KR200458800Y1 - Moving Type Compact Solar Power Generator System - Google Patents

Abstract

The present invention is a solar device 100 for converting solar energy into direct current electricity: a bottom plate 211 is provided with a caster (211a) on the bottom, and a plurality of pillar members provided on the upper edge of the bottom plate 211 212 and a pair of side plates 213 disposed to face each other and disposed between the pillar members 212 to form sidewalls, and between the pillar members 212 where the side plates 213 are not installed. And a mounting plate 214 having an open center, a ceiling plate 215 on which an edge of the bottom surface is mounted on and fixed to an upper surface of the pillar member 212, and a switch exposure unit 216a and an LED exposure unit 216b. , A front plate 216 installed on the front of the mounting plate 214, a first door part 217 rotatably installed on the front of the front plate 216 via a hinge H, and a first door. A carrier 210 having a second door part 218 rotatably installed via a hinge H on an opposite side to which the part 217 is installed; A solar controller 220 installed in the carrier 210 and charging the battery 230 with direct current electricity supplied from the solar device unit 100; A battery 230 which receives the direct current electricity from the solar controller 220 and stores it, and transmits the direct current electricity to the inverter 240; It is characterized in that it comprises a power generation unit 200 having an inverter 240 for receiving a direct current electricity from the battery 230 and converts it into alternating current electricity.
According to an embodiment of the present invention, there is an advantage in that it is easy to produce electricity on its own even in a region in which electricity supply is difficult through the solar unit and the generator unit as described above.

Description

Mobile Compact Solar Power Generator System

The present invention relates to a mobile compact solar power system.

At present, the world's most energy-dependent coal and nuclear power plants continue to increase their interest in alternative energy due to depletion of resources and environmental and stability issues. Among them, solar power costs little to no maintenance costs. Many studies are being conducted even now because they are receiving considerable attention in terms of infinite clean energy.

Currently, the power generated by photovoltaic power generation is used in a wide range of fields such as battery chargers, pumps, home power supplies, street lights, and satellite power systems, but the photovoltaic power generation system is expensive for solar cell modules and other systems. The situation is somewhat limited.

In addition, the conventional photovoltaic power generation system has a problem that it is difficult to miniaturize because it is a structure that supplies electricity acquired through the solar module to a separate facility in the state that most of them are not mobile, fixed to the ground, and researches to solve this problem are actively conducted. It was in progress.

The present invention has been devised to solve the above problems, it is possible to easily produce and use electricity in places where power can not be supplied by making a small photovoltaic power generation system, and has a relatively simple structure. The aim is to provide a portable small photovoltaic system that is very easy to move, install and install.

The present invention for achieving the above object,

Solar unit to convert solar energy into direct current electricity:

A bottom plate with a caster on the bottom surface, a plurality of pillar members installed at the top edge of the bottom plate, a pair of side plates disposed opposite to each other and installed between the pillar members to form sidewalls, and side plates are not installed. The front panel is installed between the pillar members, and has an installation plate with an open center, a ceiling plate having a bottom edge mounted on the upper surface of the pillar member, and a switch exposure unit and an LED exposure unit. And a carrier having a first door part rotatably installed on the front of the front plate and a second door part rotatably installed on the opposite side on which the first door part is installed.

A solar controller installed in the carrier and charging the battery with direct current electricity supplied from the solar device;

A battery which receives the direct current electricity from the solar controller and stores the received direct current electricity to the inverter;

Characterized in that it comprises a power generation unit having an inverter for receiving a direct current electricity from the battery to convert into alternating current electricity.

According to an embodiment of the present invention, there is an advantage in that it is easy to produce electricity on its own even in a region in which electricity supply is difficult through the solar unit and the generator unit as described above.

In addition, in the case of the carrier has a relatively simple structure is easy to assemble, in particular, the second door portion of the carrier has the advantage that the repair and replacement is quite easy, and the caster installed in the carrier greatly improves the convenience of movement I can let you.

In addition, the carrier is arranged to separate the electronic device (solar controller, inverter, battery level indicator) and the battery through the diaphragm, so that the semiconductor of the electronic device is damaged due to the heat generated during charging and discharging of the battery. There is an advantage to block.

1 is a conceptual diagram of a mobile compact photovoltaic system according to the present invention.
Figure 2 is a perspective view showing a separate extracting the generator unit in a portable small photovoltaic power generation system according to the present invention.
3 is an exploded perspective view of FIG. 2;
Figure 4 is a perspective view of the main portion separately shown in FIG.
Figure 5 is a block diagram showing the correlation between each component in the mobile compact photovoltaic system according to the present invention.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described in detail. In describing the present invention, when it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

1 to 4, the portable small photovoltaic power generation system according to the present invention is largely divided into a solar device unit 100 and a power generator device 200.

