KR102520001B1 - Integrated SAR Satellite - Google Patents

Abstract

The present invention includes a housing having a folding structure, a solar power generation unit formed on the housing to generate power, and an antenna unit formed on the satellite body to receive signals, the housing, the solar power generation unit, and the antenna. It relates to an antenna and a body-integrated SAR satellite capable of miniaturization, weight reduction, temperature gradient minimization, and power consumption reduction by being composed of one module to be integrated with each other.

Description

Antenna and body integrated SAR satellite {Integrated SAR Satellite}

The present invention relates to a synthetic aperture radar (SAR) satellite, and more particularly, to an antenna and body-integrated SAR satellite capable of overcoming spatial limitations through a foldable structure as well as being lightweight by simplifying the structure.

As shown in FIG. 1, a conventional satellite has a structure in which a solar power generation unit 2 is formed on a satellite body 1 and an antenna unit 3 is foldably coupled to the satellite body 1, and the satellite body Since (1) and the antenna unit 3 are configured separately from each other, there is a problem in that the volume increases. In addition, when the antenna unit 3 is coupled to the satellite body 1, it is difficult to reduce the weight of the satellite because the support structure 4 for supporting the antenna unit 3 must be formed on the satellite body 1. In addition, since the satellite body 1 limits the area of the antenna unit 3 where sunlight is incident or heat is generated, the area where sunlight is incident is not constant and heat is not uniformly emitted, resulting in a temperature gradient There was a growing problem.

In detail, when the antenna unit 3 is coupled to the body 1 as shown in FIG. 1, the volume of the satellite increases and the surface shape becomes complicated, so it can be transported using one projectile. Since the number of satellites in the space is limited and the load is increased by the structure for supporting the antenna part, it is difficult to transport and meet the limited design standards. In addition, the temperature gradient of the antenna part increases, which reduces the flatness of the antenna due to thermal deformation. It is a problem that is difficult to maintain.

Therefore, the need for a satellite having a new structure capable of solving these problems is emerging.

Patent Document 1) Korean Patent Publication No. 2017-0142175 (Name: Satellite frame and satellite manufacturing method, publication date: 2007.12.27)

The present invention has been made to solve the above problems, and an object of the present invention is to minimize the volume of the satellite and simplify the surface shape to maximize the number of satellites that can be transported by one launch vehicle. to provide SAR satellites.

In addition, it is to provide an antenna and body-integrated SAR satellite capable of matching the weight of the satellite to limited design standards by simplifying the structure of the satellite.

In addition, an antenna and a body-integrated SAR satellite capable of maintaining constant flatness of an antenna by minimizing a temperature gradient and minimizing power consumption for temperature maintenance are provided.

The antenna and body-integrated SAR satellite of the present invention for achieving the above object includes a housing 100 having a foldable structure; A photovoltaic power generation unit 200 formed on the housing 100 to generate power; and an antenna unit 300 formed on the satellite body 100 to transmit and receive signals.

In addition, the housing 100 is characterized by including a plurality of housing units 100A and a connecting portion 110 connecting the housing units 100A to each other in a hinged manner.

In addition, the housing 100 is characterized in that it includes a restraining portion 120 for limiting the hinge movement of the folded housing unit body 100A.

In addition, the housing 100 is characterized in that it includes a vibration absorber 130 for damping vibration. (Number 130 needs to be confirmed that it is not a Star Tracker, not a vibration absorber)

In addition, the photovoltaic power generation unit 200 is characterized in that it includes a main photovoltaic power generation unit 210 and an auxiliary photovoltaic power generation unit 220 arranged to have different directions.

In addition, it further includes an auxiliary wing part 400 coupled to the housing 100, the main solar power generation unit 210 is formed on the housing 100, and the auxiliary solar power generation unit 220 Is characterized in that formed on the auxiliary wing portion (400).

In addition, the wing portion 400 is hinged on the housing 100 and deployed, and when deployed, the main photovoltaic power generation unit 210 and the auxiliary photovoltaic power generation unit 220 face different directions characterized by

In addition, it is characterized in that it further comprises a temperature control unit for adjusting the temperature of the photovoltaic power generation unit 200 and the antenna unit 300.

