KR101831986B1 - Solar power station - Google Patents

Abstract

The present invention stores energy using solar light and provides charging of the smart device through the stored energy to more conveniently charge the smart device in various places such as bus stop, India, road, outdoor, And more particularly to a solar power station for recharging a smart device using a super capacitor as an energy storage device and having excellent charging capacity and efficiency,
A main body and a solar charger provided in the main body and collecting energy from solar light, an energy storage device provided in the main body and storing the collected energy, and a smart device provided in the main body, And a smart device connection unit for applying the stored energy to the smart device to provide charging, wherein the energy storage device includes a super capacitor in which a plurality of unit capacitors are connected in parallel, in series or in series and in parallel.

Description

Solar power station for recharging smart devices {SOLAR POWER STATION}

The present invention relates to a solar power station for charging smart devices,

More particularly, the present invention relates to a method for storing energy using solar light and providing charging of a smart device through stored energy, thereby making it possible to more conveniently use smart devices in various places such as a bus stop, a road, And more particularly, to a solar power station for charging a smart device having excellent charging capacity and efficiency by using a super capacitor as an energy storage device.

Portable smart devices such as mobile devices, tablets, notebooks, and digital cameras, which are called smartphones, have already been deeply applied in everyday life. As time goes by, the technology is rapidly developing, and the penetration rate is also increasing and increasing.

Such a smart device can not only transmit and receive information anytime and anywhere by applying wireless communication technology, but also can use various contents, and inconvenience to battery capacity is increasing.

Therefore, although the capacity of the smart device is maximized during the manufacture of the smart device, there is a limitation in the capacity of the battery of the smart device. As an alternative, the use of the auxiliary battery is spreading, but the auxiliary battery is generally consumed.

When the user is indoors, the battery can be charged by using the outlet. However, since the power supply means is not provided in an outdoor place such as a bus stop, a road, a sidewalk, or a public place, charging of the battery is difficult.

For this reason, a charging device capable of easily charging a mobile phone is required in the outdoors, but it is difficult to apply easily due to various problems such as securing a power source for charging, maintenance cost of the device, and charging efficiency.

[0004] As a conventional technology relating to a charging device provided in the outdoors, there is a charging system for portable devices for public places using solar light (hereinafter referred to as "prior art") (Japanese Patent No. 10-1436729 (Aug. 26, 2014) Technology is installed in a public place, the power generated from the solar energy is stored in a battery, and the converted voltage is converted into a predetermined voltage, so that the technology can be used for charging a smart device through a standardized USB port.

However, the prior art also fails to solve the problem of charging efficiency, which is one of the problems mentioned above. However, problems such as the lifetime of the battery, the guarantee of the charging speed by the battery, and the problem caused by external environmental factors including temperature and humidity I still have it.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems,

It is more convenient to charge the smart device in various places and various environments such as bus stop, India, road, outdoor, public places, etc. Especially, by using super capacitor as energy storage device, charging capacity is excellent, It is easy to maintain / manage, fast charging cycle by fast charge / discharge cycle, low risk of trouble due to wide operating temperature, high efficiency of charging / discharging and environmental friendliness, The purpose is to provide.

The present invention having the above object

A main body and a solar charger provided in the main body and collecting energy from solar light, an energy storage device provided in the main body and storing the collected energy, and a smart device provided in the main body, And a smart device connection unit for applying the stored energy to the smart device to provide charging, wherein the energy storage device includes a super capacitor in which a plurality of unit capacitors are connected in parallel, in series or in series and in parallel.

Also, the energy storage device may include an input module for receiving power from the solar photovoltaic module, a control module for controlling charging of the super capacitor, an output module for applying power to the smart device connection module, And a voltage transforming module for converting the voltage.

In addition, the supercapacitor may include a parallel connection unit for connecting the unit capacitors in parallel and a serial connection unit for connecting the unit capacitors in series, wherein the parallel connection unit includes a plate and a plate And the terminal unit may include a terminal connecting portion to which the terminals of the unit condenser are coupled. The serial connecting means may include a plate, a connecting piece projecting upwardly and downwardly from the plate end portion, a connecting hole provided on the connecting piece, And a coupling member inserted through the hole.

