KR20200000897U - Mounting structure of solar cell module in container ship - Google Patents

Abstract

This design effectively installs and de-installs the solar cell module on a container ship that has insufficient space to install the solar cell module compared to other ships, so that the container ship can perform photovoltaic power generation without disturbing the loading and unloading work of the container. Regarding a battery module mounting structure, a solar cell module mounting structure of a container ship according to the present invention includes a plurality of unit cargo holds provided on a container ship to provide a loading space of a cargo container; A container for a solar cell module, which is mounted on any one or more of a plurality of unit cargo holds and holds a plurality of solar cell modules in a hinge shape; A lifting device provided inside the container for the solar cell module to elevate the solar cell module; And a deployment provided on one side of the container for the solar cell module to guide the solar cell module accommodated through a rotation operation to be unfolded to the top of the cargo container, or to guide the unfolded solar cell module to be received into the container for the solar cell module. Apparatus; including, the deployment device, a hinge portion fixed to the upper side of the container for the solar cell module, a deployment arm connected to the hinge portion and rotatable by the operation of the hinge portion, one end of the deployment It is characterized in that it comprises a connecting arm fixed to the arm and the other end is selectively fastened to one side of the solar cell module.

Description

Mounting structure of solar cell module in container ship

The present invention relates to a structure of mounting a solar cell module of a container ship, and more specifically, loading and unloading of containers by effectively installing and releasing the solar cell module on a container ship having insufficient space for installation of the solar cell module compared to other ships. It relates to a solar cell module mounting structure of a container ship capable of performing photovoltaic power generation without disturbing work.

In order to reduce air pollution due to the use of fossil raw materials and to reduce the cost of electricity production, a technique of applying a solar cell module to a ship has been recently researched (Korean Patent Publication No. 2006-79940, Korean Patent Publication No. 2010-129896 See).

The technology disclosed in the patent publication is a method of providing a separate support for supporting a solar cell module on a ship and using it to install at a position spaced apart from a ship deck or residence. This method has the disadvantages that the installation cost increases and the space utilization of the deck is lowered by the installation of the support. In addition, when the solar cell module is buried and installed, there is a problem in that repair of the solar cell module is not easy, and the solar cell module is overheated and damaged. Recently, a technology has been proposed in which a solar cell module is directly installed on a ship deck to reduce installation cost and increase space utilization (refer to Korean Registered Patent No. 1318948).

However, since the above-described techniques are techniques for installing a solar cell module in a free space of a ship, utilization is low for container ships in which container loading and unloading are repeated.

Korea Patent Publication No. 2006-79940 Korean Patent Publication No. 2010-129896 Korean Registered Patent No. 1318948

The present invention has been devised to solve the above problems, and it is possible to effectively install and de-install the solar cell module in a container ship that has insufficient space to install the solar cell module compared to other ships, without disturbing the container loading and unloading work. The object of the present invention is to provide a solar cell module mounting structure of a container ship capable of performing photovoltaic power generation.

A solar cell module mounting structure of a container ship according to the present invention for achieving the above object is provided in the container ship, a plurality of unit cargo holds to provide a loading space of the cargo container; A container for a solar cell module, which is mounted on any one or more of a plurality of unit cargo holds and holds a plurality of solar cell modules in a hinge shape; A lifting device provided inside the container for the solar cell module to elevate the solar cell module; And a deployment provided on one side of the container for the solar cell module to guide the solar cell module accommodated through a rotation operation to be unfolded to the top of the cargo container or to guide the unfolded solar cell module to be received into the container for the solar cell module. Apparatus; including, the deployment device, a hinge portion fixed to one side of the upper portion of the container for the solar cell module, a deployment arm connected to the hinge portion and rotatable by the operation of the hinge portion, one end of the deployment It is characterized in that it comprises a connecting arm fixed to the arm and the other end is selectively fastened to one side of the solar cell module.

When a plurality of solar cell modules are accommodated in a hinge shape, connect one end of the connecting arm to one side of the solar cell module adjacent to the deploying arm, and then rotate the deploying arm 180 degrees. Unfolds in the deployment direction, releases the connection of the connecting arm from the unfolded solar cell module, moves the solar cell module to the upper side through the lifting device, connects the connection box to one side of the exposed solar cell module, and then connects The solar cell module unfolds when the rotation is rotated 180 degrees.

