KR101687399B1 - Hybrid charging apparatus for ship - Google Patents

Abstract

A ship hybrid charging apparatus is disclosed. The hybrid charging apparatus for a ship according to an embodiment of the present invention includes a solar cell module installed on a deckhouse of a ship, an actuator unit for supporting the solar cell module, a sensor unit for tracking the position of sunlight, A solar cell module module including a solar cell module for controlling an operating state of the actuator unit such that the solar cell module faces the sun according to the position of the sun sensed by the solar cell module module; A surface glass is provided on an upper surface of the solar cell module, and a low iron tempered glass having a low surface reflectance is used. In addition to the solar cell module unit, a wave applied in the vertical direction or in the left- An electric energy generating unit that receives electric power generated by vibrations and shocks applied to the hull; A main battery unit in which electric energy generated in the solar cell module unit and the electric energy generating unit is stored; A load unit for receiving and consuming electric energy supplied from the main battery unit; And controlling charging of the main battery unit through one or both of the solar battery module unit and the electric energy generating unit when the ship is moving, and when the ship stops moving for fishing, And a control unit for controlling an amount of electric energy input through the solar cell module unit and the electric energy generating unit according to the amount of current consumed in the unit, wherein the solar cell module unit comprises: Further comprising an auxiliary solar cell module vertically installed at front, rear, left and right positions of the sidewalls of the deckhouse to provide electric energy to the main battery unit together with the solar cell module, A cover is provided on an upper surface thereof to prevent corrosion due to seawater, A reflector installed at front, rear, left, and right positions of the main frame on which the module is mounted, for irradiating sunlight toward the solar cell module, and a reflector plate positioned along the rim of the main frame and facing the main frame Wherein the actuator unit includes first to nth unit actuators having one end connected to a lower surface of the solar cell module and the other end spaced apart from an upper surface of the deckhouse, And a reflector rotation motor unit that rotates the rotation axis by a predetermined angle so that the angle of tilt of the reflection plate for emitting sunlight toward the solar cell module is maintained at a different angle in accordance with a change in length of the nth unit actuator, The electric energy generating unit may be disposed on an upper side or an inner side of the bottom surface of the bow of the ship, It characterized in that the unit consists of a piezoelectric member having a plurality of piezoelectric elements provided on the outer surface components or vibration of the unit is generated.

Description

[0001] Hybrid charging apparatus for ship [0002]

The present invention minimizes the consumption of electric energy through the main battery unit when the ship is moving or operating in a special position such as the sea, by using the rotational motor for driving the two snakes used for operation on the ship, And more particularly, to a marine hybrid charging apparatus capable of charging a ship.

Recently, the proportion of natural energy use is steadily increasing, and the size of power generation is getting bigger and bigger, so the capacity of power generation system is also increasing.

In general, renewable energy such as solar or wind power generation is not stable due to irregularly obtained natural energy, and it is required to be installed far away from people. Therefore, additional power generation system is considered.

For example, a load unit consuming electricity in a ship includes an engine unit installed for moving the ship, a pump unit including various pumps for supplying or draining water, a dashboard provided with a dashboard, various lamps or various fishing operations For example, an illuminating unit including a lighting unit for capturing fish, squid or shrimp that live in the water, and a lifting unit for automatically lifting the net from the ship.

In order to cover the electric energy consumed by the above-described load unit, the ship is supplied with electric energy required by the engine unit, the pump unit and the electric unit by using a main battery (not shown). However, If the battery capacity is excessively increased, the water level of the main battery is remarkably reduced and stable electric energy can not be supplied.

For example, although a separate engine for an amphibious machine is installed and used for operation of the amphibious machine, since the engine for the amber also uses gasoline as fuel, economic costs have arisen for the purchase of the fuel for operating the amphibian.

The main battery has a power generation unit capable of sufficiently assisting the stable operation of the main battery although the charging must be stably performed when the usage amount of the load unit is reduced, If there is an emergency situation due to power shortage at sea, it is necessary to take measures to cope with it in a stable manner.

Korean Patent No. 10-1358852

Embodiments of the present invention are directed to a solar battery module that receives vibrations and impacts applied to a hull while a ship is moving, generates electric energy to generate electricity, and supplies electric energy to a main battery unit through a solar cell module unit using solar light A hybrid charging device for a ship.