Further, the control module may include a charge control unit for controlling the charging of the unit condenser through the collected energy, a power output unit for outputting energy stored in the unit condenser, and a control unit for controlling the charge control unit and the power output unit A filter unit for removing the detected noise, a filter driving unit for driving the filter unit only at the time of noise detection, a filter unit for driving the filter unit only at the time of noise detection, And a signal generating module having a signal generator for generating the control signal from the signal power source from which the noise is removed, and a signal output unit for checking whether the control signal is clean or not and outputting the signal.

According to the present invention,

It is more convenient to charge the smart device in various places and various environments such as bus stop, India, road, outdoor, public places, etc. Especially, by using super capacitor as energy storage device, charging capacity is excellent, It is easy to maintain / manage, has a fast charging / discharging cycle, has a high charging speed, has a low operating temperature, and has high charging / discharging efficiency and improved environmental friendliness.

1 is a configuration diagram of the present invention. (First embodiment) Fig.
Fig. 2 is a configuration diagram of the present invention (second embodiment). Fig.
3 is a schematic circuit configuration of the present invention.
4 to 6 show a third embodiment of the present invention.
7 and 8 show a fourth embodiment of the present invention.

While the present invention has been described in connection with certain embodiments, it is obvious that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention. It is to be understood, however, that the invention is not intended to be limited to the particular forms disclosed, but on the contrary, is intended to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

In the drawings, the same reference numerals are used for the same reference numerals, and in particular, the numerals of the tens and the digits of the digits, the digits of the tens, the digits of the digits and the alphabets are the same, Members referred to by reference numerals can be identified as members corresponding to these standards.

In the drawings, the components are expressed by exaggeratingly larger (or thicker) or smaller (or thinner) in size or thickness in consideration of the convenience of understanding, etc. However, It should not be.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the term " comprising " or " consisting of ", or the like, refers to the presence of a feature, a number, a step, an operation, an element, a component, But do not preclude the presence or addition of one or more other features, integers, steps, operations, components, parts, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries are to be interpreted as having a meaning consistent with the contextual meaning of the related art and are to be interpreted as either ideal or overly formal in the sense of the present application Do not.

It is to be understood that the first to second aspects described in the present specification are merely referred to in order to distinguish between different components and are not limited to the order in which they are manufactured, It may not match.

The present invention stores energy using solar light and provides charging of the smart device through the stored energy to more conveniently charge the smart device in various places such as bus stop, India, road, outdoor, And more particularly to a solar power station for recharging a smart device using a super capacitor as an energy storage device and having excellent charging capacity and efficiency.

Hereinafter, a solar power station (hereinafter referred to as " present station P ") for charging a smart device E according to the present invention will be described in detail with reference to the accompanying drawings.

1 and 2 relate to the first and second embodiments of the present invention, respectively. Fig. 1 shows an embodiment in which the main body 6 of the station P is constituted by a mounting type main body 6A and Fig. 2 shows an embodiment in which the main body 6 of the station P is constituted by a portable main body 6B .

1 and 2, the station P mainly includes a main body 6, a solar charger 7 provided in the main body 6, an energy storage device 8 provided in the main body 6, And a smart device connection unit 9 provided in the main body 6.

As shown in FIGS. 1 and 2, the main body 6 is provided with a mounting type main body 6A installed at a specific place, And the portable main body 6B.

As shown in FIG. 1, the installation-type main body 6A can be installed at a specific place such as a bus stop, a road, a delivery place, a public place, and the like. The shape of the installation-type main body 6A need not be specified in any one of them.

In addition, the installation type main body 6A may further include a CCTV for monitoring the present station P, an LED illumination for night use of the present station P, and a billboard.

Also, as shown in FIG. 2, the portable main body 6B is provided so that it can be carried by a user or relocated as needed, and it is not necessarily required to be specified in any form.

In addition, the portable main body 6B may further include a recording medium (e.g., CD) insertion portion and the like.

The selection of the main body 6 can be freely changed according to the choice of the operator, and can be varied depending on the purpose, environment, etc. of utilizing the present station P.

Next, the solar photovoltaic unit 7, which is a component of the present station P, collects energy from sunlight and operates on a principle similar to that of a solar cell, a solar power plant, etc., Although the term "sunlight" is used in consideration of the high use, it may include all the ways of collecting energy using the sun, such as solar heat.

