KR20110030255A - Blind having a function of two axis sun tracking and fluid flow path - Google Patents

Abstract

PURPOSE: A blind having a two-axis sun tracking function and fluid flow paths is provided to maximize the efficiency of solar energy collection by simultaneously tracking the altitude and azimuth angle of the sun. CONSTITUTION: A blind having a two-axis sun tracking function and fluid flow paths comprises hollow rotating pins(96), vertical frame slats(S2), mini horizontal fluid path slats(S1), and manifold fluid tubes(143m). The mini horizontal fluid path slats are connected in multiple stages through connection fluid tubes(143) and the manifold fluid tubes to form a fluid path in which the fluid drawn into the mini horizontal fluid path slats or the manifold fluid tubes flows. When the hollow rotating pins are rotated by the rotation of a second rotary shaft(93b), the vertical frame slats rotate to control the side angle and the mini horizontal fluid path slats provided in each vertical frame slat are controlled in the angular azimuth to the sun first. And, the mini horizontal fluid path slats provided in each vertical frame slat are simultaneously rotated by a tilt angle control unit driven with a first rotary shaft(93a) so as to control the angular azimuth to the sun secondly and all the mini horizontal fluid path slats face the sun.

Description

BLIND HAVING A FUNCTION OF TWO AXIS SUN TRACKING AND FLUID FLOW PATH}

The present invention relates to a two-axis solar-driven vertical flow path blinds, and more specifically, it is possible to track both the azimuth and altitude angles of the sun to maximize the condensing efficiency of solar energy and at the same time the sun is provided The present invention relates to a two-axis solar-driven vertical flow path blind that enhances energy utilization and enhances the function of the blind.

In general, a blind is a device that is installed in a window of a house, an office, or the like, and used for privacy protection, light, shading, and the like.

These blinds are divided into vertical blinds and horizontal blinds according to their shape, and are divided into electric and manual according to the driving source, and the operation line (thickness adjusting line, angle adjusting line) is pulled regardless of the type of driving source to perform the function. A plurality of slats are pulled up or down, left and right, or overlapped to perform a function desired by a user, such as shading and lighting.

The blinds having such a function have been developed in various forms for a long time, and the vertical blinds as shown in FIG. 1 used in a residential environment such as an apartment are the most representative forms currently used (horizontal blinds differ in direction only by 90 °. The principle of operation is the same).

According to the illustrated, when pulling the gap adjusting line 10, the holder 12 is slid left and right along the main shaft 14, so that the plurality of slats 30 can be unfolded at regular intervals or collected in one place to overlap. Pulling the angle adjustment line 20 rotates the main shaft 14 to operate the gears (not shown) built in the holder 12 to rotate the rotary pin 22 so that the plurality of slats 30 are simultaneously left and right. The angle can be adjusted while rotating in the direction to perform as many shades or mining functions as the user desires.

In this case, a spline is formed on an outer circumferential surface of the main shaft 14, and the holder 12 is correspondingly coupled to the holder 12, thereby allowing the holder 12 to slide in the longitudinal direction of the main shaft 14 while the main shaft ( 14) is rotated is configured to rotate together.

However, the field to which the present invention belongs is evolving into blinds in which technologies that can meet various market needs are continuously being developed as the market size is large and competition is accelerated. For example, the interval between blinds in terms of user convenience And technological advances in the direction in which the angle can be more easily adjusted and the lifespan can be extended, for example, related technologies such as registration room 281169, registration room 283751, registration room 400985, and registration room. Examples of 468382, 511520, 517274, 512800, Published Patent 2009-0090793, and the like can be exemplified.

In recent years, efforts to use environmentally friendly and limitless solar energy as energy sources have been underway due to the closure of fossil fuels and the strengthening of regulations on carbon emission rights. The movement to get electrical energy is taking place.

Power generation by this solar energy is made by the solar cell module 703 as shown in FIG.

Since the electromotive force generated by the photoelectric effect in the unit photovoltaic device 7031 is very small in practical use, the solar cell module 703 connects a plurality of photovoltaic cell elements 7031 to obtain a predetermined electromotive force. 7031) An electromotive force of approximately 0.4 to 0.5V is generated per unit, and the generated current increases in proportion to the intensity of the solar radiation and the area of the total photovoltaic cell element 7031.