According to an aspect of the present invention, there is provided a solar cell module comprising: a solar cell module installed on a deckhouse of a ship; an actuator unit supporting the solar cell module; a sensor unit for tracking the position of sunlight; A solar cell module unit including a solar cell control module for controlling an operating state of the actuator unit such that the solar cell module faces the sun according to the position; A surface glass is provided on an upper surface of the solar cell module, and a low iron tempered glass having a low surface reflectance is used. In addition to the solar cell module unit, a wave applied in the vertical direction or in the left- An electric energy generating unit that receives electric power generated by vibrations and shocks applied to the hull; A main battery unit in which electric energy generated in the solar cell module unit and the electric energy generating unit is stored; A load unit for receiving and consuming electric energy supplied from the main battery unit; And controlling charging of the main battery unit through one or both of the solar battery module unit and the electric energy generating unit when the ship is moving, and when the ship stops moving for fishing, And a control unit for controlling an amount of electric energy input through the solar cell module unit and the electric energy generating unit according to the amount of current consumed in the unit, wherein the solar cell module unit comprises: Further comprising an auxiliary solar cell module vertically installed at front, rear, left and right positions of the sidewalls of the deckhouse to provide electric energy to the main battery unit together with the solar cell module, A cover is provided on an upper surface thereof to prevent corrosion due to seawater, A reflector installed at front, rear, left, and right positions of the main frame on which the module is mounted, for irradiating sunlight toward the solar cell module, and a reflector plate positioned along the rim of the main frame and facing the main frame Wherein the actuator unit includes first to nth unit actuators having one end connected to a lower surface of the solar cell module and the other end spaced apart from an upper surface of the deckhouse, And a reflector rotation motor unit that rotates the rotation axis by a predetermined angle so that the angle of tilt of the reflection plate for emitting sunlight toward the solar cell module is maintained at a different angle in accordance with a change in length of the nth unit actuator, The electric energy generating unit may be disposed on an upper side or an inner side of the bottom surface of the bow of the ship, It characterized in that the unit consists of a piezoelectric member having a plurality of piezoelectric elements provided on the outer surface components or vibration of the unit is generated.
The actuator unit includes first to n-th unit actuators, one end of which is connected to a lower surface of the solar cell module, and the other end of which is spaced apart from an upper surface of the deckhouse.
The actuator unit includes a hinge ball whose one end is fixed to the solar cell module and the other end is connected to the tip of the first to nth unit actuators.
Wherein the rod unit is a lighting unit including a pump unit including various hooks or various pumps installed on a ship or various lamps used in the ship, wherein the hopper transmits rotational force from a driving motor provided for operation And is operated.
The solar cell control module further includes a communication module for controlling an operating state of the actuator unit according to current weather information data of a current location and wakeup information data of n hours or later when the ship is operating at sea .

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The embodiments of the present invention can stably supply the power source necessary for charging the main battery unit, in addition to the main engine installed in the ship, by using the solar cell module and the piezoelectric element that generates power using the vibration and impact applied to the hull Electric energy can be used stably regardless of sea or emergency situation.

The embodiments of the present invention can stably supply the electric energy from the main battery unit without operating the main engine even when the lifting device used for the operation is operated for a long time, so that only the fuel consumption is reduced and the economical efficiency is improved, Power generation through the provided solar energy enables stable supply of electric energy required for moving and operating the ship.

1 is a block diagram schematically illustrating a marine hybrid charging apparatus according to an embodiment of the present invention;
2 is a perspective view illustrating a solar cell module unit according to an embodiment of the present invention.
3 is a plan view of a solar cell module unit according to an embodiment of the present invention.
4 (a) to 4 (b) are operational states of a solar cell module unit according to an embodiment of the present invention.
FIG. 5 to FIG. 6 are operational states of a marine hybrid charging apparatus according to an embodiment of the present invention;

A marine hybrid charging apparatus according to an embodiment of the present invention will be described with reference to the drawings. 2 is a perspective view illustrating a solar cell module unit according to an embodiment of the present invention, and FIG. 3 is a cross-sectional view of the present invention FIG. 4 is a plan view of a solar cell module unit according to one embodiment of the present invention, and FIGS. 4 (a) to 4 (b) are operational states of a solar cell module unit according to an embodiment of the present invention.