Next, the energy storage device 8, which is a constituent of the present station P, is configured to store the collected energy. A key feature of the present invention is that the energy storage device 8 includes a plurality of unit capacitors C And a super capacitor S connected in parallel, in series or in series and in parallel.

The super capacitor (S) is a power source that has a much larger capacity than general capacitors (capacitors) and electrolytic capacitors, and collects a lot of energy and emits high energy for several tens of seconds or several minutes. (S) is a useful new renewable energy (solar) storage device that can fill in the performance characteristics that can not be achieved. Especially, Super Capacitor (S) has excellent charging performance for storage of all renewable energy do.

The super capacitor (S) has a long lifetime, a charge and discharge cycle of several hundred thousand times, a wide operating temperature condition (-40 ~ + 90 ℃), a high charging and discharging efficiency (95 ~ 99% , An energy saving device optimized for the present station (P) utilizing sunlight, because it has the advantage of being made of environmentally friendly materials.

Next, the smart device connection unit 9, which is a configuration of the present station P, is configured to connect the smart device E and apply the energy stored in the energy storage device 8 to the smart device E Provides charging.

It is preferable that the smart device connection unit 9 has a terminal unit for connection with the external smart device E, and the terminal unit may have various forms.

Also, in the present invention, it is preferable that the smart device E is interpreted as a concept including all electronic devices requiring power such as a smart phone, a tablet, a notebook, a Bluetooth speaker, and a digital camera.

The present invention having the above-described configuration and features can more conveniently charge the smart device (E) in various places and various environments such as bus stop, delivery, road, outdoor, public place, In battery charging can be done anywhere easily.

Further, the station P uses a super capacitor (S) to provide excellent charging capacity, easy maintenance / management due to a semi-permanent life span, fast charging speed due to a fast charging / discharging cycle, It is possible to provide effects such as high charging / discharging efficiency and improved environmental friendliness.

Additional features of the present invention will now be described with reference to Figures 3-8.

3 is a diagram showing a schematic structure related to the circuit configuration of the present invention.

3, the present station P comprises an energy storage device 8 further comprising an input module 81, a control module 82, an output module 83, and a transformer module 84 .

First, the input module 81 receives power from the solar charger 7, and the power for charging the super capacitor S is input through the input module 81.

The control module 82 controls the charging of the super capacitor S and not only controls the charging of the super capacitor S but also controls the charging of the input module 81 and the output module 83, , And the transformer module 84. The control module < RTI ID = 0.0 > 84 < / RTI >

Next, the output module 83 is configured to apply power to the smart device connection unit 9, and supplies power from the super capacitor S to the smart device connection unit 9 for charging the smart device E.

Next, the transformer module 84 is configured to convert the voltage of the power source applied by the output module 83, and the station P is provided with various smart modules 84 having different charging voltage specifications through the transformer module 84, So that the charging of the device E can be performed stably.

Fig. 4 to Fig. 6 show a specific configuration of the super capacitor S according to an embodiment (third embodiment) of the present invention.

4 to 6, the super capacitor S constituting the energy storage device 8 of the present invention comprises a combination of unit capacitors C as mentioned above, And a series connection means 2 for connecting the unit capacitors C in series with the parallel connection means 1 for connecting the unit capacitors C in parallel with each other.

With the provision of the connecting device L having such a configuration, the present invention can variously connect the unit capacitors C in series, parallel, or series-parallel so as to obtain a desired charging capacity.

(Hereinafter, the combination of the unit capacitors C connected by the parallel connection means 1 will be referred to as a condenser unit U.)

4 to 6 (in particular, FIG. 6), the parallel connection means 1 of the connection device L comprises a plate 10, And a terminal coupling unit 11 provided on the base 10 for coupling the terminals of the unit condenser C to each other.

The parallel connection means 1 will be described in more detail with reference to FIGS. 4 to 6 (particularly FIG. 6). First, the plate 10 is provided with a base to which the unit capacitors C are coupled. The terminal of the unit condenser C is connected to the terminal coupling portion 11 provided on the main body portion 11 and the number of the terminal coupling portions 11 is provided corresponding to the number of unit capacitors C to be connected in parallel .