In order to use the solar cell module 703 for a predetermined purpose, the capacity of the solar cell module 703 is adjusted according to the purpose of the solar cell module 703. In order to increase the generated voltage per unit area of the solar cell module 703, the solar cell It is common to connect the elements 7031 in series with each other with an inter connector ribbon 7042 to obtain as much power as necessary.

At this time, the material of the conductor connecting ribbon 7034 is usually made of Sn + Pb + Ag, Sn + Ag, Sn + Ag + Cu, and has a negative width of 1-3mm formed on the front surface of the photovoltaic cell element 7031 when connected in series. The negative polarity silver paste electrode wire is connected to the silver paste electrode wire having a positive (+) polarity of 3-5 mm width formed on the rear surface of the other photovoltaic cell device 7031 through the conductor connecting ribbon 7044, and the battery connection terminal ( 7032) is electrically connected, and this state is referred to as a solar cell module 703 semi-finished product.

The width of the conductor connecting ribbon 7042 connecting the photovoltaic elements 7031 is 1.5-3 mm and a thickness of 0.01-0.2 mm. The connection method is composed of an indirect connection method using an IR lamp, a halogen lamp, hot air, and a direct connection method using a soldering iron.

In addition, the semi-finished product of the solar cell module 703 is a bare state of electrical connection, which is only a set of connected solar cell elements 7031, so that a protective film is used up and down for practical use. In order to protect the semi-finished product of the solar cell module 703 from the impact or chemical corrosion from the outside, a light incidence transparent film 7035 having electrical insulating properties is disposed on the light incidence side. On the opposite side, the rear reinforcement film 7036 made of metal, plastic, or resin is disposed for the strength of the semi-finished solar cell module 703 or other purposes.

In addition, a thermosetting resin (EVA; vinyl) between the light incidence transparent film 7035 and the back reinforcement film 7036 and the photovoltaic cell element 7031 is high in transparency, light in weight, small in volume, and not easily damaged by external physical impact. The solar cell device 7031 is sealed using a cell filling film 7033 made of a material such as acetate-ethylene copolymer.

The light incidence transparent film 7035 is basically made to reach the photovoltaic cell element 7031 with sunlight, and is generally used in order to block the photovoltaic cell element 7031 from moisture and prevent physical damage. It is produced using a polymer resin.

Considerations in the light incident transparent film 7035 include transparency, weight, material used, antireflection, etc. to maximize light incidence to the photovoltaic cell element 7031 according to the application field of the photovoltaic cell element 7031. This applies.

In addition, the back reinforcement film 7036 is excluded only the transparency requirements for light incidence of the light incidence transparent film 7035 for the photoelectric effect, the reinforcement function as a basic premise, there are also considerations for various applications In case of installation on glass window, various technologies such as transparency for securing eyes, weight for installation location, heat conductive material for heat sink, insulation, etc. are applied.

Typically, two sheets of tempered glass are commonly used in the solar cell module 703 that is installed outdoors, as a light incidence transparent film 7035 and a back reinforcement film 7036. However, depending on the application, a metal plate provided with a plastic plate or an insulating layer may be used. Optionally available.

For example, in applications where weight is very important, bags, mobile phones, portable chargers, etc., glass is used rather than glass for reasons of load or management. When the light is irradiated with the light incident transparent film 7035, In order to reduce light reflection and increase light absorption, the front surface is specially treated in various ways to have high light absorption.

The rear reinforcement film 7036 is provided with a heat sink (not shown) according to an application, and is provided to cool the solar cell module 703 so that various technologies may be combined to prevent a decrease in power generation efficiency due to heat. Can be.

Therefore, it can be seen that the light incident transparent film 7035 and the back reinforcement film 7036 can be configured in various ways on the premise of basic functions in various ways.

The above description is a brief description of a commonly used solar cell module 703, the solar cell module 703 is produced by various types of solar cell module 703 in consideration of manufacturing cost and efficiency appropriately Can be.

