KR101332683B1 - Cctv control box for uninterruptible monitoring using a solar module - Google Patents

Abstract

The present invention includes a support stand, a closed-circuit television (CCTV) installed to the support stand monitoring the fixed surveillance zone, a wireless monitoring system that is installed the stand and controls the CCTV and includes a main body with a solar module on the surface. The CCTV is charged by the electricity produced from the solar module and it comprises of the first axis battery that runs in case of emergencies which gets electricity from the solar module, and the second axis battery which is used before the first axis battery. Also, the invention generates the solar module at least or more on either the upper, lower, and left and right side of the main body, and it has a technical feature that the main body is able to control the angle of the solar module.

Description

CCTV enclosure for uninterrupted surveillance using photovoltaic module {CCTV CONTROL BOX FOR UNINTERRUPTIBLE MONITORING USING A SOLAR MODULE}

The present invention relates to a housing of a surveillance CCTV, and more particularly to an uninterruptible surveillance CCTV enclosure using a solar module.
The present invention is to use the power by condensing and converting sunlight, more specifically for uninterruptible monitoring using a solar module that can operate CCTV uninterrupted by using the solar power and commercial power together It's about a CCTV enclosure.

The present invention is to form a photovoltaic module in the enclosure, and to adjust the angle of the photovoltaic module to expand the area condensed on the photovoltaic module uninterruptible using a photovoltaic module that can maximize the amount of light collected It is about surveillance CCTV enclosure.

The present invention is to form a reflecting plate on the outside of the solar module, to the uninterruptible surveillance CCTV enclosure using a solar module that is reflected through the reflector to the sunlight reflected to the outside of the solar module to the solar module. It is about.

The present invention includes a first storage battery, a second storage battery and an auxiliary storage unit in the enclosure, by using the first storage battery or the second storage battery to enable the operation of CCTV even in the event of a power failure such as power outage, the power of the auxiliary storage unit The present invention relates to a CCTV enclosure for uninterruptible monitoring using a solar module that can increase the amount of storage by supplying the first storage battery or the second storage battery.

In general, CCTV (Closed Circuit TeleVision) is installed in the surveillance range and is supplied with power to monitor the set surveillance range.

At this time, the power supplied to CCTV is usually supplied by Korea Electric Power, which is provided with a separate enclosure (electric box) around the CCTV installed, and converts the power supplied by the enclosure into the power available for CCTV to distribute the power.

However, it is exposed to the risk of electric power accident because the electric power supplied to CCTV may be cut off or the power may be cut off due to a deliberate loss due to electric accidents such as electric line leakage, power supply unstable power supply and local power failure.

As such, when the power supplied to the CCTV is cut off, there is a problem that the operation of the CCTV is interrupted. There is a problem that does not function properly.

In addition, as described above, in order to monitor a crime or an accident occurring within the detection range of the CCTV, the CCTV must be operated at all times, and thus there is a problem in that required power consumption increases.

In order to solve the above problems, recently, technologies that use natural energy to convert power and use the converted power have been developed. Among them, photovoltaic power generation that can be used for a long time without depletion of resources is attracting attention. .

Photovoltaic power generation means concentrating solar light in a solar cell or a photovoltaic module to perform power generation.

As described above, the principle of photovoltaic power generation using a photovoltaic module is performed by a photovoltaic effect, wherein the photovoltaic effect includes a PN junction portion and a rectifying action of a P-type semiconductor and an N-type semiconductor. When the solar light is incident on the interface between the metal and the semiconductor, electrons and holes made in the semiconductor are separated due to the contact potential difference, and thus, photovoltaic power generated by different kinds of electricity in both materials is generated.

For example, when light is incident on the solar module from the outside, electrons in the conduction band of the P-type semiconductor are excited to the valence band by the incident light energy, and the electrons thus excited are P One electron-hole pair (EHP) is generated inside the semiconductor, and electrons in the electron-hole pair generated in this type are transferred to the n-type semiconductor by an electric field existing between the PN junctions. To supply current to the outside.