6 shows an example in which four unit capacitors C to be connected in parallel are provided. Therefore, there is shown an embodiment in which four terminal connecting portions 11 are arranged on the plate 10, It can be inferred that the condenser C constitutes one condenser unit U.

6A and 6B, the terminal fitting portion 11 may be divided into a welding type terminal fitting portion 11W and a fastening type terminal fitting portion 11L .

The welded terminal fitting portion 11W is composed of a seating portion on which the terminal of the unit condenser C is seated and a welding expected portion disposed on the seating portion so that the seating portion and the terminal are welded .

For example, the welding type terminal joining portion 11W may be formed by laser welding (Razor Welding), electric arc welding, oxygen welding, argon welding, or the like Can be used.

The fastening type terminal engaging portion 11L is composed of a through portion through which the terminal of the unit capacitor C passes and a nut member fastened to the terminal passing through the through portion, To be coupled to the plate (10).

In this case, it is a matter of course that the nut member must be provided sufficiently larger than the penetrating portion, and it is a matter of course that the terminal is provided with a thread for coupling with the nut member. In FIG. 6, the nut member is omitted, It would be no problem to infer the presence of a nut through.

For example, a steel screw, a nut, a washer, a rivet, a bolt, or the like may be used as the fastening type terminal engaging portion 11L.

It is possible to obtain the super capacitor S having a desired charging capacity by connecting the unit capacitors C in parallel through the parallel connection means 1 having the above configuration and characteristics. The joint method is to break the conventional soldering structure and short circuit of the joint due to the soldering which is a disadvantage of the soldering structure, complication of the strength member and the production line due to introduction of PCB for soldering, And the like can be solved.

In addition, the above-described parallel connection means 1 also breaks the bus bar structure, which causes a heat problem due to a resistance of the fastening portion and a load increase which are disadvantages of the bus bar structure and a failure due to external impact and vibration The problem of increasing the complexity of the assembly and assembly process, and the difficulty of standardization can be solved.

Therefore, the parallel connection means 1 of the present invention has the effect of being electrically stable, minimizing the number of members for connection, and improving stability and durability.

4 to 6 (in particular, Fig. 6), the serial connection means 2 of the connection device L is composed of a plate 10, a connection piece 18, which is vertically protruded from the end of the plate 10, A connection hole 23 provided on the connecting piece 22 and a coupling member (not shown) inserted through the connection hole 23.

The plate 10 is provided with a base to which the unit capacitors C are coupled with the same structure as the plate 10 mentioned earlier in the parallel connection means 1.

It is preferable that the next connecting piece 22 protrude up and down at the end of the plate 10 in a direction opposite to the direction in which the unit capacitor C is coupled with respect to the plate 10.

For example, when the unit condenser C is coupled to the upper portion of the plate 10, the connecting piece 22 protrudes downward from the end of the plate 10, The connecting piece 22 is protruded upward from the end of the plate 10. [0050] As shown in Fig.

The connecting piece 22 may be formed by welding the connecting piece 22 to the plate 10 or by molding the connecting piece 22 so as to protrude to the outside of the end of the plate 10 at the time of forming the plate 10 It is also possible to bend it.

The next connecting hole 23 is an opening provided on the connecting piece 22 to provide the insertion of a connecting member (not shown).

The two plates 10 of the two unit condensers C or the condenser units U to be connected in series are stacked in such a manner that the respective connecting pieces 22 are overlapped with each other. So that the connection holes 23 are arranged at the same position. (Not shown) so as to penetrate both of the two connection holes 23 so that the two plates 10 are attached to the coupling member (not shown), the unit capacitor C by the series connection means 2, Is completed.

The coupling member (not shown) of the serial connection means 2 may also be divided into a welding type coupling member and a coupling type coupling member similarly to the parallel coupling means 1 described above.

Here, the welded joint member is a filler material to be melted and inserted into the joint hole 23, and the joint member can be formed of a screw, a rivet, a screw, etc. inserted into the joint hole 23, (Welding method and fastening method) can be applied here.

It is an object of the present invention to provide a soldering structure and a bus bar structure which are manufactured from a solder structure and a bus bar structure and which are electrically stable and minimized in the number of members for connection and are improved in stability and durability Effect can be provided.