In addition, the temperature controller is located inside the housing 100 and is a heat transfer medium that transfers heat from one selected from the photovoltaic power generation unit 200 and the antenna unit 300 to the other one. do.

In order to achieve the above object, the antenna and body-integrated SAR satellite stacking method of the present invention includes a miniaturization step of miniaturizing the integrated SAR satellite by folding the housing 100; and a stacking step of stacking a plurality of miniaturized antennas and body-integrated SAR satellites so that planar sides face each other, wherein the vibration absorbers 130 formed on the adjacent integrated SAR satellites have different natural frequencies. to be characterized

The antenna and body-integrated SAR satellite of the present invention has the advantage of stacking and transporting a plurality of satellites on a launch vehicle because both the power generation unit and the antenna unit are formed on a housing having a foldable structure, reducing the volume of the satellite and simplifying the external shape. there is.

In addition, since the antenna unit is located on one side, the photovoltaic power generation unit is located on the other side, and the essential components constituting the satellite are integrally formed with attached devices built inside, reinforcement used to connect the essential components constituting the satellite to each other Since there is no need for a structure, it has the advantage of minimizing the weight of the satellite.

In addition, since it has an integrated structure in which the antenna unit is located on one side of the housing and the photovoltaic power generation unit is located on the other side of the housing, sunlight is evenly applied to the entire satellite and the temperature gradient is minimized, thereby preventing the satellite from being deformed due to the temperature difference. There is an advantage, and there is an advantage in that power consumption required to minimize the temperature gradient can also be reduced.

In addition, since the vibration absorbers formed on the housing of each satellite have different natural frequencies, it is possible to solve a problem in which vibrations are amplified in the process of being transmitted along the stacked satellites.

In addition, since the vibration absorbers formed on each satellite have different natural frequencies, it is possible to solve the problem of vibration amplification even when satellites are stacked.

In addition, the housing 100 is provided with a transmission/reception module 100B inside, and both ends of the transmission/reception module 100B in the longitudinal direction are disposed in contact with the inner surface of the housing 100.

In addition, since the photovoltaic power generation units are positioned on the housing with different orientations, there is an advantage in that power can be continuously generated even when the orientation of the satellite is changed.

1 is a perspective view showing a conventional satellite;
2 is a perspective view showing a deployed antenna and body-integrated SAR satellite according to the present invention;
3 is a perspective view showing a folded antenna and body-integrated SAR satellite according to the present invention;
4 is a front view showing an antenna and a body-integrated SAR satellite of the present invention unfolded;
5 is a rear view showing the antenna and body-integrated SAR satellite of the present invention folded.
6 is a conceptual view showing that the antenna and the body-integrated SAR satellite of the present invention are stacked on the receiving space of the launch vehicle.
7 is a side view showing auxiliary wings formed on the antenna of the present invention and the body-integrated SAR satellite;
8 is a plan sectional view showing the internal structure of an antenna and a body-integrated SAR satellite according to the present invention;

Advantages and characteristics of the embodiments of the present invention, and methods for achieving them will become clear with reference to the embodiments described below in detail in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below and may be implemented in various different forms, only the present embodiments make the disclosure of the present invention complete, and common knowledge in the art to which the present invention belongs. It is provided to completely inform the person who has the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numbers designate like elements throughout the specification.

In describing the embodiments of the present invention, if it is determined that a detailed description of a known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description will be omitted. In addition, terms to be described later are terms defined in consideration of functions in the embodiment of the present invention, which may vary according to the intention or custom of a user or operator. Therefore, the definition should be made based on the contents throughout this specification.

Hereinafter, the antenna and body-integrated SAR satellite 1000 according to the present invention will be described with reference to the accompanying drawings.

2 is a perspective view showing the antenna and body-integrated SAR satellite 1000 according to the present invention unfolded, and FIG. 3 shows a perspective view showing the antenna and body-integrated SAR satellite 1000 according to the present invention folded. there is.

2 and 3, the antenna and body integrated SAR satellite 1000 according to the present invention includes a housing 100 having a foldable structure, and a photovoltaic power generation unit 200 formed on the housing 100 to generate power. ), and an antenna unit 300 formed on the satellite body 100 to transmit and receive signals.