Such a solar module stores a direct current power source in a storage battery, converts the stored direct current power source into an alternating current power source through an inverter device, and supplies power to another load.

As described above, the solar power distribution panel is disclosed in Korean Patent Publication No. 10-2007-0089391 with respect to a technology for supplying power through a storage battery of a solar module.

The technology described above can reduce power consumption by supplying the generated electricity generated by solar power as part of the electricity supply of the distribution panel, and utilize natural energy that can supply power even in the event of power failure. A first storage battery for power and a second storage battery for uninterruptible power supply.

In other words, the above-described technology may use both a commercial power and a first storage battery, and supply power through the second storage battery even in a power failure event.

However, in the event of a power failure such as a power failure or a power failure, the recovery time until the power supply is resumed is not constant. Accordingly, when the recovery time is long, the storage battery and the storage battery used with commercial power are prepared. There is a realistic difficulty to prepare alone.

In addition, when the first battery and the second battery are used while using or storing power, when the storage battery is not charged to be suitable for use, power may not be supplied to the device by not using both batteries.

Therefore, the method further includes means for storing auxiliary power, which can increase the use of solar power, thereby minimizing the use of commercial power, thereby maximizing the reduction of power consumed, and intentional power failure or power. It is required to develop a technology capable of maximizing the stability of power usage by increasing the amount of backup power used in an emergency situation such as power failure due to an accident.

The object of the present invention to be devised to meet the above requirements, to provide an uninterruptible surveillance CCTV enclosure using a solar module that can minimize the power consumption required for CCTV operation by using a combination of commercial power and solar power. There is.

Another object of the present invention is to provide an uninterruptible surveillance CCTV enclosure using a solar module that can increase the solar light (concentration) collected by the solar module through the angle control.

Still another object of the present invention is to provide a CCTV enclosure for an uninterruptible monitoring using a solar module that can operate a CCTV in the event of a power failure such as a power failure, including a first storage battery, a second storage battery and an auxiliary storage unit in the enclosure. .

Still another object of the present invention is to minimize the power consumption required for CCTV operation by using the power charged in the second storage battery before commercial power, and the power charged in the auxiliary storage unit is stored in the first storage battery or the second storage battery. Provided to provide an uninterruptible surveillance CCTV enclosure using a solar module that can increase the use of the first storage battery or the second storage battery.

The present invention to solve the above problems, the support is placed on the ground; CCTV for monitoring the monitoring area is installed on the support; And an enclosure installed on a support to control the CCTV and having a solar module formed on an outer surface thereof. The CCTV system for an uninterruptible monitoring, wherein the enclosure is charged with power by a solar module and used in an emergency. ; And a second storage battery which is charged with the solar module and used before commercial power.

In another aspect, the present invention, the solar module is formed on at least one or more of the upper surface, the lower surface, the left side and the right side of the enclosure, the enclosure is characterized by the ability to adjust and control the angle of the solar module.

The present invention has the effect of minimizing the power required for CCTV operation because it can be used with photovoltaic power and commercial power.

The present invention has the effect of securing the power for CCTV operation until the supply of commercial power is restored because the power charged with solar light can be used even in the event of a power failure such as power failure of commercial power. .

Since the angle of the photovoltaic module can be adjusted according to the control of the enclosure, the present invention can condense solar light more effectively.

The present invention can minimize the power consumption required for CCTV operation by using the power charged in the second storage battery before commercial power, and can supply power charged in the auxiliary storage unit to the first storage battery or the second storage battery. It has the effect of increasing the amount of use of the first storage battery or the second storage battery.

Figure 1 shows the overall configuration of the CCTV enclosure for uninterrupted monitoring using a solar module according to the present invention.
Figure 2 shows the configuration of the enclosure in the CCTV enclosure for uninterrupted monitoring using a solar module according to the present invention.
Figure 2a shows an example of the angle adjusting means for adjusting the angle of the photovoltaic module formed in the enclosure in the CCTV enclosure for uninterruptible monitoring using the photovoltaic module according to the present invention.
Figure 3 shows an example of a reflector plate formed on the outside of the solar module in the CCTV enclosure for uninterrupted monitoring using the solar module according to the present invention.
Figure 4a schematically shows the configuration of the CCTV enclosure for uninterrupted monitoring using a solar module according to a first embodiment of the present invention.
Figure 4b shows a system configuration of an uninterruptible surveillance CCTV enclosure using a solar module according to a first embodiment of the present invention.
Figure 5a schematically shows the configuration of the CCTV enclosure for uninterrupted monitoring using a solar module according to a second embodiment of the present invention.
Figure 5b shows a system configuration of the CCTV enclosure for uninterrupted monitoring using a solar module according to a second embodiment of the present invention.
6 shows a system configuration of an uninterruptible surveillance CCTV enclosure using a solar module according to a third embodiment of the present invention.
FIG. 7 illustrates an example of a monitor of a control room for remote control in an uninterruptible surveillance CCTV enclosure using a solar module according to a third embodiment of the present invention.

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary meanings and the inventor can properly define the concept of the term to describe its invention in the best possible way And should be construed in accordance with the principles and meanings and concepts consistent with the technical idea of the present invention.

Therefore, the embodiments described in the present specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and are not intended to represent all of the technical ideas of the present invention. Therefore, various equivalents And variations are possible.

Before describing the present invention with reference to the accompanying drawings, it should be noted that the present invention is not described or specifically described with respect to a known configuration that can be easily added by a person skilled in the art, Sounds good.

In other words, this specification can mainly describe the configuration (for example, the outer and inner configuration of the enclosure and the solar module) for achieving the object according to the present invention, whereby the present invention is not limited to the configuration It is emphasized that it does not.

The present invention, by converting the power of the sunlight (light) into the operating power and converting the power to use, such as CCTV, by using a combination of commercial power and solar power charged with sunlight can operate CCTV uninterrupted The present invention relates to a CCTV enclosure for uninterrupted surveillance using a photovoltaic module.

An example of the structure of the CCTV enclosure for an uninterruptible monitoring using a solar module according to the present invention will be described below with reference to FIGS. 1 to 3.

Figure 1 shows the overall configuration of the CCTV monitor for uninterrupted monitoring using the solar module according to the present invention, Figure 2 shows the configuration of the enclosure in the CCTV enclosure for uninterruptible monitoring using the solar module according to the present invention. Figure 2a illustrates an example of an angle adjusting means for adjusting the angle of the photovoltaic module formed on the enclosure in the CCTV enclosure for uninterrupted monitoring using the photovoltaic module according to the present invention.

In addition, Figure 3 shows an example of a reflector formed on the outside of the solar module in the CCTV enclosure for uninterrupted monitoring using the solar module according to the present invention.

As shown in FIG. 1 of the accompanying drawings, the present invention mainly includes a housing 100 for distributing power and controlling equipment, a support 200 installed on the ground, and a CCTV 300 for monitoring a set monitoring area. The solar module 400 is formed on the outer surface of the 100.

According to the accompanying drawings, the enclosure 100 and the CCTV 200 is installed on the support 200.

The enclosure 100 distributes and controls the power required for equipment such as CCTV.

At this time, the solar module 400 is formed on the outer surface of the enclosure 100 as described above.

Here, the solar module 400 is provided on at least one of the upper surface, the lower surface, the left side, and the right side of the enclosure 100.

In addition, the solar module 400 may be formed in the enclosure 100 to have a predetermined inclination, thereby widening the area where the solar light is collected so that the solar light can be incident efficiently.
In addition, according to other conditions, it is a matter of course that the black box device for dual monitoring with CCTV can be connected to the housing 100.
This is a configuration for achieving the purpose of the uninterruptible and supervised according to the present invention, this black box device is a well-known, commonly known technique generally known, and the detailed description is omitted.

The photovoltaic module 400 uses a conventional photovoltaic module in which photovoltaic cells 410 are collected (see FIG. 2) to receive sunlight and convert it into electric power.

The photovoltaic module 400 may be made of either a dual panel structure or a single layer panel structure stacked in a double layer.

It is sufficient to achieve the purpose of supplying power to the device by converting it into electricity through sunlight, and the present invention can use the power converted into sunlight regardless of the type of solar module. It is enough.

The present invention also includes an angle adjusting means 420 for connecting the enclosure 100 and the solar module 400 as shown in Figure 2a of the accompanying drawings.

The angle adjusting means 420 may control and adjust the angle of the solar module 400.

At this time, the angle control of the solar module 400 may be made automatically or manually according to the control of the enclosure 100, which will be described through the following embodiments.

In addition, according to Figure 2a of the accompanying drawings, the angle adjusting means 420 is formed between the enclosure 100 and the photovoltaic module 400, which is only an example and the present invention is not limited to the drawings. It is natural.

Therefore, the angle adjusting means 420, as shown in Figure 2 attached to one side of the photovoltaic module may be formed and adjusted, which is achieved only the purpose of controlling the angle of the photovoltaic module 400 manually or automatically Is enough.

In addition, the solar module 400 includes a reflecting plate 430 on the outside.

The reflector 430 reflects sunlight incident from the solar module 400 to be collected by the solar cell 410 of the solar module 400.

The reflective plate 430 is formed on at least one outside of the outside of the solar module 400 as shown in FIG. 3 of the accompanying drawings.

The CCTV system for an uninterruptible monitoring according to the present invention using the enclosure 100 including such a solar module 400 will be described through the first to third embodiments.

Example 1 CCTV system for uninterrupted monitoring through a battery

A first embodiment according to the present invention will be described with reference to FIGS. 4A and 4B of the accompanying drawings.

Figure 4a schematically shows the configuration of the CCTV enclosure for an uninterruptible monitoring using a solar module according to a first embodiment of the present invention, Figure 4b is an uninterruptible monitoring using a solar module according to a first embodiment of the present invention It shows the system configuration of the CCTV enclosure.

According to the first embodiment of the present invention according to the accompanying drawings, the first storage battery 110, the second rechargeable battery 120, the power cut-off unit 130, the accident detection unit 140, the power control unit (100) 150 and a direction controller 160 are included.

The first storage battery 110 is charged with electric power by the solar module, and is used as emergency power in the event of a power failure such as power failure under the control of the enclosure 100.

The second storage battery 120 is charged with power by the solar module, and is used before commercial power under the control of the housing 100.

However, in order for the second storage battery 120 to be used before commercial power, the amount of power charged in the second storage battery must be charged by a predetermined amount.

In other words, in the present invention, when the amount of charge of the second storage battery 120 is greater than or equal to a certain amount, the commercial power may be cut off under the control of the housing 100 and the power of the second storage battery 120 may be used.

In addition, when the charge amount of the second storage battery 120 is less than a predetermined amount, the supply of commercial power is resumed.

To this end, the enclosure 100 includes a power cutoff unit 130 and an accident detection unit 140.

The power cutoff unit 130 cuts off the supply of commercial power in order to use the electric power charged in the second storage battery before the commercial power.

As described above, the commercial power is cut off by the power cut-off unit 130, and the power charged in the second storage battery 120 is supplied to the CCTV.

The accident detecting unit 140 detects whether commercial power is smoothly supplied to the enclosure 100, and when supply of commercial power is not smooth, detects and determines a power accident to supply emergency power.

Accordingly, when the accident detection unit 140 detects an electric power accident, the electric power charged in the first storage battery 110 is used.

In this case, when the first storage battery 110 is used, the case 100 detects a power accident such as a power failure accident, and when a power accident is detected, the control room may be notified.

Therefore, in the event of a power accident, the relevant jurisdiction (for example, Korea Electric Power) can be notified of the accident quickly.

In addition, as described above, the enclosure 100 may distinguish whether the power supplied to the CCTV through the power cutoff unit 130 or the accident detecting unit 140 is cut off according to a power accident or cut off by the system. .

The power controller 150 controls the use of power to supply the device with the electric power charged in the first storage battery 110 or the second storage battery 120.

Accordingly, as described above, the power control unit 150 may control or supply the power of the first storage battery, or may control the power of the second storage battery.

The direction controller 160 adjusts and controls the angle of the photovoltaic module 400 formed in the enclosure 100.

In addition, the direction controller 160 may adjust and control the angle of the reflector 430 formed on the outside of the solar module 400. Therefore, sunlight can be efficiently collected.

In brief, the present invention according to the first embodiment, the first storage battery 110 or the second storage battery 120 supplies the power of each of the storage battery (110, 120) along with the commercial power in an emergency or normal, such as a power accident In the present invention, the electric power is charged by solar light in the order of the first storage battery 110 and the second storage battery 120.

In other words, the second storage battery 120 is preferentially charged over the first storage battery 110, which is used as an emergency power when power is not buffered in both the first storage battery 110 and the second storage battery 120. When the first storage battery 110 is fully charged while the first storage battery 110 is charged while preferentially charging power to the first storage battery 110, the second storage battery 120 is charged.

This has the advantage of ensuring emergency power at all times.

However, in the event of a power accident such as power failure of the commercial power, it may be difficult to maintain the power until the supply of commercial power is resumed with only the first battery and the second battery.

Therefore, it may further include an auxiliary storage unit other than the first storage battery and the second storage battery, this second embodiment of the present invention will be described with reference to Figure 5a and 5b of the accompanying drawings.

Example 2 CCTV system for uninterrupted monitoring further comprising an auxiliary storage

Figure 5a schematically shows the configuration of the CCTV enclosure for an uninterruptible monitoring using a solar module according to a second embodiment of the present invention, Figure 5b is an uninterruptible monitoring using a solar module according to a second embodiment of the present invention It shows the system configuration of the CCTV enclosure.

The present invention according to FIGS. 5A and 5B of the accompanying drawings further includes an auxiliary storage unit 170 in the enclosure 100. The direction control unit 160 further includes a scheduling setting module.

The auxiliary storage unit 170 according to the second embodiment charges power by the solar module 400, and powers the first storage battery 110 and the second storage battery 120 under the control of the enclosure 100. To supply.

The auxiliary storage unit 170 includes a charge amount detection module, and the charge amount detection module detects the amount of power charged in the first storage battery 110 and the second storage battery 120.

Accordingly, power may be supplied according to the amount of power charged in the first storage battery 110 and the second storage battery 120.

For example, the commercial power is cut off by the power cut-off unit 130, and the charged power is supplied to the second storage battery 120, and the second storage battery 120 has a preset setting (a charge amount of the second storage battery is 40). In the case of%, the power supply is intermittently controlled, and the auxiliary storage unit 170 receives power according to the charge amount detected by the charge amount detection module.

In other words, the amount of charge stored in the second storage battery is detected through the charge detection module of the auxiliary storage unit 170. In this case, when the amount of charge of the second storage battery 120 is detected as a predetermined amount of charge, the second storage battery is stored in the second storage battery. Supply power.

For example, when the amount of power storage of the second storage battery 120 is 40% as described above, when the power of the second storage battery 120 is set to interrupt the power, the power of the second storage battery 120 is detected to be 45% or less. When it is done, the secondary storage unit 170 supplies power.

Predetermined predetermined values (40% and 45%) described above are described to help the understanding of the present invention, which may vary depending on the operator's setting, and the above-described numerical values are not limited to the present invention. It is natural.

The power supply of the auxiliary storage unit 170 described above may be applied to the case of the first storage battery 110.

That is, the first storage battery 110 is a storage battery for charging power used in an emergency, and detects the amount of charge as described above to receive the charged power in the auxiliary storage unit 170.

In addition, although the control of the interruption and supply of the above power can be performed in the power control unit 150, it may be made in the control room.

In addition, adjusting and controlling the angle of the photovoltaic module 400 formed in the enclosure 100 may be performed by setting scheduling as described above, as well as manual operation of an operator.

In this case, the scheduling may be set differently according to a preset period such as quarter, semi-annual, season, and monthly, which is set differently according to the period because the height and the moving line of the sun vary according to the period.

According to other conditions, the scheduling may be set differently based on the amount of sunshine per region or the amount of incident light of sunlight according to latitude / longitude.

As described above, in the present invention according to the second embodiment, the first storage battery 110, the second storage battery 120, and the auxiliary storage unit 170 are included. In this case, the first battery 110 is charged by sunlight. The storage battery 110, the second storage battery 120, and the auxiliary storage 170 may be formed in the order.

Therefore, it is possible to increase the amount of power available in an emergency, so in the event of power failure such as power failure due to intentional loss or power failure due to power accident, more efficient use of emergency power can operate CCTV uninterruptedly. There is this.

The enclosure 100 of the CCTV system for uninterruptible monitoring according to the present invention described above can be remotely controlled by the control room, the present invention according to the third embodiment will be described with reference to FIG. 6 of the accompanying drawings.

Example 3. CCTV system for uninterrupted monitoring according to the remote control

6 shows a system configuration of an uninterruptible surveillance CCTV enclosure using a solar module according to a third embodiment of the present invention.

The present invention according to the third embodiment can be controlled remotely by setting the charge amount charged in the first storage battery 110 and the second storage battery 120 in the control room.

In this case, the remote control may be made by wireless or wired, which uses a conventional remote control communication system, and detailed description thereof will be omitted.

In addition, the remote control controls the power storage amount setting (A) for interrupting the power supply of the first storage battery 110 and the second storage battery 120 or the power storage amount setting (B) supplied with the power of the auxiliary storage unit 170. Accordingly, an interface (not shown) may be further included in the enclosure.

The power control is controlled by the power control unit 150 as described above, the power control unit 150 is included in the enclosure 100, which can be made by automatic control or manual control by the operator according to the configuration of the enclosure will be.

According to other conditions, the power control unit 150 may be controlled by the control room and may be made by automatic control or manual control by an operator, which will be described with reference to FIG. 7.

7 illustrates an example of a monitor of a control room for remote control in an uninterruptible surveillance CCTV enclosure using a solar module according to a third embodiment of the present invention, an example of operating with a mouse cursor (a) and a separate interface An example (b) to operate with is shown.

In FIG. 7 of the accompanying drawings, a charge amount setting A for interrupting power supply and a charge amount setting B for receiving power from the auxiliary storage unit are displayed on the control room screen.

In addition, in FIG. 7 of the accompanying drawings, an operation by a mouse cursor (FIG. 7 (a)) or an operation by a separate interface (FIG. 7 (b)) is performed.

Herein, the mouse cursor or a separate interface is merely a view for explaining an example of the operation according to the present invention, and it is emphasized that the present invention is not limited to the drawings. Therefore, of course, it can be operated by other operation methods other than the accompanying drawings.

In addition, in FIG. 7 of the accompanying drawings, the first storage battery or the second storage battery is displayed on the control room screen, and the storage battery is divided into a certain column (10 spaces in FIG. 7 and 100%).

At this time, in the charge amount setting A for interrupting the power supply, the power supply is set by displaying the number of columns (4 spaces and 40% in FIG. 7) corresponding to the set values in the division of the predetermined spaces.

In other words, the charge amount setting A for interrupting the power supply is a setting for interrupting the power supply of the corresponding battery when the amount of charge of the battery set as shown in FIG. 7 of the accompanying drawings reaches 40%.

The charging amount setting (B) supplied with power of the auxiliary storage unit is configured to receive auxiliary power by displaying as many columns (4.5 spaces and 45% in FIG. 7) as the set value in a certain column division.

That is, the charging amount setting (B) supplied with the power of the auxiliary storage unit is equal to or less than the charging amount (for example, the charging amount of the storage battery is set to 45% in the case of FIG. 7 of the accompanying drawings) of the storage batteries 110 and 120. If detected, it is a setting for receiving auxiliary power of the auxiliary storage unit 170.

In this manner, the setting of the first storage battery 110 or the second storage battery 120 can be controlled remotely.

Accordingly, the present invention according to the third embodiment, according to the recovery time until the power supply is resumed even in the event of an emergency, such as power outage due to intentional loss or power outage due to power accident, setting the charge amount of the battery 110, 120 Otherwise, the power supply can be controlled more efficiently.

In addition, even if the amount of sunlight (light) changes depending on the environmental requirements, such as the weather, it is possible to control the power supplied to the CCTV by changing the amount of charge of the battery, there is an advantage that can operate the CCTV efficiently.

In addition, in the third embodiment of the present invention, as shown in Figure 7 of the accompanying drawings it may be displayed on the control room screen so that the charge amount charged in the first storage battery 110 or the second storage battery 120.

As described above, in the present invention according to the first to third embodiments, when the solar light is collected and used as electric power, latitude / longitude may vary according to the region, and thus, the amount of sunshine in each region can be different.

In this case, it is possible to separately provide statistical data on the amount of sunshine or latitude / longitude of the area in which the system according to the present invention is installed, and guide the installation direction of the enclosure in which the solar module is formed based on the statistical data.

In the systems according to the present invention installed in each region, it is made in the control room to check the charge amount charged through the solar (light), for this purpose, each system has a GPS (Global Positioning System) receiving module (not shown) It is further included in the enclosure 100 and can be displayed on the control room screen.

For example, if the system according to the present invention installed in the C region is less than the average charge amount of the systems according to the present invention installed in another region, it is displayed so that it can be checked in the control room. The system according to the present invention and the system according to the present invention having a less than average value are displayed in different colors.

According to other conditions, the present invention may guide the filling amount of the auxiliary storage unit to the control room based on the filling amount of the auxiliary storage unit 170.

At this time, guiding the filling amount of the auxiliary storage unit guides additional information about the auxiliary storage unit according to the average of the buffer or the filling amount of the auxiliary storage unit based on the statistical data on the amount of incidence according to the amount of sunshine or the hardness / latitude of each region. will be.

For example, as shown in the third embodiment, the charge amount charged in the auxiliary storage unit is insufficient in the system according to the present invention installed in one region such as displaying the charge amount of the first storage battery, the second storage battery and the auxiliary storage unit on the control room screen. It can be determined by the control room or automatically determined by the system.

In this case, in order to automatically determine that the charging amount of the auxiliary storage is always insufficient, the system automatically calculates an average value of the auxiliary storage part charging amount detection module (not shown) that detects the charging amount of the auxiliary storage part and the auxiliary battery part. A calculation module (not shown) may be further included.

In the auxiliary storage unit of a certain system according to the present invention, the secondary storage unit detected by the auxiliary storage unit charge amount detection module is divided by a predetermined period, and the secondary storage unit for a certain period by the average value calculation module When the average value of the charged amount is calculated and the calculated average value is less than a predetermined standard, the system determines that the amount of charge is always insufficient in the auxiliary storage unit.

In other words, the auxiliary storage of the system determines that the amount of power supplied to the first storage battery or the second storage battery is large.

Therefore, since the auxiliary storage unit may be further provided in the enclosure 100 installed in the corresponding system, or the amount of charge charged in the auxiliary storage unit or the storage unit size of the auxiliary storage unit may be different, the sun according to different sunshine or latitude / longitude according to regions. It has the effect of operating the system more efficiently based on the incident amount of light.

As described above, the present invention can be used together with commercial power, including a first storage battery and a second storage battery for charging power converted by photovoltaic light collected by a solar module formed in a housing, so that the consumption required for device operation It has the effect of minimizing the power.

According to the present invention, power can be supplied using a first storage battery precharged by a solar module even during an emergency such as supply of commercial power is cut off, thereby securing power for equipment operation until commercial power is supplied. It has an effect.

Since the angle of the photovoltaic module can be adjusted according to the control of the enclosure, the present invention can condense solar light more effectively.

The present invention uses the power charged in the second storage battery prior to the commercial power under the control of the enclosure, and when the power of the second storage battery is less than a certain amount can be provided with the power of the auxiliary storage, solar light According to the effect that you can use longer power.

2 to 7 are merely the main points of the present invention. As various designs can be made within the technical scope of the present invention, the present invention is limited to the configurations of Figs. 2 to 7 It is self-evident.

100: enclosure 110: first storage battery
120: second storage battery 130: power cut off
140: accident detection unit 150: power control unit
160: direction control unit 170: auxiliary storage unit
200: support 300: CCTV
400: solar module 410: solar cell
420: angle adjustment means 430: reflector

Claims (11)

Supports placed on the ground;
CCTV for monitoring the monitoring zone is installed on the support; And
In the uninterruptible surveillance CCTV system including a; installed on the support to control the CCTV, the solar module is formed on the outer surface;
The housing is,
A first storage battery charged with power by the solar module and used in an emergency;
A second storage battery charged with power by the solar module and used before commercial power; And
An auxiliary storage unit in which power is charged by the solar module; Including,
The auxiliary storage unit,
Uninterruptible surveillance CCTV enclosure using a solar module, characterized in that for supplying power to the first storage battery or the second storage battery according to the control of the housing.
The method according to claim 1,
The solar module,
Uninterruptible surveillance CCTV enclosure using a solar module, characterized in that formed on at least one or more of the top, bottom, left and right sides of the enclosure.
The method according to claim 1,
Uninterruptible surveillance CCTV enclosure using a solar module, characterized in that it further comprises an angle adjusting means for adjusting the angle of the solar module.
The method according to claim 1,
Further comprising angle adjusting means for adjusting the angle of the solar module,
The angle adjusting means,
CCTV enclosure for uninterrupted monitoring using a solar module, characterized in that the angle is automatically adjusted according to a predetermined scheduling.
The method of claim 4,
The predetermined scheduling is a CCTV enclosure for an uninterruptible monitoring using a solar module, characterized in that set according to any one selected from quarter, semi-annual, seasonal and monthly.
delete The method according to claim 1,
The auxiliary storage unit,
Detects the amount of charge of the first storage battery or the second storage battery,
When the detected charge amount is less than a predetermined amount, CCTV box for uninterruptible monitoring using a solar module, characterized in that to supply power to the storage battery.
The method according to claim 1,
The housing is,
When the charge amount of the second storage battery is more than a certain amount, the CCTV enclosure for the uninterruptible monitoring using a solar module, characterized in that the supply of commercial power is cut off, and the power of the second storage battery is controlled to be used.
The method according to claim 1,
CCTV enclosure for uninterrupted monitoring using a solar module, characterized in that the reflector is installed on the outside of the solar module.
The method of claim 9,
The reflector includes:
CCTV enclosure for uninterrupted monitoring using a solar module, characterized in that the angle is adjusted according to the control of the enclosure.
The method according to claim 1,
Further comprising a control room for remotely controlling the first storage battery or the second storage battery,
The remote control,
A charge amount setting for controlling power supply of the first storage battery or the second storage battery and
Uninterruptible monitoring CCTV enclosure using a solar module, characterized in that for controlling the charge amount of the first storage battery or the second storage battery is supplied with the power of the auxiliary storage.

Images