1 to 4, the ship hybrid charge apparatus 1 according to an embodiment of the present invention is mainly described as being used in a small ship or a medium-sized ship, but is not limited to a large- It can be applied to various vessels used for transportation or fishing, and is not limited to vessels and structures specifically shown in the drawings.

The ship hybrid charging apparatus 1 comprises a solar cell module unit 100, an electric energy generating unit 200, a main battery unit 300, a rod unit 400 and a control unit 500.

The solar cell module unit 100 includes a solar cell module 110 installed on a ship's deck house 5, an actuator unit 120 for supporting the solar cell module 110, A solar cell control module (130) for controlling the operation state of the actuator unit (120) so that the solar cell module (110) faces the sun according to the position of the sun sensed by the sensor unit 140).

The solar cell module 110 is used to generate a constant voltage and current under sunlight by connecting a plurality of cells in series or in parallel. The solar cell module 110 may be manufactured in various forms according to applications. In this embodiment, It is possible to use other solar cell modules.

A crystalline silicon solar cell module is formed by cutting a plurality of cells and arranging them in series or parallel to each other, and placing the cells in the main frame to protect them from external shocks or bad weather.

The solar cell module 110 is provided with a surface glass (not shown) on the upper surface thereof and uses a low-iron-tempered glass 111 having a low surface reflectance to minimize the reflection loss of the surface glass itself. The filler is usually EVA Vinyl Acetate (not shown), which protects the fragile cell.

The solar cell module 110 is selectively used in various forms such as a flexing flexible module, a roof tile type module, a circular module, and a triangular module, and is not particularly limited to a specific module.

The actuator unit 120 includes first to n-th unit actuators 120a to 120n, one end of which is connected to the lower edge of the main frame 104 and the other end of which is fixed to the upper surface of the deck house 5, The first to n-th unit actuators 120a to 120n are configured to have a unit piston inserted in a unit cylinder and can be operated by hydraulic pressure.

The first to nth unit actuators 120a to 120n are elongated to have different lengths so that the tilted slope of the left or right side of the solar cell module 110 is adjusted according to the position of sunlight.

A reflector 112 installed on a side surface of the main frame 104 on which the solar cell module 110 is mounted and irradiating sunlight toward the solar cell module 110, And a rotation shaft 114 inserted into the main frame 104 in the longitudinal direction of the main frame 104.

The reflector 112 irradiates the sunlight so that the sunlight is concentrated on the solar cell module 110. The reflector 112 is capable of emitting a greater amount of sunlight, It is possible to generate electric power from the solar cell module unit 100 in a stable manner by reflecting the solar cell module 110 to the cell module 110, thereby maximizing power generation in the limited size of the solar cell module 110.

The reflector 112 is installed to be rotatable via a rotation shaft 114 inserted in the longitudinal direction of the main frame 104. The reflector 112 is disposed on the main surface of the main body 104, A reflector rotating motor unit 103 for rotating the rotating shaft 114 at a predetermined angle such that the angle of inclination of the reflecting plate 112 for emitting sunlight toward the module 110 is maintained at a different angle.

The reflector rotation motor unit 103 can be installed in all of the unit reflectors. The reflector rotation motor unit 103 can be installed in the unit reflector by the solar cell control module 140, Are controlled differently.

For example, when the solar cell module 110 is placed in a tilted state, the unit reflector is rotated by the reflector rotation motor unit 103 so that a maximum amount of sunlight is directed toward the inclined solar cell module 110 The solar cell module 110 can be irradiated with sunlight.

Accordingly, a larger amount of solar light can be generated through the solar cell module 110 and the reflection plate 112, and thus the generated electric energy is stored in the main battery unit 300.

The solar cell module module 100 further includes an auxiliary solar cell module 110a provided on a side of the deckhouse 5 to provide the electric energy of the main battery unit 300 together with the solar cell module 110, The solar cell module 110a provides the main battery unit 300 with a shortage of the electric energy generation amount through the solar cell module unit 100 so as to generate stable electric energy and to generate a large amount of electricity And enables stable development even when energy is consumed. For reference, the auxiliary solar cell module 110a can be installed at a position other than the above-described position and is covered with a separate cover 110b which is formed transparent so as to prevent damage due to salt.