In detail, as described with reference to FIG. 1 above, in a conventional satellite, a solar power generation unit 2 is formed on a satellite body 1, and an antenna unit 3 is deployable on the satellite body 1. Since the antenna unit 3 is separately coupled on the satellite body 1, the volume increases, the weight increases, the surface shape becomes complicated, and the temperature gradient increases. In the invention, the satellite can have a structure in which each component is not connected to each other but formed integrally, and the housing 100 in which the power generation unit 200 and the antenna unit 300 are formed has a foldable structure to solve these problems that made it possible to solve

In other words, if the volume of the satellite increases, the weight increases, or the surface shape becomes complicated, the number of satellites that can be loaded on the launch vehicle decreases, so in the present invention, the housing 100 and the solar power generation unit 200 ) and the antenna unit 300 are integrally formed, and the integrally formed satellite has a folding structure, so that more satellites can be moved to orbit through one launch vehicle.

In addition, when the satellite has an integrated structure, the surface of the photovoltaic power generation unit 200 or the surface of the antenna unit 300 is covered by the housing 100, so that the amount of sunlight applied to the satellite varies for each specific area. Since it is possible to solve the problem of deformation of the antenna unit 300, which should have a certain flatness due to the temperature gradient, of course, there is an advantage in that it can be solved.

At this time, in the present invention, the photovoltaic power generation unit 200 may include a photovoltaic cell array 211 composed of a plurality of photovoltaic cells 211A, and the antenna unit 300 transmits and receives wavelengths. It may include an antenna array 310 formed by gathering antennas 310A, and other components constituting the photovoltaic power generation unit 200 and the antenna unit 300 are built into the housing 100. Thus, one surface and the other surface of the antenna and the body-integrated SAR satellite 1000 on which the photovoltaic cell array 211 and the antenna array 310 are formed may have a flat structure.

That is, in the case of the antenna and body-integrated SAR satellite of the present invention, it is necessary to minimize the storage area required to increase the storage efficiency, and in order to fold the housing 100 as shown in FIG. Since both sides of the SAR satellite must have a flat structure, in the present invention, both sides of the housing 100 are formed flat, and the photovoltaic cell array 211 and the antenna array 310 are formed on both sides to form a flat This increases the usability of both sides.

4 is a front view showing the antenna and body-integrated SAR satellite 1000 of the present invention unfolded.

Referring to FIGS. 1 to 4 , the housing 100 may include a plurality of housing units 100A and a connection part 110 connecting the housing units 100A to each other in a hinged manner.

In detail, in order to obtain shape information of an object using satellites, the location of the antenna 310A through which signals are transmitted, the location information of the antenna 310A through which signals are received, delay time information, and the like are required. Since a plurality of antennas 310A must be arranged in a certain area with a certain distance in order to obtain the antenna array 310, the antenna array 310 is formed on one surface of the housing 100, but the area where the antenna array 310 is installed Since the problem of excessively widening the housing 100 occurs when the information is expanded to an area where information can be obtained, in the present invention, the housing 100 is composed of a plurality of housing units 100A, and as shown in FIG. A plurality of housing units 100A are hingedly connected to each other using the connecting portion 110, and when the housing 100 is folded, the housing units 100A connected to each other by the connecting portion 110 are centered around the connecting portion 110. It is folded so that it can be stacked on top of each other as shown in FIG. 3 .

5 is a rear view showing the antenna and body-integrated SAR satellite 1000 of the present invention folded.

Referring to FIG. 5 , the housing 100 may include a restraining part 120 that limits the hinge motion of the folded housing unit 100A.

In detail, the antenna and body-integrated SAR satellite of the present invention is moved to a satellite orbit through a launch vehicle. At this time, if the hinge movement of the housing unit 100A is not restricted, the housing unit 100A is hinged by vibrations generated in the launch environment and the satellite may be destroyed. Therefore, in the present invention, the restraining unit The hinge movement of the housing unit 100A is limited by using the 120.

In addition, the housing unit 100A has a first restraining part 121 located at the center of the edge of the housing unit 100A and restricting the movement of the housing unit 100A, and the first restraining part 121 is interposed therebetween. and a second restraining part 122 positioned adjacent to an edge end of the housing unit 100A, and any one or more of the first restraining part 121 and the second restraining part 122 may include an antenna and When the body-integrated SAR satellite reaches the satellite orbit, the housing unit 100A is unfolded so that the satellite has an area where the antenna array 310 can obtain various information through signals as shown in FIGS. 2 and 4 (HRM) and Release Mechanism).

