KR102646920B1 - Communication Repeater Equipment - Google Patents

Abstract

The present invention relates to a multi-function communication repeater connected to a communication cable dedicated to long-distance transmission,
A ring-shaped seat 11 and a ring-shaped side plate 12 formed along the circumference of the seat 11 and protruding forward, having a plurality of heat dissipation holes 12a open to the left and right, and , an installation plate 13 formed on the front side of the side plate 12 is provided with a passage hole 13a opened front and rear, and a receiving space a is formed inside the base 10 to accommodate the receiving space a. ) a base (10) in communication with the heat dissipation hole (12a) and the through hole (13a);
A body portion 21 installed on the front side of the installation plate 13; A clock having first and second antenna seating grooves (22a, 22a') formed around the clock portion (22) so that the front, rear, and sides are open, and indicating time through an hour hand (22b) and a minute hand (22c). wealth (22); A clock operation control unit 23 installed on the body portion 21 to control the operation of the clock portion 22; A wireless communication relay unit (24) installed on the body portion (21); It is installed on the body portion 21, rotatably installed toward the first and second antenna mounting grooves (22a, 22a'), and is seated in the first and second antenna mounting grooves (22a, 22a'), and wireless communication relay First and second antennas 25 and 25' in communication connection with the unit 24; A small communication relay equipped with a power supply unit (26) installed in the body portion (21) and having a power connection terminal (26a) detachably connected to the power line (E) from the solar power generation unit (80). device 20;
First and second pushing unit bodies (31, 31') installed on the body portion (21), and movable forward and backward on the first and second pushing unit bodies (31, 31'), the first and second antennas Equipped with first and second pushing bars (32, 32') that push (25, 25') toward the first and second antenna seating grooves (22a, 22a'), the first and second antennas (25, 25') First and second pushing units (30, 30') located respectively at the rear of;
A communication error lamp (40) installed on the front side of the clock unit (22) and located on the same horizontal line as the first antenna (25);
A power failure lamp 50 installed on the front side of the clock unit 22;
It is equipped with a communication connection terminal (61) that is detachably connected to the incoming communication line (L) from the remote relay unit (70), and when a communication abnormality in the wireless communication relay unit (24) is detected, the first pushing unit (30) is connected. The main control unit (60) turns on the communication error lamp (40) while driving, and turns on the power error lamp (50) while driving the second pushing unit (30') when detecting a power supply problem of the power supply unit (26). )class;
A remote relay unit ( 70) and;
It is equipped with a solar module 81 installed on the top of the support 71 and a power conversion device 82 that converts electricity from the solar module 81, is installed outdoors, and connects a power line E. A solar power generation unit (80) electrically connected to the power supply unit (26) through a medium.
It is characterized by including.

Description

Multi-functional communication repeater with dedicated communication cable for long-distance transmission {Communication Repeater Equipment}

The present invention relates to a multi-function communication repeater connected to a communication cable dedicated to long-distance transmission.

With the rapid development of mobile communication (or wireless communication) services, high-quality services are desired even in shadow areas such as mountainous remote areas, remote islands, urban radio wave blind spots, subways, tunnels, and apartment complexes where mobile communication services are not fully provided. .

The shaded area refers to an area where the radio wave path between the base station and the terminal is cut off, that is, an area where radio waves cannot reach due to buildings or terrain. To resolve these shadow areas, additional base stations are installed or a communication network is designed using large repeaters.

However, building additional base stations to eliminate small shadow areas has the problem of excessive investment in terms of cost, so in the case of small shadow areas, this is solved with communication repeaters such as small repeaters.

Meanwhile, conventionally, when installing a small repeater indoors, there were limits to efficient electricity use due to the use of the small repeater.

In addition, conventionally, when installing a small repeater indoors, there was difficulty in utilizing the indoor space because the small repeater took up indoor space, and there were limitations in immediately confirming if there was a problem with the operation of the small repeater.