As illustrated in FIG. 1, the solar device unit 100 includes a support 110 and a solar module 120. The support 110 is a kind of support, and the solar module 120 is a known solar panel. Here, the solar module 120 is installed on the support 110 to function to convert solar energy into direct current electricity. On the other hand, the solar module 120 is provided with a module plug 121 to transfer the converted direct current electricity to the generator 200.

The module plug 121 is detachably connected to a module outlet 221 electrically connected to the solar controller 220 which will be described later.

Since the technology of converting solar energy into direct current electricity through the solar module 120 is already known, a detailed description thereof will be omitted.

The generator 200 is composed of a carrier 210, a solar controller 220, a battery 230, an inverter 240, the outlet 250 and the remaining battery indicator 260 is further reinforced , Converts the DC electricity received through the solar device unit 100 to AC electricity to provide to the user.

2 to 4, the carrier 210 includes a bottom plate 211, a plurality of pillar members 212, a pair of side plates 213, a mounting plate 214, and a ceiling plate 215. The front plate 216, the first door part 217, the second door part 218, and the diaphragm 219 constitute a housing capable of accommodating devices therein.

The bottom plate 211 is a rectangular plate having a predetermined thickness. In the present embodiment, four pillar members 212 are disposed at the upper edges of the bottom plate 211, and the arranged pillar members 212 are fixed to the bottom plate 211 through fastening means, and the bottom plate ( Four casters 211a are provided at the edge of 211.

Referring to FIG. 4, the pillar member 212 has a fan shape when viewed in a plan view, and a side plate guide groove 212a and an installation member guide groove 212b are integrally formed on a right angled surface in a longitudinal direction. . The installation member B is inserted into the installation member guide groove 212b so as to be movable. In the present embodiment, the magnet (M) or the hinge (H) is installed through the installation member (B).

The pair of side plates 213 are plates having a predetermined thickness, and are disposed to face each other between the pillar members 212 in the longitudinal direction, and both end portions of the side plate guide grooves 212 a of the pillar members 212. Is inserted. In particular, the upper and lower ends of the side plate 213 are arranged inwardly facing the bent side, the bent side is fixed to the bottom plate 211 and the ceiling plate 215 through the fastening means to form a side wall. . In addition, the side plate 213 is provided with a plurality of vents for discharging the heat generated from the inside to the outside, the handle is installed in the center to carry the user. On the other hand, any one of the pair of side plates 213 is provided with a module outlet 221 and the outlet 250, the module outlet 221 and the outlet 250 is installed so that the connection portion is exposed to the outside It is preferred for ease of use.

The mounting plate 214 is a plate having a predetermined thickness, and the center thereof is opened. In the present embodiment, the installation plate 214 is installed on the rear surface of the pillar member 212 in which the side plate 213 is not installed through an installation member (not shown).

The ceiling plate 215 is a rectangular plate having the same shape as the bottom plate 211. In the present embodiment, the bottom edge of the ceiling plate 215 is mounted on the upper surface of each of the pillar members 212 and the side plate 213 is fixed through the fastening means.

The front plate 216 is a plate having a predetermined thickness, like the mounting plate 214, the switch exposure unit 216a and the LED so that the switch of the inverter 240 and the LED of the battery remaining indicator 260 is exposed to the outside. The exposed part 216b is provided. In the present embodiment, the front plate 216 is fixed to the front surface of the installation plate 214 by a fastening means, and the front surface of the front plate 216 has a specification table for each device.

The first door part 217 is rotatably installed in the front of the front plate 216 via a hinge H. In the present exemplary embodiment, a confirmation window 217a is installed in the first door part 217, and an operation state of the inverter 240 and the battery remaining indicator 260 may be easily confirmed through the confirmation window 217a. On the other hand, the opposite pole member 212 is installed the hinge (H) is provided with a magnet (M) for fixing the first door portion 217 by magnetic force. In the case of the present embodiment is adopted by the fixing method by the magnetic force, which is only one embodiment to the last, a known coupling means may be applied if necessary.

The second door part 218 is rotatably installed via a hinge H on the opposite side where the first door part 217 is installed. The second door part 218 is also fixed by a magnet (M) installed opposite the hinge (H).

Here, the first door unit 217 operates the switch of the inverter 240 exposed through the front plate 216 and checks the operation state of the inverter 240 and the battery level indicator 260 with a related relationship. The second door part 218 is installed for the purpose of easily maintaining and repairing the devices installed therein.