6 is a conceptual diagram showing that the antenna and the body-integrated SAR satellite 1000 of the present invention are stacked on the storage space 11 of the launch vehicle 10.

1 to 6, the antenna and body-integrated SAR satellite 1000 of the present invention may include a vibration absorber 130 for damping vibration on the housing 100, and the satellite is stacked on the receiving space of the launch vehicle. In order to limit resonance and amplification of vibrations generated in the launch environment during movement, the vibration absorbers 130 formed on each satellite may have different natural frequencies.

In detail, the step of accommodating the antenna and body-integrated SAR satellite on the launch vehicle includes the step of miniaturizing the antenna and body-integrated SAR satellite by folding the housing 100, and the miniaturized plurality of antennas and the body-integrated SAR satellite on the flat side. It may include a lamination step of stacking the layers so that they face each other. At this time, when the projectile 10 is launched in a state in which the antenna and body-integrated SAR satellite are stacked, the vibration generated in the launch environment is amplified by the resonance phenomenon in the process of being transmitted through the stacked integrated SAR satellite 1000. Since this can occur, in the present invention, the vibration absorber 130 having a different natural frequency is formed on each projectile 10 to prevent vibration from being amplified due to resonance.

At this time, the vibration absorber 130 may include a damper, a spring located on the restraining unit, and a vibration isolator, and a damper formed on different antennas and body-integrated SAR satellites, a spring located on the restraining unit, and a vibration isolator The method of differentiating the natural frequency of may be a method of changing the elastic modulus by differentiating the material and differentiating the shape or structure of the spring (S) on the damper or restraining part.

7 is a side view showing that the auxiliary wing 400 is formed on the antenna and body-integrated SAR satellite 1000 according to the present invention.

Referring to FIG. 7, the antenna and body-integrated SAR satellite 1000 of the present invention further includes an auxiliary wing part 400 coupled to the housing 100, and the photovoltaic power generation part 200 has different directions. It includes a main photovoltaic power generation unit 210 disposed to have and an auxiliary photovoltaic power generation unit 220, wherein the main photovoltaic power generation unit 210 is formed in the housing 100, and the auxiliary photovoltaic power generation unit (220) may be formed on the auxiliary wing portion (400).

In detail, in order for the satellite to transmit and receive a signal to investigate the designated position, the direction of the satellite must be changed to look at the designated position. However, in the case of the present invention, the photovoltaic cell array 211 and the antenna array 310 are arranged symmetrically on one side and the other side of the housing 100, so that the antenna array 310 transmits a signal to a designated location. Since sunlight is not applied to the photovoltaic cell array 211 when the direction is changed so that power supply may stop, in the present invention, the main sun formed in the housing 100 on the wing portion 400 By forming an auxiliary photovoltaic power generation unit 220 having a direction different from that of the photovoltaic power generation unit 210, the solar power generation unit 200 can stably produce electricity.

In addition, although not shown on the drawing, it is sufficient for the main photovoltaic power generation unit 210 and the auxiliary photovoltaic power generation unit 220 to have different directions, so that the main solar light is placed on one side of one or more housing units 100A. Of course, it may have a structure in which the power generation unit 210 is formed and the auxiliary photovoltaic power generation unit 220 is formed on the other side of one or more housing units 100A.

In addition, the antenna and body-integrated SAR satellite according to the present invention may have a temperature control unit for uniformizing the temperature distribution of the satellite or emitting or heating heat as necessary. The temperature control unit uses a circulating fluid circulating inside the SAR satellite. It may be a method, and in addition, it may be a method using a solid material having high conductivity.

In detail, in the case of the SAR satellite as shown in FIG. 1, there is a problem that the temperature of the part to which sunlight is applied is relatively high and the temperature of the part to which sunlight is not applied is relatively low in space environment conditions. Since it is recommended that the temperature of the antenna unit 300 be above a certain level in order for the antenna unit 300 to operate normally, in the present invention, thermal deformation is prevented by minimizing the temperature gradient using the temperature controller, and at the same time, if necessary By raising the temperature of the satellite, it is possible for the satellite to operate normally even in the harsh environment of space.