In addition, when a plurality of solar cell modules are unfolded, connect the connecting arm to one side of the adjacent solar cell module, and then rotate the deployment arm 180 degrees in the opposite direction of the unfolding operation, so that the solar cell module is stored inside the container for the solar cell module. When the received solar cell module is lowered by using an elevating device, the connecting arm is released, and the connecting arm released from the stored solar cell module is connected to an adjacent unfolded solar cell module to rotate 180 degrees of the deployed arm again. If the operation and the descending operation of the lifting device are repeated, the unfolded solar cell module can be stored inside the container for the solar cell module.

A solar cell module mounting structure of a container ship according to the present invention includes a plurality of unit cargo holds provided on a container ship to provide a loading space for a cargo container; A container for a solar cell module mounted on any one or more of a plurality of unit cargo holds and accommodating a plurality of solar cell modules; A solar cell module transport roller which is provided on an upper portion of the container for the solar cell module and discharges one of the solar cell modules stored in the container for the solar cell module in a guide rail direction through a rotation operation; And a guide rail for guiding the solar cell module discharged by the solar cell module transport roller to be moved to the top of the cargo container.

The solar cell module mounting structure of the container ship according to the present invention has the following effects.

Compared to other ships, solar cell modules can be effectively installed and installed on container ships that have insufficient space to install solar cells. In addition, photovoltaic power generation can be performed without disturbing the loading and unloading of containers.

1 is a configuration diagram of a solar cell module mounting structure of a container ship according to a first embodiment of the present invention.
2A to 2D are reference diagrams for explaining the unfolding operation of the solar cell module according to the first embodiment of the present invention.
3 is a configuration diagram of a solar cell module mounting structure of a container ship according to a second embodiment of the present invention.

The present invention proposes a technique for effectively installing and releasing a solar cell module in a container ship.

As mentioned in the previous 'Technical Background', the technology of installing solar cell modules on ships to reduce air pollution and fossil fuel use due to the use of fossil fuels has been spotlighted. These solar cell modules are installed in the ship's idle spaces such as decks and residences. In the case of container ships, the space for installation of the solar cell modules is insufficient compared to other ships because most of the space on the ship's plane is filled with cargo containers.

The present design allows the solar cell module to be installed on the uppermost cargo container when loading of the cargo container is completed, and when the cargo container is unloaded, the solar cell module installed on the uppermost cargo container is removed to load and unload the container. Presenting a technology that can effectively perform solar power generation without being disturbed by

To this end, the present invention has the same height and position as the container on the top floor, and provides a container for a solar cell module that holds a plurality of solar cell modules in a hinge shape, and when loading of the cargo container is completed, for the solar cell module The plurality of solar cell modules accommodated in the container is raised using a lift device so that the plurality of solar cell modules are unfolded on the loaded cargo container, and when unloading the cargo container, the platform is provided inside the container for the solar cell module. By lowering the value, a technique is proposed in which a plurality of solar cell modules unfolded on a cargo container are folded and accommodated inside a container for a solar cell module.

Hereinafter, a structure of mounting a solar cell module of a container ship according to an embodiment of the present invention will be described in detail with reference to the drawings.

1, the mounting structure of the solar cell module 30 of the container ship according to the first embodiment of the present invention, first, has a cargo hold. The cargo hold provides a space in which the plurality of cargo containers 10 are loaded, and the plurality of cargo containers 10 may be stacked in rows and columns in a cargo hold and may be stacked in a multi-stage form. Therefore, the cargo hold may be provided in multiple stages in the vertical direction, and a plurality of cargo containers 10 may be arranged in rows and rows for each stage of the cargo hold. In other words, it can be said that a lattice-shaped space is provided for each stage of the cargo hold, and a cargo container 10 is disposed for each grid, and the space of the cargo hold where one cargo container 10 is located can be referred to as a unit cargo hold. have. In the following description, it is assumed that cargo holds are divided into a plurality of stages, and that the cargo holds of each stage are composed of a plurality of unit cargo holds forming a lattice shape.

At the top of the cargo hold, a plurality of unit cargo holds can be loaded with a cargo container 10, respectively, and at least one of the plurality of unit hold holds a solar cell module container 20. It is preferable that the container 20 for the solar cell module and the cargo container 10 have the same standard and shape. When a plurality of cargo containers 10 are loaded on the top of the cargo hold, the solar cell module container 20 and the cargo container 10 have the same height.

