KR102711914B1 - Communication distributor - Google Patents

Abstract

The present invention relates to a communication distributor, and more particularly, to a communication distributor capable of self-power generation and having an auxiliary power means in an emergency situation, comprising: a communication distributor housing module including a first housing, a communication unit and a power unit installed on a stand attached to an inner wall of the housing, a second housing installed on the upper part of the communication distributor housing module, a solar cell module including a solar cell installed on a surface of the second housing, and a solar cell inverter and a battery installed inside the second housing, wherein the power unit is connected to receive power independently from an external power source connected through a wiring pass-through hole and the solar cell module, so that even if a problem occurs in a transmission facility between a power supply source and the communication distributor housing and the power supply is interrupted, a means for receiving an emergency power supply is provided, and at the same time, the communication distributor is manufactured compactly with a small occupied space, so that the choice of an installation location is relatively free.

Description

Communication distributor

The present invention relates to a telecommunications distributor, and more particularly to a telecommunications distributor capable of generating its own power and having auxiliary power means in emergency situations.

The wired communication distribution box is used for areas outside of the building or for maintaining a small number of lines. In addition, the wired communication distribution box has become widely used due to the development of communication technology today, and is now an essential device. In addition, the function and efficiency of the wired communication distribution box are further improved with copper cable switching boards or AGWs. In some cases, these wired communication boxes are simply called terminals or switching boards.

These wired communication boxes are essential for the use of communication devices in general homes and stores, and are installed in a form attached to the ground and utility poles. In the past, cases of boxes installed on the ground were often inconvenient to the appearance and movement, so new installations are being reduced, and newly installed communication distributor boxes are installed in a form attached to utility poles.

Meanwhile, the existing communication distribution box is supplied with power from an external facility such as a KEPCO pole through a wire routed to the internal power supply device of the communication distribution box. Therefore, there are frequent cases where users experience inconveniences due to problems with the wiring due to external or internal factors, or when the device stops due to natural factors such as lightning. Therefore, the need for a wired communication distribution box to improve these problems is being highlighted.

Patent Registration No. 10-2113073 (Publication Date: May 20, 2020)

Accordingly, the present invention provides a wired communication distributor which is equipped with a means for supplying emergency power even when power supply is interrupted due to a problem in the transmission equipment between a power supply source and a communication distributor body, and which is manufactured compactly with a small occupied space, allowing relatively free choice of installation location.

In order to achieve these purposes, a communication distributor according to the present invention comprises a first housing having a door with a sealed packing attached to an inner edge installed on the front side and a wiring pass-through hole and an air circulation slit formed on the bottom surface, a communication distributor housing module including a communication unit and a power unit installed on a stand attached to an inner wall of the housing, a second housing installed on the upper part of the communication distributor housing module, a solar cell module including a solar cell installed on the surface of the second housing, and a solar cell inverter and a battery installed inside the second housing, wherein the power unit is connected so as to be able to receive power independently from an external power source connected through the wiring pass-through hole and the solar cell module.

Here, the second body is preferably formed with an inclined surface as the upper surface, and the solar cell is installed on the inclined surface, so that the solar cell increases the solar radiation incidence efficiency and at the same time reduces the occupied volume of the second body, thereby minimizing interference between surrounding devices and the second body.

In this case, the second body is preferably rotatably coupled to the first body, making it extremely easy to avoid interference with surrounding objects, and allowing selection of the optimal sunlight incidence angle depending on the installation location.

In addition, the first or second body preferably has a protruding rotary sleeve or rotary shaft, and the second body or the first body has a joining hole formed into which the rotary sleeve or rotary shaft can be inserted, so that the horizontal angle of the solar cell module can be manually adjusted without separate power consumption.

At this time, a stopper is preferably protruded on the surface of the rotating sleeve or the rotating shaft, and a corresponding stopper is formed on the inner surface of the coupling hole to stop the rotation of the stopper, thereby limiting the rotation angle of the second body, thereby preventing twisting of the power cable connecting the second body and the first body.

In particular, the joining hole may be formed in a layered form, with an axial rotation hole formed with a diameter corresponding to the diameter of the sleeve or the rotation shaft, and a stopper rotation hole having a diameter larger than the axial rotation hole so that the stopper can rotate.

The communication distributor according to the present invention is provided with a means for supplying emergency power even when power supply is interrupted due to a problem in the transmission equipment between a power supply source and a communication distributor body, and at the same time, it is manufactured compactly with a small occupied space, so that the installation location can be selected relatively freely.