Republic of Korea Patent Publication No. 10-2586473

The present invention was invented to solve the above problems. It stably performs a relay function over a long distance while saving electrical energy, improves space utilization by utilizing an analog clock, and uses an antenna to prevent communication abnormalities and power supply. The problem to be solved is to provide a communication repeater that easily displays the above problems visually.

The present invention to solve the above problems,

A ring-shaped seat 11 and a ring-shaped side plate 12 formed along the circumference of the seat 11 and protruding forward, having a plurality of heat dissipation holes 12a open to the left and right, and , an installation plate 13 formed on the front side of the side plate 12 is provided with a through hole 13a opened front and rear, and a receiving space a is formed inside the base 10 to accommodate the receiving space a. ) a base (10) in communication with the heat dissipation hole (12a) and the through hole (13a);

A body portion 21 installed on the front side of the installation plate 13; A clock having first and second antenna seating grooves (22a, 22a') formed around the clock portion (22) so that the front, rear, and sides are open, and indicating time through an hour hand (22b) and a minute hand (22c). wealth (22); A clock operation control unit 23 installed on the body portion 21 to control the operation of the clock portion 22; A wireless communication relay unit (24) installed on the body portion (21); It is installed on the body portion 21, rotatably installed toward the first and second antenna mounting grooves (22a, 22a'), and is seated in the first and second antenna mounting grooves (22a, 22a'), and wireless communication relay First and second antennas 25 and 25' in communication connection with the unit 24; A small communication relay equipped with a power supply unit (26) installed in the body portion (21) and having a power connection terminal (26a) detachably connected to the power line (E) from the solar power generation unit (80). device 20;

First and second pushing unit bodies (31, 31') installed on the body portion (21), and movable forward and backward on the first and second pushing unit bodies (31, 31'), the first and second antennas Equipped with first and second pushing bars (32, 32') that push (25, 25') toward the first and second antenna seating grooves (22a, 22a'), the first and second antennas (25, 25') First and second pushing units (30, 30') located at the rear, respectively;

A communication error lamp (40) installed on the front side of the clock unit (22) and located on the same horizontal line as the first antenna (25);

A power failure lamp 50 installed on the front side of the clock unit 22;

It is equipped with a communication connection terminal (61) that is detachably connected to the incoming communication line (L) from the remote relay unit (70), and when a communication abnormality in the wireless communication relay unit (24) is detected, the first pushing unit (30) is connected. The main control unit (60) turns on the communication error lamp (40) while driving, and when detecting a power supply problem of the power supply unit (26), turns on the power error lamp (50) while driving the second pushing unit (30'). )class;

A remote relay unit ( 70) and;

It is equipped with a solar module 81 installed on the top of the support 71 and a power conversion device 82 that converts electricity from the solar module 81, is installed outdoors, and connects a power line E. A solar power generation unit (80) electrically connected to the power supply unit (26) through a medium.

It is characterized by including.

The present invention, which is a means of solving the above problems, has the effect of receiving electricity through the solar power generation unit 80, saving electrical energy, and performing a relay function by stably receiving signals from a distance. .

In addition, the present invention has the effect of performing a wireless communication relay function while improving space utilization by utilizing an analog clock installed on the wall (W).

Additionally, the present invention can be installed on the top of the building wall (W), thereby improving communication efficiency.

In addition, the present invention utilizes the first and second antennas (25, 25') and the first and second pushing units (30, 30') to easily visually indicate communication abnormalities and electrical supply abnormalities, and in addition, The communication error lamp 40 and the power supply error lamp 50, which are located on the same line as the first and second antennas 25 and 25', respectively, have the effect of easily checking communication problems and power supply problems more efficiently. there is. Through this, the present invention has the effect of convenient maintenance.

In addition, the present invention can be conveniently installed on the building wall (W) or the floor (B) of the structure, improving usability, and especially when installed on the floor (B) of the structure, it can be safely installed through the base (10). As a result, electric wires and communication lines can not be exposed to the outside, and the small communication relay device 20 can be easily cooled.