4 to 6, the supercapacitor S of the present invention includes a voltage balancing module 60 for uniformly controlling the voltage difference between the unit capacitors C and the voltage difference between the capacitor units U, ). [0027] In addition,

It is preferable that the voltage balancing module 60 is provided in the form of a balancing bar inserted into the connection hole h60 provided on the plate 10. The balancing bar is connected to the unit capacitor C (U), and are disposed between the unit capacitors C connected in parallel to each other.

Also, the voltage balancing module 60 may be provided with a central processing unit (CPU, MCU, MICOM, etc.) to perform a control operation.

4 to 6, the supercapacitor S of the present invention further includes a fixing shaft 13 for supporting the coupling between the unit capacitors C or the coupling between the condenser units U. And the like.

It is preferable that one of the stationary shafts 13 is connected and fixed to all the condenser units U so as to enhance the structural stability of the condenser units U.

4 to 6, the plate 10 is provided with a shaft hole h13 at its center, and the stationary shaft 13 is inserted through the shaft hole h13, and the unit capacitors C And the series connection between the capacitor units U through which the stationary shaft 13 provides the overall structural stability and improved durability of the super capacitor S,

It is preferable that the stationary shaft 13 is wrapped around the outer surface of the stationary shaft 13 by an insulating covering material to prevent a short circuit.

In addition, an eye nut (not shown) may be coupled to both ends of the fixed shaft 13, and such an eye nut provides convenience in installation, fixing, and mounting of the super capacitor S.

In the present invention, it is preferable that the super capacitor (S) is surrounded by the insulation shrink tube to have a protection effect against external impact and an insulation effect, and the insulation shrink tube and the condenser unit U are preferably provided with a buffer material such as urethane to maximize the protection effect and the insulation effect.

4 to 6, the super capacitor S includes a substrate 41 which is placed in contact with the plate 10 of the condenser unit U disposed at both ends, A support plate 42 disposed in contact with the support plate 42, and a fixing plate 43 disposed in contact with the support plate 42.

The substrate 41 provides a circuit configuration of the control module 82 and the support plate 42 and the fixing plate 43 provide escape prevention and bonding strength enhancement of the assembly of the condenser unit U.

The substrate 41, the support plate 42, the fixing plate 43, and the like can be variously used, and various coupling methods using a plurality of fixing members can be utilized.

Figs. 7 and 8 are views related to the fourth embodiment of the present invention. Fig.

7 and 8, the control module 82 of the present station P includes a charge controller 821 for controlling the charging of the unit capacitor C through the collected energy, a charging controller 821 for controlling charging of the unit capacitor C via the unit condenser C, A power output unit 822 for outputting stored energy and a central control unit 823 for controlling the charge control unit 821 and the power output unit 822 through a control signal.

In particular, the central control unit 823 includes the above-mentioned input module 81, output module 83, and power transformer module 84 as well as the respective components (the charge control unit 821, the power output unit 822) ). Noise may be introduced into such a control signal due to various external factors such as influences by high frequency, interference by strong electric field of the power source, and external environment (temperature, humidity, dust, etc.).

The noise introduced into the control signal rapidly increases or decreases the voltage level of the control signal, causing unstable operation of each structure, and further, it may cause malfunction and failure.

In order to solve this problem, the present invention includes a signal generation module (100) for generating a control signal in a clean state from which the possibility of noise is excluded, thereby detecting and removing noise to be introduced into the control signal in advance, Operation control is enabled.

The signal generation module 100 of the present invention is characterized in that it detects and removes noise through various steps and re-detects whether noise of the control signal is included before the control signal is finally output.

Hereinafter, the signal generation module 100 according to the fourth embodiment of the present invention will be described in detail with reference to FIG.

(For the sake of convenience, it is not necessary to distinguish the names of the device units in the following description.) Therefore, it is preferable to deduce through the corresponding circuit including each element,

8, the signal generation module 100 includes a noise amplification unit 110 for amplifying a DC signal power, a noise detection unit 120 for detecting noise included in the amplified signal power, A filter driving unit 140 for driving the filter unit only when noise is detected, a signal generating unit 150 for generating a control signal from the signal power source from which noise has been removed, and a control unit 150 for stabilizing and outputting the generated control signal And a signal output unit (160).

