KR0170988B1 - Lnb structure of satellite antenna - Google Patents

Abstract

The present invention relates to an LNB structure of a satellite antenna, which is formed in a hexahedron shape and has circuit board storage grooves and waveguides separated by partition walls, each having a predetermined size and depth from a surface mounted on the rear surface of the antenna. A main body, a circuit board provided on the bottom surface of the circuit board storage groove, a probe projecting into the waveguide through a mounting hole formed in the partition wall in a state soldered to one end of the circuit board, and the main body opening A cover covering the surface of the body and a connector installed at an outer lower side of the main body and applying a low noise amplified satellite signal to the satellite broadcasting receiver in an electrically connected state with the circuit board. In the LNB structure of the satellite antenna having through holes formed on the outer wall of the waveguide corresponding to the corresponding position, The bottom surface of the body corresponding to the bottom is orthogonal to the direction of formation of the mounting hole on the partition wall, a fastening hole is formed in communication with the mounting hole, the fastening hole is inserted into the mounting hole while the front and rear pitch shift by the rotational force applied from the outside The probe support member is inserted and coupled to prevent the probe from flowing in the correct mounting position, while the tapered pin is inserted and coupled to the through hole, thereby optimizing the positioning of the probe in the LNB for the satellite antenna to prevent misalignment of the center line when installing the probe. It is possible to prevent the error of radio wave reception caused by it, and to change the shape of the screw inserted into the through hole machined on the outer wall of the waveguide for the installation of the probe to prevent the leakage of the radio wave according to the distance difference with the inner wall of the waveguide. While preventing the fastening of the body and cover It will have to improve the property.

Description

LNB structure of satellite antenna

1 is a side cross-sectional view and a partially enlarged side cross-sectional view showing the LNB structure of a conventional satellite antenna.

2 is a side cross-sectional view showing the LNB structure of a satellite antenna according to the present invention.

* Explanation of symbols for main parts of the drawings

10: LNB 14: Waveguide

20: circuit board 22: mounting hole

24: probe 30: through hole

42: fastening hole 44: probe support member

46: taper pin 52: support pin

56: support pin insertion hole

The present invention relates to a low noise blockdown converter (LNB) structure of a satellite antenna, and more particularly, converts a high frequency signal reflected from a satellite to an antenna and converts it into a low frequency signal, and amplifies it to a low noise signal. Optimize the positioning of the probes that make up the LNB in the LNB sent to the receiver) to prevent the error of radio reception caused by the mismatch of the center lines when installing the probe, and to process the outer wall of the waveguide to install the probe. The present invention relates to an LNB structure of a satellite antenna for changing a shape of a screw fitted into a through hole to prevent leakage of radio waves due to a distance difference between a machining step surface of an inner end of the screw and an inner wall of the waveguide.

In general, an LNB is installed on the back side of the satellite antenna to convert a high frequency signal reflected from the satellite to the antenna and then to a low frequency signal and to amplify the low noise signal to a satellite broadcasting receiver. As shown in FIG. 1, the circuit board accommodating groove 12 and the waveguide 14 each having a predetermined size and depth inward from the surface mounted on the rear side of the antenna are partition walls ( The main body 18 having a structure divided by 16, a circuit board 20 provided on the bottom surface of the circuit board receiving groove 12, and in a state soldered to one end of the circuit board 20 A probe 24 protruding into the waveguide 14 through the mounting hole 22 formed in the partition 16, a cover 26 covering the open surface of the main body 18, and It is installed in the lower outer side of the main body 18 and the circuit It is composed of a connector (not shown) for applying a low noise amplified satellite signal to a separate satellite broadcasting receiver in an electrically connected state to (20), in the LNB of such a structure is transmitted from the satellite to the antenna and then The high frequency signal reflected by the reflecting surface is introduced into the waveguide 14, is applied to the circuit board 20 by the probe 24 protruding into the waveguide 14, and amplified low noise. The cable is connected to the satellite broadcasting receiver.

Meanwhile, in attaching the probe 24 to the LNB 10 having such a structure, a mounting hole 22 on the partition 16 on which the probe 24 is installed may be formed by a general mold structure. Since the through hole 30 is drilled in the outer wall 28 forming the waveguide 14 by a mechanical processing method, the mounting hole 22 is formed on the partition 16 through the through hole 30. And connecting pins 32 protruding from one end of the probe 22 in a state in which the probe 24 is inserted into the mounting hole 22 through the through hole 30 to the circuit board 20. The through hole 30 formed in the outer wall 28 of the waveguide 14 is soldered to prevent the use of the spring washer 34 and the screw 36.

However, in the conventional probe mounting structure of the LNB of the satellite antenna, the inner end of the screw 36 blocking the through hole 30 is inevitably processed during the machining, as shown in the partially enlarged side cross-sectional view of FIG. The stepped angle θ does not coincide with the inner wall surface of the waveguide 14, and partly spaced apart from the inner wall surface of the waveguide 14, causing leakage of radio waves. .