The solar cell module container 20 includes a plurality of solar cell modules 30, and the plurality of solar cell modules 30 are positioned on the elevating device 110. According to the elevation of the elevating device 110, it is possible to elevate the plurality of solar cell modules 30, and more precisely, the plurality of solar cell modules 30 according to the elevation of the elevating device 110 allows the container 20 for solar cell modules. It can be discharged to the outside and unfolded on the surrounding loaded cargo container 10 or stored inside the container 20 for a solar cell module.

The plurality of solar cell modules 30 accommodated inside the solar cell module container 20 are connected and received in a hinge shape. That is, the neighboring solar cell modules 30 are connected in a hinge shape, and the plurality of solar cell modules 30 form a folding screen. In addition, the plurality of solar cell modules 30 connected in a hinged manner is received in a form in which flat plates are stacked.

The plurality of solar cell modules 30 accommodated in the container 20 for solar cell modules is spread on the cargo container 10 by the operation of the lifting device 110 and the deployment device 120 or the container for the solar cell module ( 20) It can be stored folded inside.

2A to 2D, the deployment device 120 is provided on an upper side of the container 20 for a solar cell module, and is composed of a hinge portion 121 and a deployment arm 122. The hinge portion 121 is fixed to the upper side of the container 20 for the solar cell module, the deployment arm 122 is connected to the hinge portion 121, 180 degrees by the operation of the hinge portion 121 Rotation is possible. One side of the deployment arm 122 is provided with a connecting arm 123, and one end of the connecting arm 123 can be selectively fastened with the solar cell module 30. Therefore, one end of the connection arm 123 is connected to one side of the solar cell module 30 adjacent to the deployment arm 122 in a state in which a plurality of solar cell modules 30 are accommodated in a hinge shape, and then the deployment arm 122 ) When rotated 180 degrees, the solar cell module 30 connected to the connecting arm 123 is unfolded in the developing direction of the developing arm 122. Through this operation, it is possible to unfold the two solar cell modules 30 connected by hinges onto the cargo container 10. In addition, in the state in which the unfolding of the two solar cell modules 30 is completed, the connection arm 123 is released from the unfolded solar cell module 30 and the solar cell module 30 is lifted through the elevating device 110. After moving a certain distance to the upper part, connect the connection box to one side of the solar cell module 30 exposed to the upper part, and then proceed with the above operation, that is, the rotation of the deployment arm 122 by 180 degrees, the two solar cells again. The module 30 can be unfolded. At this time, the two solar cell modules 30 that have already been unfolded move forward in the direction in which the solar cell modules 30 are unfolded. If the above-described operation is repeatedly performed, all the solar cell modules 30 accommodated in the solar cell module container 20 can be unfolded on the cargo container 10.

In the process of storing the plurality of solar cell modules 30 unfolded on the cargo container 10 into the container 20 for the solar cell modules, the unfolding operation of the solar cell module 30 described above may be reversed. In a state in which a plurality of solar cell modules 30 are unfolded, connecting the connection arm 123 to one side of the adjacent solar cell module 30 and then rotating the deployment arm 122 in the opposite direction by 180 degrees rotates the two solar cell modules 30 ) Is stored inside the container 20 for a solar cell module. Subsequently, the received solar cell module 30 is lowered by a predetermined distance using the elevating device 110, the connection arm 123 is released, and the connection arm 123 released from the received solar cell module 30 is removed. ) Is connected to the adjacent solar cell module 30 to repeat the 180-degree rotation operation of the deployment arm 122 and the descending operation of the elevating device 110 to expand the expanded solar cell module 30 to the solar cell. It is possible to receive the module container 20 inside.

The structure of mounting the solar cell module of the container ship according to the first embodiment of the present invention has been described above. The present invention relates to a technique of utilizing the upper portion of a loaded cargo container as a mounting space of a solar cell module, and the first embodiment of the present invention described above elevates a plurality of solar cell modules stored inside a container for a solar cell module. The present invention relates to a technology of storing a plurality of solar cell modules deployed through an operation of the device and a deployment device to the upper portion of a cargo container or vice versa into a container for a solar cell module.