8 is a cross-sectional view showing the internal structure of the antenna and body-integrated SAR satellite 1000 according to the present invention.

Referring to FIG. 8, in the antenna and body-integrated SAR satellite 1000 of the present invention, the housing 100 has a transmission/reception module 100B inside, and the transmission/reception module 100B has both ends in the longitudinal direction of the housing ( 100), internal heat can be released to the outside through the side of the housing 100, and the transmission/reception module 100B may include TR (Transmit-Receive), (TWTA).

In detail, since heat dissipation may not be performed efficiently in the case of a side surface having a relatively small area, the end of the transmission/reception module 100B provided inside the housing 100 is brought into contact with the side surface of the housing 100 to dissipate heat. that increased the area. Therefore, since heat is dissipated more efficiently from each surface of the housing 100, it is possible to prevent a distortion phenomenon that may occur due to an increase in temperature difference at each location of the housing, as well as f, which occurs as the temperature of the satellite itself increases. Of course, it is possible to solve the problem of reducing the efficiency of each component, and the transmission/reception module 100B may be made of GaN to increase heat dissipation efficiency.

The present invention is not limited to the above-described embodiments, and the scope of application is diverse, and anyone with ordinary knowledge in the field to which the present invention belongs without departing from the gist of the present invention claimed in the claims Of course, various modifications are possible.

100: housing 100A: housing unit
110: connection part 120: restraint part
130: vibration absorber
200: solar power generation unit 210: main solar power generation unit
220: auxiliary solar power generation unit
300: antenna unit
400: auxiliary wing

Claims (11)

a housing 100 having a folding structure;
A photovoltaic power generation unit 200 formed on the housing 100 to generate power; and
An antenna unit 300 formed on the housing 100 to transmit and receive signals; including,
The photovoltaic power generation unit 200 is provided on one surface of the housing 100, and the antenna unit 300 is provided on the other surface,
An antenna and a main body formed in a form that can be folded so that one side surface provided with the photovoltaic power generation unit 200 and the other surface provided with the antenna unit 300 face each other with one end and the other end in the longitudinal direction of one surface Integral SAR satellite.
According to claim 1,
The housing 100 includes a plurality of housing units 100A and a connection part 110 connecting the housing units 100A to each other in a hinged manner.
According to claim 2,
The housing 100 includes a restraining portion 120 limiting hinge motion of the folded housing unit 100A.
According to claim 1,
The housing (100) includes a vibration absorber (130) for damping vibration.
According to claim 1,
The photovoltaic power generation unit 200 includes a main photovoltaic power generation unit 210 and an auxiliary photovoltaic power generation unit 220 disposed to have different directions, and an antenna and body integrated SAR satellite.
According to claim 5,
Further comprising an auxiliary wing 400 coupled to the housing 100,
The main solar power generation unit 210 is formed on the housing 100, and the auxiliary solar power generation unit 220 is formed on the auxiliary wing unit 400.
According to claim 6,
The wing portion 400 is hingedly deployed on the housing 100, and when deployed, the main photovoltaic power generation unit 210 and the auxiliary photovoltaic power generation unit 220 face different directions, the antenna and body-integrated SAR satellites.
According to claim 1,
The antenna and body-integrated SAR satellite further comprising a temperature control unit for adjusting the temperature of the photovoltaic power generation unit 200 and the antenna unit 300.
According to claim 8,
The temperature controller is located inside the housing 100 and is a heat transfer medium that transfers heat from one selected from the photovoltaic power generation unit 200 and the antenna unit 300 to the other, the antenna and body integrated SAR. satellite.
According to claim 2,
The housing 100 is provided with a transmission/reception module 100B therein, and both ends of the transmission/reception module 100B in the longitudinal direction are disposed in contact with the inner surface of the housing 100, and the antenna and body integrated SAR satellite.
In the antenna and body-integrated SAR satellite stacking method of claim 4,
miniaturization step of miniaturizing the integrated SAR satellite by folding the housing 100; and
A stacking step of stacking a plurality of miniaturized integrated SAR satellites so that their flat sides face each other;
The method of stacking the antenna and body integrated SAR satellites, wherein the vibration absorbers 130 formed on the integrated SAR satellites adjacent to each other have different natural frequencies.

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