The inside of the carrier 210, specifically, between the pair of side plates 213 is provided with a diaphragm 219 to partition the internal space of the carrier 210. In particular, the diaphragm 219 is provided with an electronic device such as a solar controller 220, an inverter 240, and a battery remaining indicator 260.

According to the present exemplary embodiment, since the electronic device (the solar controller 220, the inverter 240, the battery remaining indicator 260) and the battery 230 are separated from each other through the diaphragm 219, the battery 230 of the battery 230 is disposed. The heat generated during charging and discharging has an advantage of preventing the semiconductor of the electronic device from being damaged in advance.

Subsequently, the solar controller 220, the battery 230, the inverter 240, the outlet 250, and the battery remaining indicator 260 constituting the generator 200 will be described.

The solar controller 220 has a module outlet 221 connected via a wire. The module plug 121 is detachably inserted into the module outlet 221 and receives the direct current electricity supplied from the solar module 120 through the module plug 121 and delivers it to the solar controller 220. do. The solar controller 220 functions to charge the DC 230 received from the module outlet 221 to the battery 230.

In particular, the solar controller 220 is composed of a booster and charging unit, a feedback stabilization circuit unit and a microcomputer (MCU).

A brief description of the boosting unit and the charging unit, the feedback stabilization circuit unit, and the microcomputer (MCU) constituting the solar controller 220 is as follows.

The booster boosts a relatively low output voltage obtained from the solar module 120 above a rated voltage used for a general battery.

The charging unit is configured to charge the voltage supplied from the boosting unit to the battery 230, and separately includes an overcharge and overdischarge protection unit so that the battery 230 is not overcharged or overdischarged when the charging function is performed.

The feedback stabilization circuit unit stabilizes the battery 230 by generating a stabilization pulse, and includes a separate stabilization pulse generator. Here, the stabilization pulse generator continuously supplies a DC pulse wave to the positive electrode and the negative electrode to remove the sulfate (PbSO ₄ ) that is fixed to the pole plate of the battery 230 to increase the electricity generation area to create a regeneration condition of the battery 230 Has a configuration. In more detail, DC pulse wave current flows from the positive electrode to the negative electrode of the battery 230 to decompose the sulfate (PbSO ₄ ) remaining on the surface of the electric electrode, and the carbon suspension obtained by electrolytic oxidation is used for the battery ( As it is used as the electrolyte of 230), the electrolytic solution is activated by the electrochemical doping of the lead acid battery positive electrode and is configured to improve performance.

The microcomputer (MCU) performs a function of controlling the operation of the charging unit and the feedback stabilization circuit unit by sensing the voltage obtained from the solar module and the booster.

Since the configuration and function of the aforementioned solar controller 220 are well known in the art, a detailed description thereof will be omitted.

The battery 230 is installed inside the carrier 210, in the present embodiment is installed on the bottom plate 211 of the carrier 210, receives the direct current electricity from the solar controller 220 and stores it to the inverter ( Direct current to 240).

The inverter 240 receives a direct current electricity from the battery 230, converts it into an alternating current electricity, and transmits the same to the outlet 250.

The outlet 250 is a known device to which a plug of an electronic product is inserted and connected.

On the other hand, between the solar controller 220 and the battery 230 is further provided with a battery remaining indicator 260 to detect the remaining amount of the battery to be displayed to the outside. In the present embodiment, the battery remaining indicator 260 includes a plurality of LEDs to identify the charging and discharging process of the battery 230 as a related, and indicates the remaining amount of the current battery 230 through the LED lighting state It can be easily identified. As described above, since the device capable of checking the remaining amount of the battery 230 is already well known in the art, a detailed description thereof will be omitted.

On the other hand, the module outlet 221 and the outlet 250 is installed on any one of the pair of side plates 213, so that the user can easily expose the connection to the module plug of the solar device 100 It is preferable to be able to insert and withdraw the plug 121 and the electronic product.

Referring to the installation and operation of the subject innovation made of the above configuration as follows.

First, the installation process of the portable small photovoltaic power generation system according to the present invention will be described briefly, the solar device unit 100 is disposed outside, the power generation unit 200 is arranged in the room, the solar device unit Fixing the support 110 of the ground (100) to the ground, to fit the solar module 120 so as to correspond to the sun, the generator plug unit (120) drawn from the solar module 120 is disposed in the room ( Insert into the module outlet 221 of 200 to complete the installation.