In addition to the first embodiment using the lifting device and the deploying device as described above as a method of expanding the accommodated plurality of solar cell modules to the top of the cargo container or storing the expanded plurality of solar cell modules into a container for a solar cell module, as described above, It is also possible to implement in other embodiments. The second embodiment below presents a technique for realizing the unfolding and receiving operation of the solar cell using the solar cell module transport roller and the guide rail.

According to the second embodiment of the present invention, as shown in FIG. 3, the container 20 for a solar cell module is provided as in the first embodiment, and a plurality of solar cell modules are provided inside the container 20 for a solar cell module. 30 is stored. However, unlike the first embodiment, the plurality of solar cell modules 30 accommodated inside the container 20 for a solar cell module are stacked in a single unit form without forming a hinge.

The solar cell module transport roller 310 is provided on the top of the container 20 for a solar cell module, and a guide rail 320 is provided on the cargo container 10. The solar cell module transfer roller 310 serves to discharge the solar cell modules 30 stored inside the container 20 for the solar cell modules one by one in the direction of the guide rail 320 through a rotation operation, and the guide rail 320 serves to guide the solar cell module 30 discharged by the solar cell module transfer roller 310 to be moved to the upper portion of the cargo container 10. The solar cell module transport roller 310 rotates and a plurality of solar cell modules 30 are extended to the upper portion of the cargo container 10 through the guide rail 320 or the solar cell modules 30 are expanded. It is possible to receive the module container 20 inside.

10: cargo container 20: solar cell module container
30: solar cell module 110: lifting device
120: deployment device 121: hinge portion
122: unfolding arm 123: connecting arm
310: solar cell module transfer roller 320: guide rail

Claims (4)

A plurality of unit cargo holds provided in the container ship to provide a loading space for the cargo containers;
A container for a solar cell module, which is mounted on any one or more of a plurality of unit cargo holds and holds a plurality of solar cell modules in a hinge shape;
A lifting device provided inside the container for the solar cell module to elevate the solar cell module; And
A deployment device that is provided on one side of the container for the solar cell module, and guides the solar cell module accommodated through a rotational operation to be unfolded to the top of the cargo container or to guide the unfolded solar cell module to be received into the container for the solar cell module. It is made, including;
The deployment device includes a hinge portion fixed to an upper side of the container for a solar cell module, a deployment arm connected to the hinge portion and rotatable by an operation of the hinge portion, one end fixed to the deployment arm, and the other end of the sun Solar cell module mounting structure of a container ship, characterized in that it comprises a connecting arm that is selectively fastened to one side of the battery module.
The solar cell of claim 1, wherein one end of the connecting arm is connected to one side of the solar cell module adjacent to the developing arm in a state in which a plurality of solar cell modules are accommodated in a hinge shape, and then, when the developing arm is rotated 180 degrees, the sun connected to the connecting arm The battery module is unfolded in the deployment direction of the deployment arm,
The connection arm is disconnected from the unfolded solar cell module, the solar cell module is moved to the upper part via a lifting device, the connection box is connected to one side of the solar cell module exposed to the upper part, and then the deployment arm is rotated 180 degrees. The solar cell module mounting structure of the container ship, characterized in that when the solar cell module is unfolded.
According to claim 1, In a state in which a plurality of solar cell modules are unfolded, connecting the connecting arm to one side of the adjacent solar cell module and then rotating the deployment arm 180 degrees in the opposite direction of the unfolding operation, the solar cell module is used for the solar cell module. It is stored inside the container,
The received solar cell module is lowered by using an elevating device, the connecting arm is released, and the connecting arm released from the stored solar cell module is connected to an adjacent unfolded solar cell module to rotate the deployment arm 180 degrees and The solar cell module mounting structure of a container ship, characterized in that, when the lowering operation of the lifting device is repeated, the unfolded solar cell module can be stored inside the container for the solar cell module.
A plurality of unit cargo holds provided in the container ship to provide a loading space for the cargo containers;
A container for a solar cell module mounted on any one or more of a plurality of unit cargo holds and accommodating a plurality of solar cell modules;
A solar cell module transport roller which is provided on an upper portion of the container for the solar cell module and discharges one of the solar cell modules stored in the container for the solar cell module in a guide rail direction through a rotation operation; And
A solar cell module mounting structure of a container ship, comprising: a guide rail for guiding the solar cell module discharged by the solar cell module transfer roller to be moved to the top of the cargo container.

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