1 is a front view for explaining a first embodiment of the present invention,
Figure 2 is a partial cross-sectional view taken along line X-X' in Figure 1;
Figure 3 is a rear perspective view for explaining the clock unit in the first embodiment of the present invention;
Figure 4 is a diagram for explaining a long-distance relay unit and a solar power generation unit according to the first embodiment of the present invention;
5 is an electrical configuration diagram between components according to the first embodiment of the present invention;
6 and 7 are diagrams for explaining the operation according to the first embodiment of the present invention,
Figures 8 and 9 are diagrams for explaining the second embodiment of the present invention.

Hereinafter, the present invention will be described in detail so that those skilled in the art can easily carry out the present invention.

FIG. 1 is a front view for explaining a first embodiment of the present invention, FIG. 2 is a partial cross-sectional view taken along line It is a rear perspective view, Figure 4 is a diagram for explaining the remote relay unit and solar power generation unit according to the first embodiment of the present invention, and Figure 5 is an electrical configuration diagram between the components according to the first embodiment of the present invention, The configuration of the present invention will be described with reference to FIGS. 1 to 5 as follows. Meanwhile, in the present invention, the directionality of the configuration of the present invention is explained by assuming that the

A multi-function communication repeater connected to a communication cable dedicated to long-distance transmission according to the first embodiment of the present invention includes a base 10, a small communication repeater 20, first and second pushing units 30 and 30', It includes a communication error lamp 40, a power error lamp 50, a main control unit 60, a remote relay unit 70, and a solar power generation unit 80.

As shown in FIG. 2, the base 10 includes a seating body 11, a side plate 12, and an installation plate 13.

The seating body 11 has a plate shape. In this embodiment, a pair of seating bodies 11 may be provided to face each other. Meanwhile, in this embodiment, the seating body 11 can be detachably installed on the wall W through a separate fastening member.

The side plate 12 is provided to protrude forward from the seating body 11. In this embodiment, a pair of side plates 12 may be provided to face each other.

The installation plate 13 is formed on the front side of the side plate 12 and has a through hole 13a opened front and rear.

As shown in FIGS. 1, 2, and 3, the small communication relay device 20 includes a body portion 21, a clock portion 22, a clock operation control unit 23, and a wireless communication relay. It is equipped with a unit 24, an antenna 25, and a power supply unit 26.

The body portion 21 is installed on the front side of the mounting plate 13. In this embodiment, the body portion 21 has a box shape.

The watch unit 22 is provided with first and second antenna seating grooves 22a and 22a' formed around the watch unit 22 so that the front, rear and sides are open, and includes an hour hand 22b and a minute hand ( 22c) indicates time. In this embodiment, the first and second antenna mounting grooves 22a are provided around the clock unit 22 to face each other. Additionally, in this embodiment, the first and second antenna seating grooves 22a and 22a' have an inclined inner surface so that the first and second antennas 25 and 25' can be seated thereon. Meanwhile, in this embodiment, the clock unit 22 may be a typical analog clock equipped with an hour hand 22b and a minute hand 22c. Additionally, in this embodiment, a plurality of first and second antenna mounting grooves 22a may be provided.

The clock operation control unit 23 is installed in the body portion 21 and controls the operation of the clock portion 22. In this embodiment, the clock operating unit 23 is built into the body portion 21.

The wireless communication relay unit 24 is installed in the body portion 21. In this embodiment, the wireless communication relay unit 24 is equipped with a normal relay function and is installed in the body portion 21.

The first and second antennas 25 and 25' are installed on the body portion 21, and are rotatably installed toward the first and second antenna seating grooves 22a and 22a', and are installed to accommodate the first and second antennas. It is seated in the grooves 22a and 22a' and is connected to the wireless communication relay unit 24. In this embodiment, a plurality of first and second antennas 25 and 25' may be provided. Additionally, in this embodiment, the first and second antennas 25 and 25' may be provided to face each other.