The signal generating module 100 amplifies the DC signal power by the noise amplifying unit 110 so that the noise included therein is also amplified to facilitate detection, and the noise included in the signal power source amplified by the noise detecting unit 120 is detected The noise elimination process is performed only when the noise is detected through the filter driving unit 140, thereby preventing unnecessary power consumption and operation overload, and the signal generating unit 150 And generates a clean control signal from the signal power source from which noise has been removed. The signal output unit 160 confirms whether or not the signal is cleaned and outputs the clean signal.

Hereinafter, with reference to FIG. 8, a detailed description of each sub-configuration of the signal generation module 100, a description of an operation process, and effects of the sub-module will be described.

The noise amplifying unit 110 includes a first amplifying circuit 111 for first amplifying the signal power source and a second amplifying circuit 112 for secondarily amplifying the signal power.

The first amplifying circuit 111 and the second amplifying circuit 112 have the same structure and each have a distribution resistor R101 connected to the (+) terminals of the amplifiers A101, A102, A101, A feedback resistor R105 R106 and a capacitor C105 connected in parallel between the output terminal and the negative terminal of the resistors R102, R103 and R104, the capacitors C101 and C102 and the amplifiers A101 and A102, ) C106.

The operation and effects of the first amplifying circuit 111 and the second amplifying circuit 112 will be described by taking the first amplifying circuit 111 as an example. The amplifier A101 includes the dividing resistors R101 and R102, R106), and a grounding resistor to operate as a non-inverting amplifier to amplify the voltage level of the signal power supply, so that the noise is also amplified to facilitate detection of noise. At this time, the feedback capacitor C105 prevents the oscillation of the amplifier A101.

In the second amplifying circuit 112, the signal power is amplified through the same process.

The noise amplifier 110 is connected between the amplifier output terminal of the first amplifier circuit 111 and the amplifier (+) terminal of the second amplifier circuit 112, The signal is firstly amplified by the first amplifying circuit 111 and the output is amplified by the second amplifying circuit 112 so that the signal power is doubly amplified so that the noise can be easily detected.

Next, the noise detecting unit 120 includes a comparator 121, an applying circuit 122 connected to the (-) terminal of the comparator 121, and a reference circuit 123 connected to the (+) terminal of the comparator 121 .

More specifically, the application circuit 122 includes a DC component eliminating resistor R201 and a capacitor C201, which are arranged in series with each other, and a noise checking resistor R202.

The reference circuit 123 also includes bias resistors R203 (R204) (R205) arranged in parallel to each other to provide a reference voltage for noise determination.

The application circuit 122 receives the signal power amplified by the noise amplification unit 110 through a resistor R201 and a capacitor C201 via a direct current Removes the component and leaves only the noise component. Thereafter, a noise component is applied to the resistor R202.

Thereafter, the reference circuit generates a reference voltage by the bias resistors R203 (R204) and R205, and the comparator 121 compares the reference voltage with the noise voltage applied to the resistor R202 to detect whether or not noise is generated And a driving signal is transmitted to the filter driving unit 140 when the noise is detected to drive the filter unit 130 to remove the noise included in the signal power source and to transmit the non-driving signal to the filter driving unit 140 when no noise is detected The signal power is directly transmitted to the signal generating unit without driving the filter unit 130 without driving the filter unit 130. The selection of the transmission of the non- It may be different according to.

(The specific circuit configuration of the filter driver 140 is well known in the art, and a detailed description thereof will be omitted.

In addition, as shown in FIG. 8, the noise detector 120 preferably further includes a delay circuit 124 for delaying a signal transmitted to the relay.

The delay circuit 124 includes a reverse diode D201 and a resistor R206 arranged in parallel with each other and a capacitor C202 connected in parallel thereto.

The life of the filter driver 140 can be extended through the provision of the delay circuit 124. Since the noise is generated intermittently instead of continuously and periodically, the filter driver 140 is driven and not driven It is preferable to extend the life of the filter driving unit 140 by driving the filter driving unit 140 continuously until a predetermined time elapses after the operation of the filter driving unit 140. [

Next, the filter unit 130 includes first through third filtering circuits 131, 132, and 133, each of which has an output terminal and an input terminal sequentially connected to each other.