In the conventional probe mounting structure of the LNB of the satellite antenna, the probe 24 is inserted into the mounting hole 22 on the partition 16 through the through hole 30, and one side end of the probe 24 is inserted. When soldering the connecting pin 32 protruding from the solder to the circuit board 20, the flow phenomenon of the connecting pin 32 is generated due to the difference in the operator's skill or the working force applied to the soldering portion. There is a problem that an error occurs in radio wave reception because the center line of the probe 24 is not aligned.

In addition, when the head of the screw 36 which blocks the through hole 30 formed in the outer wall 28 of the waveguide 14 protrudes outward, the fastening operation of the main body 18 and the cover 26 is very inconvenient. There is a problem.

The present invention is to solve such a conventional problem, the object is to optimize the positioning of the probe in the satellite antenna LNB to prevent the error of radio reception caused by the mismatch of the center line when installing the probe, By changing the shape of the screw fitted into the through hole machined on the outer wall of the waveguide for the installation of the probe, it is possible to prevent the leakage of radio waves due to the distance difference between the inner wall of the waveguide and the workability of the main body and the cover It is to provide a new type of LNB structure of satellite antenna to improve the performance.

In order to achieve the above object, the present invention is made of a hexahedron shape and the main body of the circuit board storage groove and waveguide formed by a partition wall, each having a predetermined size and depth inward from the surface mounted on the back of the antenna And a circuit board installed on the bottom surface of the circuit board storage groove, a probe projecting into the waveguide through a mounting hole formed in the partition wall in a state of being soldered to one end of the circuit board, and the body being opened. A cover covering the surface and a connector installed at an outer lower portion of the main body and applying a low noise amplified satellite signal to the satellite broadcasting receiver in an electrically connected state with the circuit board, and coinciding with the center line of the mounting hole. In the LNB structure of the satellite antenna having a through hole formed in the outer wall of the waveguide corresponding to the position, The bottom surface of the body corresponding to the bottom is orthogonal to the direction of formation of the mounting hole on the partition wall, a fastening hole is formed in communication with the mounting hole, the fastening hole is inserted into the mounting hole while moving back and forth pitch by a rotational force applied from the outside The probe support member is inserted and coupled to prevent the probe from flowing in the correct mounting position, while the tapered pin is fitted into the through hole.

In the present invention, the probe support member is a cylindrical body portion having a predetermined size with a screw portion formed on the outer circumferential surface, and a support pin protruding from the center of the inner end of the body portion, and directly in contact with the probe in the mounting hole, Comprising the head portion formed integrally with the outer end of the body portion, the fastening hole has a screw portion formed on the inner circumferential surface, the support pin insertion hole is formed in the center of the bottom surface communicating with the mounting hole on the partition wall .

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings.

2 is a side cross-sectional view showing the LNB structure of the satellite antenna according to the present invention, and accordingly, the LNB structure 40 of the satellite antenna of the present invention has a hexahedron shape and is respectively predetermined inward from the surface mounted on the rear surface of the antenna. The circuit board storage groove 12 and the waveguide 14 having a size and depth of the main body 18 is formed by the partition wall 16 and the circuit is provided on the bottom surface of the circuit board storage groove 12 A probe 24 protruding into the waveguide 14 through a mounting hole 22 formed in the partition wall 16 in a state of being soldered to the substrate 20 and one end of the circuit board 20, and A satellite broadcasting receiver for receiving a low-noise amplified satellite signal installed in a cover 26 covering the open surface of the main body 18 and under the outer side of the main body 18 and electrically connected to the circuit board 20. Consists of a connector to be applied to, of the mounting hole 22 In the LNB structure of the satellite antenna in which the through hole 30 is formed in the outer wall 28 of the waveguide 14 corresponding to the core line, the bottom surface of the main body 18 corresponding to the lower side of the partition wall 16. The fastening hole 42 is orthogonal to the forming direction of the mounting hole 22 on the partition 16 and communicates with the mounting hole 22, and the fastening hole 42 has a rotational force applied from the outside. Probe support member 44 is inserted and coupled to prevent the probe 24 inserted into the mounting hole 22 from flowing in the correct mounting position while moving forward and backward by pitch, while the tapered pin 46 is inserted into the through hole 30. Indicates that they are fitted together.

In the present invention as described above, the probe support member 44 protrudes from a cylindrical body portion 50 having a predetermined size having a screw portion 48 formed on an outer circumferential surface thereof, and a center of an inner end of the body portion 50. It consists of a support pin 52 in direct contact with the probe 24 in the mounting hole 22 and the head portion 54 integrally formed at the outer end of the body portion 50, the corresponding fastening The hole 42 shows that the threaded portion 48 'is formed on the inner circumferential surface thereof, and the support pin insertion hole 56 communicating with the mounting hole 22 on the partition 16 is formed at the center of the bottom surface thereof.