The power supply unit 26 has a power connection terminal 26a detachably connected to the power line E from the solar power generation unit 80, and is installed on the body portion 21. In this embodiment, the power supply unit 26 is built into the body portion 21. Additionally, in this embodiment, the power supply unit 26 is equipped with a switch 26b for turning on and off, and the switch 26b may be installed on the outside of the body portion 21. Meanwhile, in this embodiment, the power connection terminal 26a is detachably connected to the terminal of the power line E.

As shown in FIG. 2, the first and second pushing units (30, 30') include first and second pushing unit bodies (31, 31') installed on the body portion (21), and first and second pushing units (31, 31'). The first and second antennas are installed to be movable forward and backward on the pushing unit main body (31, 31') and push the first and second antennas (25, 25') toward the first and second antenna seating grooves (22a, 22a'). Equipped with pushing bars (32, 32'), they are located behind the first and second antennas (25, 25'), respectively. In this embodiment, the first and second pushing units (30, 30') may be equipped with various types of driving devices such as solenoids, and are each provided with a plurality corresponding to the number of the first and second antennas (25, 25'). It can be.

As shown in FIGS. 1 and 2, the communication error lamp 40 is installed on the front side of the clock unit 22 so as to be located on the same line in the horizontal direction as the first antenna 25.

The power failure lamp 50 is installed on the front side of the clock unit 22, as shown in FIGS. 1 and 2. In this embodiment, the power failure lamp 50 may be installed on the same line in the horizontal direction as the second antenna 25'. Additionally, in this embodiment, the power failure lamp 50 is located below the second antenna 25'.

As shown in FIG. 5, the main control unit 60 is equipped with a communication connection terminal 61 that is detachably connected to the incoming communication line (L) from the remote relay unit 70, and is a wireless communication relay unit. When a communication abnormality in (24) is detected, the communication abnormality lamp 40 is turned on while driving the first pushing unit 30, and when a power supply abnormality in the power supply unit 26 is detected, the second pushing unit 30' While driving, the power failure lamp (50) turns on. In this embodiment, the main control unit 60 may be designed to drive the first pushing unit 30 and the communication error lamp 40 in the event of a communication error, and to drive only the power error lamp 50 in the event of a power error. . Additionally, in this embodiment, the communication connection terminal 61 is detachably connected to the incoming communication line (L) terminal. Meanwhile, in this embodiment, the main control unit 60 may be equipped with separate detection means to detect communication abnormalities and power supply abnormalities.

As shown in FIGS. 4 and 5, the remote relay unit 70 is equipped with a support 71 and a remote antenna 72 installed on the support 72, is installed outdoors, and is connected to an incoming communication line. It is connected to the main control unit 60 through (L). In this embodiment, the remote relay unit 70 receives a signal from the base station and transmits the signal to the small communication relay device 20 located far away from the remote relay unit 70 through the incoming communication line (L).

As shown in FIGS. 4 and 5, the solar power generation unit 80 includes a solar module 81 installed on the top of the support 71 and a device that converts electricity from the solar module 81. It is equipped with a power conversion device (82), is installed outdoors, and is electrically connected to the power supply unit (26) via a power line (E). In this embodiment, the power conversion device 82 can convert direct current electricity generated by the solar module 81 into alternating current electricity.

FIGS. 6 and 7 are diagrams for explaining the operation of the first embodiment of the present invention. The operation of the first embodiment of the present invention will be described with reference to FIGS. 6 and 7 as follows.

In this embodiment, the remote relay unit 70 installed outdoors (for example, on the roof of a building) receives a signal from a base station (or another relay unit) and transmits the signal indoors (for example, through the incoming communication line L). It is transmitted to a small communication relay device (20) placed underground.

Additionally, in this embodiment, as shown in FIG. 6, the solar power generation unit 80 generates power using sunlight.

Then, the electricity generated by the solar power generation unit 80 is supplied to the main control unit 60 through the power line E.

Meanwhile, if the communication repeater according to this embodiment is installed on the wall (W), the time can be easily checked through the analog type clock unit 22. At this time, the clock unit 22 is arranged to be spaced apart from the wall (W).