The first filtering circuit 131 includes npn-type first and second transistors Q301 and Q302 having emitters and collectors connected to each other, and the first and second transistors Q301 and Q302 D301 and D302 and capacitors C301 and C302 which are arranged in parallel to each other are connected to one another and the base of the first transistor Q301 and the base of the second transistor Q302 are connected in parallel to each other. Two capacitors C303 and C304 and two resistors R303 and R304 in series with the capacitor C304 are connected.

The second filtering circuit 132 has the same structure as the first filtering circuit 131.

The third filtering circuit 133 includes two capacitors C305 and C306 arranged in parallel with each other and two resistors R305 and R306 connected in series with the capacitor C306, And the third filtering circuit 133 is provided with a reverse current prevention diode D303.

Since the noise can be removed in three stages through the filter unit 130 having the above-described features and features, noise can be removed more effectively than the noise filter of the related art, and a signal power source So that there is an advantage that additional commutation or DC conversion process is not required.

Next, the signal generator 150 includes a plurality of diodes D501 and D502 for providing a voltage drop for generating a control signal, a filtering inductor L501 connected in series with the diodes D501 and D502, And capacitors C501, C02, C503, and C504 connected in parallel to the inductor L501.

Although the two voltage drop diodes D501 and D502 are shown in the drawing, the voltage drop diodes D501 and D502 may be provided in a plurality of voltage drop diodes D502 and D502, respectively.

The operation and characteristics of the signal generator 150 will be described. The signal power source from which the noise is removed passes through the voltage drop diodes D501 and D502 and is converted into a voltage level suitable for the control signal. The generated noise is removed by the filtering inductor L501 and the filtering capacitors C501, C02, C503 and C504 to generate a clean control signal and transmit it to the signal output unit 160. [

Next, the signal output section 160 includes an output control element 161 for controlling the output of the control signal, a stabilization circuit 162 connected to the output control element 161 for eliminating the noise included in the control signal, A sensing circuit 163 connected to the control element 161 for sensing the state of the control signal and feeding back the output signal to the output control element 161 and a power supply circuit 164 for supplying power to the output control element 161 .

The operation and characteristics of each circuit are as follows. First, the stabilization circuit 162 includes a resistor R601 and a diode D601 connected in series and a capacitor C601 connected in parallel thereto.

The stabilization circuit 162 stores the transferred control signal in the capacitor C601 via the resistor R601 and the diode D601 to provide a buffer for the signal input so as to suppress the break of the control signal, 161 from being overloaded.

The next sensing circuit 163 includes a voltage-converting resistor R602, a resistor R603, and a filtering capacitor C602 (C603).

This sensing circuit 163 converts the current of the control signal to a voltage through the resistor R602 and is applied to the resistor R603 and filtered through the capacitors C602 and C603 to be delivered to the output control element 161 do. Thereafter, the output control element 161 confirms whether or not the noise of the control signal to be finally output is included through the sensing circuit 163, and outputs the control signal or commands the filtering of the control signal.

Next, the power supply circuit 164 includes a voltage conversion resistor R604 (R605), a charging capacitor C604 (C605) and C606 connected in parallel thereto, and a discharge prevention diode D604 connected in series thereto.

The output control element 161 is preferably an element for finally checking and outputting an output state of a control signal. It is preferable that the output control element 161 is provided with an additional power supply means for emergency situations as well as power supplied to the entire product . To this end, the power supply circuit 164 appropriately processes the signal power source and supplies power for driving the output control element 161 separately.

This power supply circuit 164 stores the signal power for which the noise is removed through the voltage conversion resistors R604 and R605 in the capacitors C604, C605 and C606, The power charged in the capacitors C604, C605, and C606 is not discharged through the diode D604 at this time, and when the emergency situation occurs, the power is supplied to the output control element 161 Allow power to be supplied.

Although the description of the additional elements constituting each circuit is omitted in the above description, it is possible to change the design according to the practice of the ordinary artisan.

In addition, the present invention described with reference to the accompanying drawings can be variously modified and changed by a person skilled in the art, and such modifications and changes should be construed as falling within the scope of the present invention.