On the other hand, in the present invention, the through hole 30 is formed in a wedge shape having a narrow inner side and a wide outer side, and has a diameter larger than the outer diameter of the through hole 30 at its outer end, and constitutes the waveguide 14. A seating portion 30a is formed to be stepped to a predetermined height with an outer surface of the outer wall 28, and the tapered pin 46 fitted into the through hole 30 is connected to the seating portion 30a at an outer end thereof. It shows that the engaging jaw (46a) of the min-head type that is fitted and seated integrally.

On the other hand, in the present invention, the inner end of the tapered pin 46 is precisely processed so as to be placed on the same surface as the inner surface of the waveguide 14 in a state completely fitted in the through hole (30).

The operation of the present invention made as described above is as follows.

As shown in FIG. 2, the probe 24 is inserted into the mounting hole 22 on the partition 16 through the through hole 30 formed in the outer wall 28 of the waveguide 14 constituting the LNB 10. Then, the tapered pin 46 is inserted into the through hole 30, and the body of the probe support member 44 is provided in the fastening hole 42 formed on the bottom surface of the main body 18 corresponding to the bottom of the partition 16. The support pin insertion hole 56 formed at the bottom surface of the fastening hole 42 has a support pin 52 protruding from the body portion 50 of the probe support member 44 while the part 50 is screwed together. In the initial state of being inserted into the mounting hole 22 and in contact with the probe 24, the support pin 32 protruding from one end of the probe 24 is soldered to the circuit board 20. As the probe 24 is supported by the pin 52 without flow at a predetermined position, an action force acts on the soldering portions of the connecting pin 32 and the circuit board 20. Will be a flow of group probe 24 is prevented.

On the other hand, since the inner end of the tapered pin 46 fitted in the through hole 30 is located on the same plane as the inner surface of the waveguide 24, the probe (without leaking the high frequency signal introduced into the waveguide 24) is leaked. 24) is applied.

When the present invention is applied, leakage of radio waves does not occur as the inner end of the tapered pin fitted into the through hole formed in the outer wall of the waveguide is placed on the same surface without stepped with the inner surface of the waveguide. It is effective, and the load acting on the soldering part as the probe inserted into the mounting hole through the through hole is soldered to the circuit board in the state supported by the support pin on the probe support member fitted from the direction orthogonal to the mounting direction. There is an effect that does not flow by the error does not occur when receiving radio waves.

In addition, the outer end of the tapered pin to be inserted into the through hole is formed in the shape of a flat head and is seated on the seating portion formed in the outer end of the through hole has an effect that the workability of the LNB body and the cover is significantly improved. will be.

Claims (3)

A main body 18 having a hexahedron shape and having a circuit board accommodating groove 12 and a waveguide 14 each having a predetermined size and depth inward from a surface mounted on the rear surface of the antenna by partition walls 16. ), A circuit board 20 provided on the bottom surface of the circuit board storage groove 12, and a mounting hole 22 formed in the partition wall 16 in a state of being soldered to one end of the circuit board 20. A probe 24 protruding into the waveguide 14 through the cover, a cover 26 covering an open surface of the main body 18, and a lower portion of the outer side of the main body 18. And a connector for applying a low noise amplified satellite signal to the satellite broadcasting receiver in an electrically connected state, and the outer wall 28 of the waveguide 14 corresponding to a position coinciding with the center line of the mounting hole 22. In the LNB structure for the satellite antenna in which the through hole 30 is formed, The bottom surface of the main body 18 corresponding to the lower side of the partition 16 is orthogonal to the direction of formation of the mounting hole 22 on the partition 16, and a fastening hole 42 communicating with the mounting hole 22 is formed. Probe support member 44 is inserted into the fastening hole 42 to prevent the probe 24 inserted into the mounting hole 22 from flowing at the correct mounting position while the pitch is moved back and forth by a rotation force applied from the outside. On the other hand, the through hole 30, the tapered pin 46 is inserted into the LNB structure of the satellite antenna, characterized in that coupled. The method of claim 1, wherein the probe support member 44 comprises: a cylindrical body portion 50 having a predetermined size having a threaded portion 48 formed on an outer circumferential surface thereof; A support pin 52 protruding from the center of the inner end of the body portion 50 and in direct contact with the probe 24 in the mounting hole 22; The head portion 54 is formed integrally with the outer end of the body portion 50, the corresponding fastening hole 42 is formed with a screw portion 48 'on the inner peripheral surface thereof, LNB structure of a satellite antenna, characterized in that the support pin insertion hole 56 is formed in communication with the mounting hole 22 on the partition wall (16). The outer wall of claim 1, wherein the through hole 30 is formed in a wedge shape having a narrow inner side and a wide outer side, and having a diameter larger than an outer diameter of the through hole 30 at an outer end thereof and constituting the waveguide 14. A seating portion 30a which is stepped to a predetermined height with an outer surface of the 28 is formed, and the tapered pin 46 fitted into the through hole 30 is fitted to the seating portion 30a at its outer end. LNB structure of a satellite antenna, characterized in that the engaging jaw (46a) is formed integrally.