Meanwhile, when the communication repeater of this embodiment is installed on the wall (W), if an abnormality occurs in the communication signal reception of the wireless communication relay unit 14, the main control unit 60 detects this.

At this time, the main control unit 60 drives the first pushing unit 30 to move the first pushing bar 32 forward as shown in FIG. 7.

Then, the first antenna 25 rotates forward and is seated in the first antenna seating groove 22a, and the first antenna 25 protrudes toward the front of the clock unit 22.

In this way, if the first antenna 25 protrudes in front of the clock unit 22, when the user inadvertently checks the time through the clock unit 22, an abnormality in the communication relay can be quickly recognized.

Additionally, in this embodiment, when the main control unit 60 detects a communication relay abnormality, the main control unit 60 turns on the communication abnormality lamp 40 to notify the user of the communication relay abnormality. At this time, the communication error lamp 40 is located on the same line in the left and right directions as the first antenna 25, and can more efficiently report a communication relay error together with the first antenna 25.

Additionally, in this embodiment, if an abnormality occurs in the power supply or supply of the power supply unit 26, the main control unit 60 detects this. At this time, the main control unit 60 moves the second pushing bar 32' forward by driving the second pushing unit 30', protrudes the second antenna 25' forward, and turns on the power failure lamp ( 50) turns on. (Refer to the first antenna operation process in FIG. 7).

Then, the user can easily see that a problem has occurred in the electricity supply to the clock operating unit 23 and the wireless communication relay unit 24.

Meanwhile, in this embodiment, after a certain period of time passes after the first and second pushing units (30, 30') are driven, the first and second pushing bars (32, 32') return to their original positions, and check for communication abnormalities and power abnormalities. When the inspection is completed, the operator pushes the first and second antennas (25, 25') backward to return the first and second antennas (25, 25') to their original positions.

Figure 8 is a bottom perspective view for explaining the base of the communication repeater according to the second embodiment of the present invention, and Figure 9 is a partial front cross-sectional view showing the communication repeater according to the second embodiment of the present invention placed on the floor. , Referring to FIGS. 8 and 9, the communication repeater according to the second embodiment of the present invention is described as follows.

In the communication repeater according to the second embodiment of the present invention, the base 10 is partially modified, and the remaining configuration is the same as that of the first embodiment.

The base 10 has a ring-shaped seat 11 and a plurality of heat dissipation holes 12a open to the left and right, and is formed along the circumference of the seat 11, but is formed to protrude forward. It is equipped with a shaped side plate 12 and an installation plate 13 formed on the front side of the side plate 12 with a through hole 13a opened front and rear, and a receiving space (a) inside the base 10. This is formed so that the receiving space (a) communicates with the heat dissipation hole (12a) and the passage hole (13a).

The communication repeater of this embodiment can be installed on the building wall (W) or the structure floor (B).

At this time, when the communication repeater of this embodiment is installed on the floor (B) of the structure, the seating body 11 of the base 10 is in close contact with the floor B, and the communication repeater is safely placed (installed) on the floor B. .

For example, the communication repeater of this embodiment can be placed on a table at a low height and used as a desk clock and communication repeater, and the electric and communication lines are neatly arranged inside the base 10, so as not to spoil the surrounding aesthetics. At this time, the communication repeater of this embodiment can be fixed in position by inserting the receiving space (a) of the base 10 and the passing hole (13a) into the upwardly protruding protrusion (not shown) provided on the table. It can be positioned on the table in a variety of conventional ways.

Here, the base 10 has an accommodating space (a) formed inside for aesthetics, and as a result, heat generated from the small communication relay device 20 cannot be easily discharged to the outside. In the case of this embodiment, the side plate This problem is solved by providing a plurality of heat dissipation holes (12a) in (12), and the heat dissipation holes (12a) are used as an entry space for electric and communication lines to increase space utilization of the base (10).

The present invention as described above has the effect of receiving electricity through the solar power generation unit 80, saving electrical energy, and performing a relay function by stably receiving signals from a distance.

In addition, the present invention has the effect of performing a wireless communication relay function while improving space utilization by utilizing an analog clock installed on the wall (W).