The actuator unit 120 includes a hinge ball 122 whose one end is fixed to the solar cell module 110 and the other end is connected to the tip of the first to nth unit actuators 120a to 120n, 122 are positioned in the solar cell module 110 when the solar cell module 110 is positioned horizontally in the deckhouse 5 and is inclined by the extension of the first to nth unit actuators 120a to 120n. The inclined state of the solar cell module 110 can be stably maintained while the hinge ball 122 is relatively moved at the corner position of the solar cell module 110. [

Therefore, even when the solar cell module 110 is inclined at various angles toward the sunlight, the inclined state is stably maintained by the hinge ball 122.

The sensor unit 130 tracks the position of the sunlight and transmits sensed data to the solar cell control module 140. The solar cell control module 140 senses the position of the first to nth unit actuators 120a To 120n are controlled so that the sunlight is viewed by controlling the extension length.

The solar cell control module 140 controls the operation state of the actuator unit 120 according to the current weather information data of the current location and the weather information data of the time after n hours when the ship is operating at sea, (142), and is operable to generate power through the solar cell module unit (100) through an optimal solar light in a sea state where the ship is changed in real time through the weather information data in which the ship is located.

The electric energy generating unit 200 receives the vibrations and shocks applied to the hull by the waves applied in the vertical and horizontal directions along with the movement of the ship together with the solar cell module unit 100 to generate electric energy, Unit 300 as shown in FIG.

The electric energy generating unit 200 is composed of a unit piezoelectric body having a plurality of piezoelectric elements provided on the upper or inner edge of the bottom of the bow of the ship and the position is not limited to the above described position but may be provided at another position. And may be installed in a pump unit or a shaft in which vibration is generated.

Referring to FIG. 4A, when the sun is located at a position shown in the drawing, for example, the first through n-th unit actuators 120a through 120n extend in the outward direction And the solar cell module 110 is positioned so as to be inclined at a predetermined angle toward the sun. Accordingly, a large amount of electric energy can be stably supplied to the main battery unit 300, which will be described later, and the storage efficiency of the main battery unit 300 through power generation is improved.

Referring to FIG. 4B, when the sun is located at a position shown in the drawing, for example, the first to n-th unit actuators 120a to 120n are extended toward the outside in the state shown in the drawing And the solar cell module 110 is positioned so as to be inclined at a predetermined angle toward the sun.

Referring to FIG. 1 or FIG. 5 to FIG. 6, the main battery unit 300 stores electric energy generated from the solar cell module unit 100 and the electric energy generating unit 200, The electric energy generated in the solar cell module unit 100 and the electric energy generating unit 200 is selectively stored or supplied to be used in the load unit 400. [ The number of the main battery units 300 may be one or a plurality, and the number is not particularly limited.

The load unit 400 is consumed by receiving the electric energy supplied from the main battery unit 300. For example, the load unit 400 may be a pump unit including a pump or various pumps installed on a ship, And the lamp unit includes a plurality of lamps.

The ship is provided with the above-described pump unit and lighting unit for production activity through fishing, and the pump unit is a drain pump, for example, and is used for discharging condensate generated on the stern of a ship outboard.

Since a large number of lighting units are installed along the outer longitudinal direction of the hull and the electric energy consumed by the lighting unit is significant in the case of a ship which illuminates and fishes, it is quite difficult to stably supply the electric energy supplied to the lighting unit It can be said that it is important.

In addition, the ammeter installed on the ship is used to raise a net located on the seabed to the hull. The ammeter receives the rotational force generated by the main engine 4, and in this embodiment, the main battery unit 300 The operation is performed with respect to the above-mentioned ammeter by using the driving motor 10 operated by the electric energy supplied from the electric motor.

Particularly, even when the lifting device is used for a long time, the electric energy stored in the main battery unit 300 can be used without operating the main engine 4, thereby reducing the fuel cost and prolonging the operating time. It is prevented in advance. It is noted that the drive motor 10 uses a DC motor, but other motors can be used.

The control unit 500 controls the charging of the main battery unit 300 through any one or both of the solar battery module unit 100 and the electric energy generation unit 200 when the ship is moving, When the ship stops moving for operation, the amount of electric energy input through the solar cell module unit 100 and the electric energy generating unit 200 is controlled differently according to the amount of current consumed in the rod unit 400 do.

For example, when the ship is moving, some electric energy is supplied to the main battery unit 300 through the generator (not shown) according to the operation of the main engine 4. At the same time, And is supplied to the main battery unit 300 through the energy generating unit 200 at the same time.