Figure 1 is a diagram showing the overall configuration of a communication distributor according to the present invention.
Figures 2a and 2b are perspective views sequentially showing the operational states of a communication distributor according to the present invention.
FIG. 3a is a partial perspective view showing a rotating sleeve in a communication distributor according to the present invention;
Figure 3b is a partial perspective view showing a coupling hole in a communication distributor according to the present invention.
Figure 3c is a conceptual diagram showing the coupling principle of the above-mentioned rotating sleeve and the above-mentioned coupling hole.
Fig. 4a is a side view of the solar cell module in Fig. 2a;
Fig. 4b is a rear perspective view of the solar cell module of Fig. 4a;
Figure 5 is a drawing showing a plan view, side view, and bottom view centered on the front perspective view of the communication distributor body module in Figure 2a.

The specific structural and functional descriptions presented in the embodiments of the present invention are merely exemplified for the purpose of explaining embodiments according to the concept of the present invention, and the embodiments according to the concept of the present invention may be implemented in various forms. In addition, it should not be construed as being limited to the embodiments described in this specification, but should be understood to include all modifications, equivalents, or substitutes included in the spirit and technical scope of the present invention.

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

The communication distributor according to the present invention is composed of a communication distributor housing module (10) similar to a conventional communication distributor housing as illustrated in FIG. 1, and a solar cell module (20) for supplying emergency power to the communication distributor housing module (10).

The communication distribution unit body module (10) includes a first body (11) which is a case member having a constant volume as shown in Fig. 1, and the inside of the first body (11) includes a communication module device, a wired terminal for a line, a power supply device, a current blocking device, and an exhaust circulation device (not shown).

And the communication distribution box module (10) is provided with a first box (11) that can be opened and closed to protect the devices built inside. Here, the name first box (11) is used to distinguish it from the second box (21) provided in the solar cell module (20) to be described later.

In addition, the first body (11) is provided with a locking means (14) on a door whose opening and closing is controlled by an opening and closing cylinder (not shown) or whose opening and closing speed can be controlled, and is manufactured so that it can be locked, and a pole attachment hook (18) that can be attached to a pole can be provided on the back.

Meanwhile, a terminal and power supply device holder (13a) on which various devices such as the communication module device and power supply device can be installed may be provided inside the first body (11). At this time, a holder (13b) for fixing the communication module may be provided separately.

In addition, a sealing packing (17) is provided on the inner edge of the door to prevent moisture or foreign substances from penetrating into the first body (11).

The solar cell module (20) is composed of a second housing (21) installed on the upper part of a communication distributor housing module (10) as shown in FIG. 2a, a solar cell (22) installed on the surface of the second housing (21), and a solar cell inverter (23) and battery (24) installed inside the second housing (21) as shown in FIG. 4b.

Here, the second body (21) is formed with an inclined surface on the upper surface, and the solar cell (22) can be installed on the inclined surface as shown in Fig. 2a. Accordingly, the second body (21) can be manufactured in a triangle shape when viewed from the side as shown in Fig. 4a. Therefore, by installing the solar cell (22) on the inclined surface, the solar irradiance efficiency increases, and at the same time, the occupied volume of the second body (21) decreases, so that interference between various devices installed around the second body (21) and the second body (21) can be minimized.

At this time, the communication housing module (10) is installed so that it can receive power supply from two power sources, i.e., two ways. Here, one of the two power sources can be an external power pole or other power source, as in a typical communication distribution housing, and the other can be a solar cell module provided for emergency power generation.

Accordingly, the communication distributor according to the present invention can normally receive power from an external power source, and when damage, aging, or failure occurs in the system receiving power from the external power source, it can immediately receive power through the solar cell module (20).

In particular, the second body (21) is rotatably connected to the first body (11), making it extremely easy to avoid interference with surrounding objects, and the optimal sunlight incidence angle can be selected according to the installation location.

Since conventional communication distributors are installed in an external environment, they are mainly installed in locations where there are street trees, fire terminal boxes, or electrical equipment around utility poles, and therefore, when a solar cell module (20) is installed on the upper portion of a communication distributor like that of the present invention, the volume increases, which may cause interference with surrounding objects and may create an obstacle to the solar cell (22) receiving sunlight.

To solve this problem, the communication distributor according to the present invention can avoid interference by having the upper solar cell module (20) rotatable, and also, since the solar cell module (20) can rotate horizontally, the direction can be adjusted to face an angle that can receive optimal sunlight, so that both interference avoidance and power charging due to the generation of solar cell module (20) can be achieved.

More specifically, looking at the structure in which the second body (21) can be rotated relative to the first body (11), as shown in FIGS. 3a to 3c, a rotation sleeve (12) or a rotation shaft (not shown) protrudes from the first body (11) or the second body (21), and a joining hole (25) into which the rotation sleeve (12) or the rotation shaft can be inserted is formed in the second body (21) or the first body (11), so that the horizontal angle of the solar cell module (20) can be manually adjusted without separate power consumption.