P: This station
6: Main body 7: Solar power charging part
8: Energy storage device 9: Smart device connection
S: Super capacitor C: Unit capacitor
L: connecting device
1: parallel connection means 2: serial connection means

Claims (4)

main body;
A solar charger provided in the main body and collecting energy from sunlight;
An energy storage device provided in the main body and storing the collected energy; And
And a smart device connection unit provided in the main body and connected to the smart device to supply stored energy to the smart device to provide charging,
The energy storage device includes a super capacitor in which a plurality of unit capacitors are connected in parallel, in series or in series and in parallel,

The super capacitor
A parallel connection unit for connecting the unit capacitors in parallel and a serial connection unit for connecting the unit capacitors in series,
Wherein the parallel connection means includes a plate and a terminal coupling portion provided on the plate and to which the terminal of the unit condenser is coupled,
Wherein the serial connection means includes a plate, a connection piece projecting upwardly and downwardly from the plate end, a connection hole provided on the connection piece, and a coupling member inserted through the connection hole,

The supercapacitor further includes a fixing shaft for supporting a coupling between the unit capacitors or a coupling between the condenser units,
One of the fixed shafts penetrates through all of the condenser units and is connected and fixed, thereby enhancing the structural stability of the condenser units,
Wherein the plate has a shaft hole at the center thereof and the stationary shaft is inserted through the shaft hole to support a parallel connection between the unit capacitors and a series connection between the capacitor units,
Characterized in that the stationary shaft is enclosed by an insulating cladding on its outer surface to prevent short-circuiting.
The method according to claim 1,
The energy storage device
A control module for controlling charging of the super capacitor, an output module for applying power to the smart device connection unit, and a transformer module for converting a voltage of a power source applied from the output module, Further comprising a solar power station.
delete The method of claim 2,
The control module includes a charge control unit for controlling charging of the unit condenser through the collected energy, a power output unit for outputting energy stored in the unit condenser, and a central control unit for controlling the charge control unit and the power output unit through a control signal. , ≪ / RTI &

A filter unit for removing the detected noise, a filter driving unit for driving the filter unit only when the noise is detected, a power supply for the signal for which the noise is removed, Further comprising: a signal generating module for generating the control signal from the control signal generating unit and a signal outputting unit for confirming whether the control signal is cleaned and outputting the control signal,
Wherein the noise amplifying unit includes a first amplifying circuit for first amplifying the signal power source and a second amplifying circuit for secondarily amplifying the signal power,
The first amplifying circuit and the second amplifying circuit are respectively connected to the distribution resistors R101, R102, R103 and R104 connected to the (+) terminals of the amplifiers A101, A102, A101, A feedback resistor R105 R106 and a capacitor C105 C106 connected in parallel between the output terminal and the negative terminal of the capacitors C101 and C102 and the amplifiers A101 and A102, 1 amplifier circuit and the amplifier (+) terminal of the second amplifying circuit are connected to each other,
The noise detection unit includes a comparator, an application circuit connected to the (-) terminal of the comparator, and a reference circuit connected to the (+) terminal of the comparator. The application circuit includes a DC component removal resistor R201, (R205) for providing a reference voltage for judging noise, the bias resistors (R203) and the noise checking resistor (R202) being arranged in parallel with each other,
The first filtering circuit includes npn-type first and second transistors (Q301 and Q302) having emitters and a collector connected to each other, and the first and second filtering circuits are connected to each other through an output terminal and an input terminal, The switching diodes D301 and D302 and the capacitors C301 and C302 are connected in parallel to the base of the first and second transistors Q301 and Q302, Two capacitors C303 and C304 arranged in parallel with each other and between the base of the first transistor Q301 and the base of the second transistor Q302 and two resistors R303 and R304 in series with the capacitor C304, Lt; / RTI >
The second filtering circuit has the same structure as the first filtering circuit,
The third filtering circuit includes two capacitors C305 and C306 arranged in parallel with each other and two resistors R305 and R306 connected in series with a capacitor C306. A reverse current prevention diode D303 is provided between the third filtering circuits 133,
The signal generator includes a plurality of diodes D501 and D502 for providing a voltage drop for generating a control signal, a filtering inductor L501 connected in series to the diodes D501 and D502, and a diode D501, D502, and an inductor L501, (C501), (C502), (C503), and (C504) connected filtering capacitors.

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