At the same time, the ship is moved to a specific position for operation, vibration and impact are transmitted to the ship by waves, and electric energy generated in the piezoelectric element provided in the electric energy generating unit 200 is supplied to the main battery unit 300 do.

Since the main battery unit 300 is charged stably through the solar cell module unit 100 and the electric energy generating unit 200 while the main engine is operating as described above, The electric energy is stored up to the maximum capacity that can be stored in the main battery unit 300 before the load is generated.

In the case where the ship is positioned at a specific position for operation and the main engine is turned off and both the ammeter, the pump unit, and the illumination unit are simultaneously used, the electric energy stored in the main battery unit 300 is transmitted to the drive motor 10, the pump unit, and the lighting unit, so that the main engine unit 4 can be operated without charging the main battery unit 300 through the operation of the main engine 4.

Therefore, even when the operation is performed for a long time, the consumption of the diesel oil is not caused by the operation of the main engine 4, so unnecessary fuel consumption can be reduced and economical operation is possible. For reference, the starter battery 3 is charged when the main engine 4 is operated.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit of the invention as set forth in the appended claims. The present invention can be variously modified and changed by those skilled in the art, and it is also within the scope of the present invention.

4: main engine
10: Driving motor
100: solar cell module unit
112: reflector
200: electric energy generating unit
300: main battery unit
400: load unit
500:
110: solar cell module
120: Actuator unit

Claims (9)

A solar cell module mounted on an upper surface of the deck house of the ship, an actuator unit supporting the solar cell module, a sensor unit for tracking the position of the sunlight, A solar cell module unit including a solar cell control module for controlling an operating state of the actuator unit so as to face the sun;
Wherein a surface glass is provided on an upper surface of the solar cell module and a low iron tempered glass having a low surface reflectance is used as the surface glass,
An electric energy generating unit for generating electric energy by receiving vibrations and shocks applied to the hull by a wave applied in the vertical direction or in the lateral direction according to the movement of the ship together with the solar cell module unit;
A main battery unit in which electric energy generated in the solar cell module unit and the electric energy generating unit is stored;
A load unit for receiving and consuming electric energy supplied from the main battery unit; And
The control unit controls to charge the main battery unit through any one or both of the solar battery module unit and the electric energy generation unit when the ship is moving, and when the ship stops moving for fishing, And a controller for controlling an amount of electric energy input through the electric energy generating unit and the solar cell module unit according to an amount of electric current consumed by the electric energy generating unit,
In the solar cell module unit,
And an auxiliary solar cell module installed vertically at the front, rear, left, and right positions of the sidewalls of the deckhouse to provide electric energy to the main battery unit together with the solar cell module, Wherein the auxiliary solar cell module is provided with a cover on its top surface to prevent corrosion due to seawater,
A reflector installed at the front, rear, left and right positions of the main frame on which the solar cell module is mounted and for irradiating sunlight toward the solar cell module, a reflector positioned along the rim of the main frame, The viewing mirror includes a rotation axis connected to the longitudinal direction of the reflection plate,
The actuator unit includes first to n-th unit actuators, one end of which is connected to a lower surface of the solar cell module, and the other end of which is spaced apart from an upper surface of the deckhouse. Further comprising a reflector rotation motor unit that rotates the rotation axis by a predetermined angle so that an angle of inclination of the reflection plate for emitting sunlight toward the solar cell module is maintained at a different angle,
The electric energy generating unit includes:
And a unit piezoelectric element having a plurality of piezoelectric elements provided on an upper or inner edge of a bottom surface of a forefront of the ship, an outer surface of a pump unit provided on the ship, or a component in which vibration is generated. delete delete The method according to claim 1,
The actuator unit includes:
And a first to an n-th unit actuator having one end connected to a lower surface of the solar cell module and the other end spaced apart from an upper surface of the deck house. delete 5. The method of claim 4,
The actuator unit includes:
And a hinge ball having one end fixed to the solar cell module and the other end connected to the distal end portions of the first through n th unit actuators. delete The method according to claim 1,
The load unit includes:
Wherein the pump unit is a lighting unit including various pumps used in the ship,
Wherein the lifting device is operated by receiving a rotational force from a drive motor provided for operation. The method according to claim 1,
The solar cell control module includes:
Further comprising: a communication module for controlling an operating state of the actuator unit according to current weather information data of a current location and wakeup information data after n hours when the ship is operating at sea.

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