Additionally, the present invention can be installed on the top of the building wall (W), thereby improving communication efficiency.

In addition, the present invention utilizes the first and second antennas (25, 25') and the first and second pushing units (30, 30') to easily visually indicate communication abnormalities and electrical supply abnormalities, and in addition, The communication error lamp 40 and the power supply error lamp 50, which are located on the same line as the first and second antennas 25 and 25', respectively, have the effect of easily checking communication problems and power supply problems more efficiently. there is. Through this, the present invention has the effect of convenient maintenance.

In addition, the present invention can be conveniently installed on the building wall (W) or the floor (B) of the structure, improving usability, and especially when installed on the floor (B) of the structure, it can be safely installed through the base (10). As a result, electric wires and communication lines can not be exposed to the outside, and the small communication relay device 20 can be easily cooled.

Meanwhile, the present invention is installed indoors, and receives and relays signals from a long distance outdoors through a communication cable such as an incoming communication line (L), in the sense that it further includes various configurations such as a clock configuration. The name of the invention is defined as a multi-function communication repeater connected to a communication cable dedicated to long-distance transmission, and the subject of the invention is defined as a communication repeater.

10: Base 20: Small communication relay device
30,30': 1st and 2nd pushing units 40; Communication error lamp
50: Power error lamp 60: Main control unit
70: long-distance relay unit 80: solar power generation unit
W: Wall B: Floor
L: Incoming communication line E: Power line

Claims (1)

A ring-shaped seat 11 and a ring-shaped side plate 12 formed along the circumference of the seat 11 and protruding forward, having a plurality of heat dissipation holes 12a open to the left and right, and , an installation plate 13 formed on the front side of the side plate 12 is provided with a passage hole 13a opened front and rear, and a receiving space a is formed inside the base 10 to accommodate the receiving space a. ) a base (10) in communication with the heat dissipation hole (12a) and the through hole (13a);
A body portion 21 installed on the front side of the installation plate 13; A clock having first and second antenna seating grooves (22a, 22a') formed around the clock portion (22) so that the front, rear, and sides are open, and indicating time through an hour hand (22b) and a minute hand (22c). wealth (22); A clock operation control unit 23 installed on the body portion 21 to control the operation of the clock portion 22; A wireless communication relay unit (24) installed on the body portion (21); It is installed on the body portion 21, rotatably installed toward the first and second antenna mounting grooves (22a, 22a'), and is seated in the first and second antenna mounting grooves (22a, 22a'), and wireless communication relay First and second antennas 25 and 25' in communication connection with the unit 24; A small communication relay equipped with a power supply unit (26) installed in the body portion (21) and having a power connection terminal (26a) detachably connected to the power line (E) from the solar power generation unit (80). device 20;
First and second pushing unit bodies (31, 31') installed on the body portion (21), and movable forward and backward on the first and second pushing unit bodies (31, 31'), the first and second antennas Equipped with first and second pushing bars (32, 32') that push (25, 25') toward the first and second antenna seating grooves (22a, 22a'), the first and second antennas (25, 25') First and second pushing units (30, 30') located respectively at the rear of;
A communication error lamp (40) installed on the front side of the clock unit (22) and located on the same horizontal line as the first antenna (25);
A power failure lamp 50 installed on the front side of the clock unit 22;
It is equipped with a communication connection terminal (61) that is detachably connected to the incoming communication line (L) from the remote relay unit (70), and when a communication abnormality in the wireless communication relay unit (24) is detected, the first pushing unit (30) is connected. The main control unit (60) turns on the communication error lamp (40) while driving, and when detecting a power supply problem of the power supply unit (26), turns on the power error lamp (50) while driving the second pushing unit (30'). )class;
A remote relay unit ( 70) and;
It is equipped with a solar module 81 installed on the top of the support 71 and a power conversion device 82 that converts electricity from the solar module 81, is installed outdoors, and connects a power line E. A solar power generation unit (80) electrically connected to the power supply unit (26) through a medium.
A communication repeater comprising: