KR20210148680A - Boards that can be monitored and contain dampers and the monitoring method using it - Google Patents

Abstract

The present invention relates to a board capable of monitoring and including a damper and, more specifically, to a board capable of monitoring and including a damper, which is capable of checking a board condition through external monitoring in real time, has a board fastening method in a sliding manner, changes an internal PCB surface to an insulation board material, and has a damper attached for reducing an impulse.

Description

Boards that can be monitored and contain dampers and the monitoring method using it

The present invention relates to a board that can be monitored and includes a damper and a monitoring method using the same, and more particularly, it is possible to check the state of the board in real time through external monitoring, and the board fastening method changed to a sliding method and the inner PCB surface are separated by an insulating board It relates to a board including a damper and a monitoring method using the same, which can be monitored by attaching a damper in order to change the material and reduce the impact of the board.

In general, photovoltaic power generation systems can be divided into stand-alone and grid-connected types according to their operation methods.

The stand-alone type is a system that uses only the power of the solar power generation itself and is independent of the grid regardless of the grid line (commercial power), and the grid-connected system is a type in which the output of the solar power generation system is connected to the grid line.

The stand-alone type is installed in an area where commercial power cannot be used, such as an isolated area, and the grid-connected type is applied to houses, etc., and uses the power generated from the solar cell for its own load, and the surplus power is transmitted back to the grid, and the amount of insolation is insufficient. Or at night, power is supplied from the grid line.

However, since all of these conventional grid-connected photovoltaic power generation systems can be used only in connection with the grid, there is a problem that it is insufficient to prepare for the case where electricity cannot be supplied from the grid line due to a failure or a power outage.

In addition, since the power generation system must always be connected to the grid line, there is a problem that the system cannot be used in various places due to poor mobility.

Meanwhile, in general, a DC-DC converter is a device that receives a DC (direct current) input and supplies a DC (direct current) output.

The transformer of the DC-DC converter may simply have a structure including two windings and a core between the two windings.

When electricity flows through one of the two windings, magnetic force is generated, and this magnetic force uses the principle of generating electricity in the other winding, and Lenz's law is applied.

However, since the DC-DC converter is integrally mounted on the board together with the input and output parts, in case of failure, the entire board needs to be replaced, which raises the maintenance cost.

In addition, there was a problem that the condition of the board deteriorated due to ultraviolet rays from the sun, and when an external shock was applied, there was a problem that caused an accident that caused it to be destroyed or the solder inside it fell

Korea Patent Publication No. 2013-0029875 Korean Patent Publication No. 2019-0111690 Korean Patent Publication No. 2019-0111001

The present invention has been made to solve the above problems, and when power is applied to the board (eg, DC-DC converter, etc.) by attaching a BT module or a WiFi module, monitoring that enables real-time board status confirmation through external monitoring is possible and to provide a board including a damper.

In addition, the present invention is a DC / DC converter by changing the sliding method instead of the bolting method

The purpose of this is to provide a board including a damper and monitoring that can increase disassembly/installation work time and convenience since the main board and sub-board can be replaced without the need for a separate tool when a problem occurs.

In addition, an object of the present invention is to increase the operational reliability of the DC/DC converter by changing the inner PCB surface to an insulating board material to block electromagnetic waves between devices.

In addition, an object of the present invention is to provide a board including a damper and capable of monitoring by attaching dampers to four corners of the case so as to reduce the impact of the board and minimize damage to the board.

An object of the monitoring system according to the present invention is to provide a board including a damper capable of monitoring a converter operation state, solar power generation amount, power consumption of a load, etc. according to values measured from each sensor.

In addition, an object of the present invention is to provide a board including a damper and capable of monitoring by attaching a BT module or a WiFi module inside the board to check the real-time board status through external monitoring when power is applied to the board.

In order to solve the above problems, the present invention attaches a BT (Bluetooth) module or a WiFi module to enable real-time confirmation of the board status through external monitoring when power is applied to the board, and is located in the four corners of the case to reduce the impact of the board. Attach the damper.

When power is applied to the board by attaching a BT module or a WiFi module to the board, real-time board status can be checked through external monitoring.

The sliding coupling shape of the board is in the shape of a “r” and prevents separation by force in the upper direction or the force in the lateral direction.

The inner PCB surface of the board is coated with an insulating material.

A UV stabilizer is applied to the surface of the PCB on an insulating material, and the UV stabilizer is HALS.

The UV stabilizer, HALS, serves to stop a chain of photo-oxidation groups by annihilating free radicals generated by photolysis from UV rays.

A metal plate is installed on the cut surface of the sliding board to be electrically connected.

It further includes a sensor capable of detecting the movement of the damper.

The present invention includes the steps of counting and storing the 'number of failures' for each DC-DC converter and determining the 'number of failures'; When the 'number of failures' occurs less than three times, the failure diagnosis processing step is terminated, and when the "number of failures" occurs three or more times, the monitoring system notifies the administrator of the failure; checking, by the manager, according to the failure notification in monitoring and taking action; When the administrator confirms and the action is completed, the 'number of failures' is reset to '0' (S140) and the failure diagnosis step is terminated; a non-real-time monitoring step including; monitoring the converter operation status, solar power generation amount, and load power consumption in real time through

When it is determined through the monitoring system that the DC-DC converter is out of the setting range and an abnormal situation has occurred, the manager terminal, which is the first alarm target, is absent or does not receive a call within a certain period of time, the second and third manager terminals In turn, the contact is forwarded; In the case of the first manager, controlling to transmit abnormal situation response manual information; monitoring is possible and includes a damper.

In the present invention as described above, when a problem occurs in the board (DC/DC converter), the main board and the sub-board can be replaced without the need for a separate tool, so that the disassembly/installation work time and convenience can be increased.

In addition, according to the present invention, when power is applied to the board (DC-DC converter) by attaching a BT module or a WiFi module, the status of the board can be checked in real time by external monitoring.

According to the present invention, by combining two or more boards connected by a metal plate or a network in a sliding manner, only the defective board can be partially replaced without the need to replace the entire board in case of failure, and the time and convenience of disassembling/installing the board can be increased. .

In addition, the present invention can reduce the impact of the board by attaching an elastic damper to the four corners.

In addition, the present invention uses a UV stabilizer on the insulating material of the PCB surface. As a UV stabilizer, HALS serves to stop the chain photooxidation reaction by annihilating the free radicals generated by photolysis from UV rays, thereby extending the service life. Maintaining physical properties can be maximized.

In addition, the present invention can improve the insulation properties of the board itself by changing the inner PCB surface to an insulating material.

In addition, according to the present invention, the operation reliability of the DC/DC converter can be improved by changing the inner PCB surface of the board to an insulating board material to block electromagnetic waves between devices.

In addition, the present invention can objectively determine the external shock state by analyzing the frequency spectrum using the acceleration vibration sensor.

1 is a perspective view showing the configuration of a board capable of monitoring and including a damper according to the present invention.
2 is a view showing in detail a bottom surface of a board capable of monitoring and including a damper according to an embodiment of the present invention.
3 is a view showing a collection of images of a damper of a board capable of monitoring and including a damper according to an embodiment of the present invention.
4 is a view showing a bottom surface of an upper end of a damper made according to another embodiment of the present invention.
5 is a view showing an upper side of a lower end of a damper according to another embodiment of the present invention.
6 is a diagram illustrating a method for monitoring a DC-DC converter or a solar panel according to another embodiment of the present invention.

In order to fully understand the present invention, preferred embodiments of the present invention will be described with reference to the accompanying drawings. Embodiments of the present invention may be modified in various forms, and the scope of the present invention should not be construed as being limited to the embodiments described in detail below. This example is provided to more completely explain the present invention to those of ordinary skill in the art. Accordingly, the shapes of elements in the drawings may be exaggerated to emphasize a clearer description. It should be noted that the same members in each drawing are sometimes shown with the same reference numerals. In addition, detailed descriptions of well-known functions and configurations determined to unnecessarily obscure the gist of the present invention will be omitted.

The present invention uses a DC-DC converter that receives and converts the power of the solar panel inside the board 10 as an embodiment, but as long as it is a device including a PCB board, a BT (Bluetooth) module, or a WiFi module, etc. There is no limitation on the apparatus that can be applied to the present invention.

Monitoring according to the present invention is possible and a board including a damper may use one board 10 to which a plurality of boards 10 are coupled in a sliding manner, and as shown in FIG. 1 , an embodiment of the present invention As a monitoring possible, the description will be divided into a main board and a sub-board of the board 10 including a damper.

In addition, a plurality of converters are installed inside the plurality of boards 10 so that individual or simultaneous control is possible.

The main board and the sub-board are coupled by sliding according to the sliding coupling shape 11, and the sliding coupling shape 11 is a “R” shape and is a shape to prevent separation by force in the upper direction or the force in the side direction. .

At this time, it is possible to prevent the main board from being separated from the sub-board by the force in the upper direction or the force in the lateral direction in various shapes other than the "d" shape.

At this time, by installing the hinge parts 11-1 moving with a hinge on both sides of the board 10, the main board and the sub-board can be fixed.

In addition, when a problem occurs with the DC/DC converter inside the board 10, the main board and the sub-board can be disassembled and replaced by opening the hinge 11-1 and sliding along the sliding coupling shape 11 without the need for a separate tool. Because it is possible, it is possible to increase the disassembly/installation work time and convenience.

In addition, a metal plate is installed on the cut surface of the sliding board 10 to be electrically connected.

For example, when the main board and the sub board are slidably coupled by the sliding coupling shape 11 by attaching the metal assembly 12 to the central part, the main board and the sub board are electrically connected to communicate.

In addition, by coating the inner PCB surface or itself of the board 10 with an insulating material to block electromagnetic waves between devices, it is possible not only to prevent malfunction between devices, but also to maximize electrical performance.

An insulating pattern layer is applied on both sides of the upper and lower (front and rear) sides of the board 10 made of the insulating material such as epoxy, polyimide, or the like.

In another embodiment, instead of the metal assembly 12, a BT (Bluetooth) module or a WiFi module may be installed on the main board and the sub-board, respectively, so that they can communicate with each other.

In addition, monitoring is possible, and when a situation such as power supply of a board including a damper occurs, real-time board status can be checked through external monitoring through the monitoring system.

For example, in the case of a DC-DC converter, it is possible to check the operating status, the amount of power generated by the solar panel, and the power consumption of the load through the board status and values measured from each sensor in real time through the BT module or WiFi module in the administrator terminal and set If it goes out of range, an alarm is sent to the manager so that they can take quick action.

As shown in FIG. 2 , the board including the damper and monitoring is possible may include a plurality of dampers 20 on the bottom, preferably by attaching the dampers to the four corners to reduce the impact of the board 10 . It is possible to reduce it as much as possible.

As shown in FIG. 3 , the damper 20 is divided into an upper end 21 and a lower end 23 , and a semi-circular portion 22 coupled to the lower end 23 is formed on the lower surface of the upper end 21 to shake left and right. It is possible to reduce the impact while maintaining the horizontal even.

The damper 20 may be formed in a separate type (eg, screw coupling, etc.) to be additionally attached after forming one board 10 coupled in a sliding manner.

In another embodiment, a semi-circular spherical portion 22 is formed on the bottom surface of the upper portion 21, and a semi-spherical concave groove 23-1 is formed in a corresponding shape to accommodate the semi-circular portion 22 in the lower portion 23. formed on the side.

Accordingly, the semi-spherical portion 22 and the semi-spherical concave groove 23-1 corresponding thereto collide with the central axis as a reference to vibrate, thereby maintaining the horizontal level and reducing the impact.

As shown in FIG. 4 , a surface to which the semi-spherical part 22 is attached is formed around the semi-spherical part 22 on the bottom surface of the upper part 21 .

As shown in FIG. 5 , a hemispherical concave groove 23 - 1 corresponding to the semi-circular spherical part 22 is formed on the upper side of the lower end 23 .

As another embodiment, a sensor capable of detecting the movement of the damper 20 may be installed therein.

That is, the external shock state can be objectively determined by analyzing the frequency spectrum of the acceleration caused by the external shock using the FET-based vibration sensor.

In addition, it is possible to check the real-time board status by external monitoring of the external shock value through the BT module or WiFi module.

The UV stabilizer is applied on the insulating material of the PCB surface on the board 10, and the UV stabilizer is preferably HALS.

In addition to this, the antioxidant that can be used as the UV stabilizer functions as a free radical scavenger, and the UV stabilizer HALS destroys free radicals generated by photolysis from UV rays, thereby establishing a chain photooxidation reaction from the sun. It is used to protect against UV rays from the incoming radiation.

In addition, the antioxidant acts as a peroxide decomposing agent to protect the appearance of the board 10 and prevent discoloration of the organic polymer, which is easily oxidized.

In addition, the antioxidant is used to prevent aging due to heat and preserve color by decomposing and neutralizing the hydroperoxide material generated through the polymer oxidation process.

In addition, the antioxidant can prevent discoloration and yellowing, and maintain physical properties and surface properties such as heat resistance.

In one embodiment, the UV stabilizer includes one of absorbers, Quenchers, and HALS according to the mechanism of action.

The HALS serves to stop the photooxidation reaction by removing free radicals generated during the photolysis reaction.

The HALS is easily oxidized and converted into a nitroxyl radical, and reacts with a polymer radical to regenerate a specific stable radical, thereby stopping the photooxidation reaction.

Therefore, the HALS has excellent surface protection, so that the board can be protected from UV rays.

Meanwhile, as shown in FIG. 6 , as an embodiment of the present invention, the 'number of failures' is counted and stored for each corresponding DC-DC converter (S100). After performing step S100, it is determined 'number of failures' (S110). If the ‘number of failures’ occurs less than three times in step S110, the failure diagnosis processing step is terminated, and when the ‘number of failures’ occurs more than three times, the monitoring system notifies the manager of the failure (S120). The manager confirms and takes action according to the failure notification in monitoring (S130). When the administrator confirms and the action is completed, the ‘number of failures’ is reset to ‘0’ (S140) and the failure diagnosis step is terminated.

As another embodiment, the monitoring system monitors the converter operation state, solar power generation, and load power consumption in real time through the values measured from each sensor (S200), and when it is determined that an abnormal situation has occurred outside the set range (S210) When the manager terminal, which is the first alarm target, is absent or does not receive a call within a certain time (S220), the contact is delivered to the second and third manager terminals in turn (S230), or the first manager responds to an abnormal situation By controlling the transmission of manual information, it is possible to respond quickly in the initial stage (S240).

10 : board
11: sliding coupling shape
11-1: hinge part
20: damper
21: (damper) upper part
22: semicircular sphere
23: (damper) lower part
23-1: hemispherical concave groove

Claims (6)

A board that can check the real-time converter operation status, solar power generation, and load power consumption by external monitoring when power is applied by attaching a BT (Bluetooth) module or WiFi module;
A monitorable board comprising a damper, characterized in that the dampers are attached to four corners of the case in order to reduce the impact of the board. The method according to claim 1,
A board including a damper and capable of monitoring, characterized in that the sliding coupling shape of the board is not separated by a force in an upper direction or a force in the lateral direction in a “r” shape. The method according to claim 1,
A board capable of monitoring and including a damper, characterized in that the inner PCB surface of the board is coated with an insulating material. The method according to claim 1,
An ultraviolet stabilizer is applied on the insulating material board on the surface of the PCB, and the ultraviolet stabilizer is a HALS that stops the photooxidation reaction by removing free radicals generated during the photolysis reaction. A monitorable board comprising a damper. 3. The method according to claim 2,
A board comprising a damper and capable of monitoring, characterized in that a metal plate is installed and electrically connected to the cut surface of the sliding board. counting and storing the 'number of failures' for each DC-DC converter and determining the 'number of failures';
When the 'number of failures' occurs less than three times, terminating the failure diagnosis processing step, and when the 'number of failures' occurs three or more times, the monitoring system notifies the administrator of the failure;
checking, by the manager, according to the failure notification in monitoring and taking action;
A non-real-time monitoring step comprising; resetting the 'number of failures' to '0' (S140) and terminating the failure diagnosis step when the administrator confirms and the action is completed;
The monitoring includes: real-time monitoring of the converter operation state, the amount of solar power generation, and the power consumption of the load through the values measured from each sensor;
When it is determined through the monitoring system that the DC-DC converter is out of the setting range and an abnormal situation has occurred, the first alarm target manager terminal is absent or the second and third manager terminals are not contacted within a certain period of time In turn, the contact is forwarded;
In the case of the first manager, controlling to transmit abnormal situation response manual information; a monitoring method using a board capable of monitoring comprising a real-time monitoring step including a damper.

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