In FIGS. 3A to 3C, a rotating sleeve (12) is formed on the upper surface of the first body (11), and a joining hole (25) is formed on the lower surface of the second body (21). However, this is not necessarily limited to this form. Instead of the rotating sleeve (12), a rotating shaft (not shown) may be formed, and the rotating sleeve (12) or the rotating shaft may be formed on the lower surface of the second body (21) instead of the upper surface of the first body (11). In addition, the joining hole (25) may be formed on the upper surface of the first body (11).

In addition, a stopper (121) is protruded on the surface of the rotating sleeve (12) or the rotating shaft as shown in FIG. 3a, and a corresponding stopper (253) is formed on the inner surface of the coupling hole (25) to stop the rotation of the stopper (121) as shown in FIG. 3b, thereby limiting the rotation angle of the second housing (21), and preventing twisting of a power cable that connects the second housing (21) and the first housing (11) to supply power.

However, in a situation where both the stopper (121) and the rotary sleeve (12) must rotate, there is a problem in that if the inner diameter of the joining hole (25) becomes large enough to allow rotation of the stopper (121), the rotary sleeve (12) cannot receive rotational support.

Therefore, in the communication distributor according to the present invention, as shown in FIG. 3b, the coupling hole (25) may be formed in a form in which an axial rotation hole (251) formed with a diameter corresponding to the diameter of the rotation sleeve (12) or the rotation shaft, and a stopper rotation hole (252) having a diameter larger than the axial rotation hole (251) and thereby allowing the stopper (121) to rotate are formed in layers.

That is, as shown in Fig. 3c, the stopper rotation hole (252) and the shaft rotation hole (251) can be formed in a form in which they are layered on each other but form a single space.

Accordingly, the communication distributor according to the present invention can function as a communication distributor in important situations by receiving power on its own even in an emergency situation where power cannot be supplied from an external source.

The present invention described above is not limited to the above-described embodiments and the attached drawings, and it will be apparent to a person skilled in the art to which the present invention pertains that various substitutions, modifications, and changes are possible within a scope that does not depart from the technical spirit of the present invention.

10: Communication distributor hull module 11: 1st hull
12: Rotating sleeve 13a: Terminal and power equipment holder
13b: Stand for fixing communication module 14: Locking means
15: Wiring hole 17: Sealing packing
18: Hook for attaching to telephone pole 19: Air circulation slit
20: Solar cell module 21: Second hull
22 : Solar cell 23 : Inverter
24: Battery 25: Combination hole
121: Stopper 251: Axis rotation hole
252: Stopper rotation hole 253: Corresponding stopper

Claims (6)

A communication distributor housing module comprising a first housing having a door with a sealing packing attached to the inner edge installed on the front side and a wiring passage hole and an air circulation slit formed on the bottom side, and a communication unit and a power unit installed on a stand attached to the inner wall of the housing;
A solar cell module comprising a second body installed on the upper part of the communication distributor body module, a solar cell installed on the surface of the second body, and a solar cell inverter and battery installed inside the second body;
The above power unit is a communication distributor that is connected so that it can independently receive power from an external power source connected through the above wiring pass-through hole and the solar cell module. In the first paragraph,
The upper surface of the second body is formed as an inclined surface, and the solar cell is installed on the inclined surface, so that
The above solar cell is a communication distributor characterized in that the solar radiation efficiency is increased while the occupied volume of the second body is reduced, thereby minimizing interference between surrounding devices and the second body. In the second paragraph,
A communication distributor characterized in that the second body is rotatably connected to the first body, making it extremely easy to avoid interference with surrounding objects, and allowing selection of the optimal sunlight incidence angle depending on the installation location. In the third paragraph,
A rotating sleeve or rotating shaft protrudes from the first or second body,
A joining hole into which the rotating sleeve or rotating shaft can be inserted is formed in the second or first body,
A communication distributor characterized in that the horizontal angle of the solar cell module can be manually adjusted without separate power consumption. In paragraph 4,
A stopper is protruded on the surface of the above rotating sleeve or rotating shaft,
A corresponding stopper is formed on the inner surface of the above-mentioned joining hole to stop the rotation of the above-mentioned stopper,
A communication distributor characterized in that the rotation angle of the second body is limited, thereby preventing twisting of a power cable connecting the second body and the first body. In paragraph 5,
A communication distributor characterized in that the above coupling hole is formed in a layered form with an axial rotation hole formed with a diameter corresponding to the diameter of the rotating sleeve or rotating shaft, and a stopper rotation hole having a diameter larger than the axial rotation hole so that the stopper can rotate.

Images