The operation of the portable small photovoltaic power generation system of the present invention installed as described above with reference to FIG. 5, the solar module 120 of the solar device unit 100 refers to solar energy as electrical energy (hereinafter, referred to as direct current electricity). The converted DC electricity is transferred to the solar controller 220 through the module outlet 221 into which the module plug 121 is inserted, and the solar controller 220 transfers the received DC electricity to the battery 230. Will charge. At this time, through the battery remaining indicator 260 installed between the solar controller 220 and the battery 230, it is possible to check the charging and discharging process of the battery 230 as a related.

In addition, the battery 230 receives the DC electricity from the solar controller 220 and stores the same, and delivers the same to the inverter 240. The inverter 240 receives the DC electricity from the battery 230 and receives the AC electricity. Converted to and delivered to the outlet 250.

Therefore, the user may insert the plug of the electronic product into the outlet 250 and then use the electronic product.

According to the present embodiment, the solar device 100 and the power generation unit 200 as described above have an advantage of easily producing electricity in themselves even in a region in which electricity supply is difficult.

In addition, in the case of the carrier 210 has a relatively simple structure is easy to assemble, in particular, through the second door portion 218 of the carrier 210 has the advantage that the repair and replacement is quite easy, the carrier ( The caster 211a installed in the 210 may greatly improve the convenience of movement.

In addition, in the case of the carrier 210, the electronic device, that is, the solar controller 220, the inverter 240, the battery remaining indicator 260, and the battery 230 are separately disposed and disposed through the diaphragm 219. There is an advantage that can prevent the damage to the semiconductor of the electronic device due to the heat generated during the charge and discharge of the battery.

Although the present invention has been described in detail only with respect to the specific embodiments described, it will be obvious to those skilled in the art that various modifications and changes can be made within the technical scope of the present invention, and such modifications and modifications belong to the appended utility model registration claims. will be.

100: solar unit 110: support 120: solar module
121: module plug 200: power generation unit 210: carrier
211: bottom plate 212: pillar member 213: side plate
214: mounting plate 215: ceiling plate 216: front panel
217: first door part 218: second door part 219: diaphragm
220: solar controller 230: battery 240: inverter
250: outlet 260: battery level indicator

Claims (8)

Solar unit 100 for converting solar energy into direct current electricity:
The bottom plate 211 is provided with a caster (211a) on the bottom, and a plurality of pillar members 212 is installed on the upper edge of the bottom plate 211, and are disposed to face each other and are installed between the pillar members 212 Between the pair of side plates 213 forming a side wall, the pillar member 212 without the side plate 213 installed, and the mounting plate 214 having an open center, and the edge of the bottom surface is a pillar member ( The front plate 216 installed on the front surface of the mounting plate 214 with a ceiling plate 215 mounted on the upper surface of the 212 and fixed, a switch exposure portion 216a and an LED exposure portion 216b. A first door part 217 rotatably installed on the front of the plate 216 via a hinge H, and a rotatably installed hinge on the opposite side on which the first door part 217 is installed. A carrier 210 having a second door part 218 to be formed;
A solar controller 220 installed in the carrier 210 and charging the battery 230 with direct current electricity supplied from the solar device unit 100;
A battery 230 which receives the direct current electricity from the solar controller 220 and stores it, and transmits the direct current electricity to the inverter 240;
Mobile small solar power system, characterized in that consisting of a generator unit 200 having an inverter 240 for receiving a direct current electricity from the battery 230 to convert into alternating current electricity.
The method of claim 1,
The carrier 210,
The portable small photovoltaic system, characterized in that the partition plate 219 is installed between the pair of side plates 213 further partitions the space.
The method of claim 1,
The first door unit 217 is a mobile small solar power system, characterized in that the confirmation window 217a is provided to reinforce the interior state.
The method of claim 1,
The solar controller 220 of the power generation unit 200 is further provided with a module outlet 221, characterized in that for receiving the direct current electricity transmitted from the solar device unit 100 via the module outlet 221. Portable small solar power system.
The method of claim 1,
The power generation unit 200 is a portable small photovoltaic system, characterized in that the outlet 250 for receiving the alternating current electricity converted from the inverter 240 is further provided with reinforcement.
The method of claim 1,
The power generation unit 200 is installed between the solar controller 220 and the battery 230 is a mobile miniature solar, characterized in that the battery remaining indicator 260 is further provided to sense the remaining amount of the battery to be displayed to the outside Photovoltaic system.
The method of claim 4, wherein
The module outlet 221 is a portable small solar power system, characterized in that installed on any one of the pair of side plates (213) to expose the connection to the outside.
6. The method of claim 5,
The outlet 250 is a portable small photovoltaic system, characterized in that installed in any one of the pair of side plates (213) to expose the connection to the outside.

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