In addition, when the above-described solar cell module 703 is mounted on the blinds, the blinds can be classified as a type of hoisting device because the blind function itself, which was conventionally limited to shading and mining, can follow the sun without additional equipment or supplementation. The mounting of the solar cell module 703 is expected to spread.

However, since the conventional blinds shown in the disclosed prior art are only rotatable in one direction, it is impossible to track both the azimuth and altitude angles of the sun that change with time at the same time. Since it is highly concentrated on the premise of incidence in parallel, when the solar light concentrating module is installed in the blind, it is possible to trace sunlight only on one axis, so the utility is very low.

Accordingly, a patent application (10-2009-0129310) (hereinafter referred to as 'first application 1') has been applied to a vertical blind that functions as a two-axis sun tracking function that tracks both the azimuth and elevation angles of the sun.

On the other hand, the Applicant pays attention to the application inside the slat of the conventional blind, for use in food waste treatment, etc., by forming a space in which the oil can flow in the inside of the blind slat that the angle is adjusted to directly face the sun A flow channel slat (hereinafter referred to as a "flow slat") formed with an inner flow path for introducing the inner flow path into the slat, and the flow oil heat exchanged by flowing the flow oil on the flow path connected in multiple stages using a connecting oil pipe Blinds with flow paths for direct use (hereinafter referred to as "euro blinds") have been patented (10-2009-0087802) (hereinafter referred to as 'first application 2').

For example, the channel blind according to the first application 2 focuses on the interior of a group of slats constituting the conventional blinds, and is utilized in various applications by expanding the functionality of the slats to the interior of the slats to use them as natural energy, air circulation, and cooling devices. It is possible to maximize the utilization efficiency of solar energy, for example, by recycling the high-temperature air cooled the solar cell module 703 mounted in the slat, additional solar energy in addition to the power generation efficiency can be utilized as a whole The utilization efficiency of solar energy can be made high. As described above, the euro blinds according to the first application have made technological advances to a considerable level in terms of the functional blinds, and the first application is a blind that traces both azimuth and elevation angles. There is a bar.

However, the first and second path blinds of the first application cannot limit the azimuth and the altitude of the sun, and the first application has the problem that no flow path is formed in the slat.

The present invention was created in view of the above-mentioned problems in the prior art, and can be solved at the same time. The azimuth and altitude angles of the sun can be traced at the same time, and an oil flow path is provided to increase the efficiency of solar energy-friendly energy sources. Its purpose is to provide a two-axis solar driven vertical flow path blind that can be used as a base technology.

According to the present invention, there is provided a cover; a pair of first and second rotary shafts, which are embedded in the cover, have splines formed on an outer circumferential surface thereof, are rotated by a driving source, and are spaced vertically; A first and second motors for driving the second rotation shaft, and blind control means for controlling the first and second motors; At least one second angle adjusting module having a worm gear and a hollow rotating pin fixed to the rotating shaft of the worm gear and horizontally movable horizontally from side to side by a vertical gap adjusting line; on an outer circumferential surface of the hollow rotating pin Vertical frame slats fixedly supported and rotated to the left and right, provided in parallel to the vertical frame slats in multiple down and at least a portion of each of the oil flow path is formed A pair of mini horizontal flow path slats; at least one connection oil pipe connected between the mini horizontal flow path slats to form a flow path therebetween; at least one manifold communicating with a plurality of the flow paths through the connection oil pipes Oil pipe; It is fitted to the first rotary shaft and is slidable, and is provided with an inclination angle adjusting means which is fixed to the upper end of the second angle adjusting module by one-to-one coupling and drawn downward through the inside of the hollow rotating pin; And a first angle adjusting module for adjusting the inclination angle of the pair of mini horizontal flow path slats, wherein the plurality of hollow body rotating pins are simultaneously rotated by the rotation of the second rotating shaft to rotate the vertical frame slats. When the left and right angles are adjusted, the azimuth angle to the sun of a set of mini horizontal flow path slats provided in each vertical frame slat By simultaneously rotating the pair of mini horizontal flow path slats simultaneously by the first rotation shaft, and by rotating the set of mini horizontal flow path slats by the first rotation shaft, the altitude angle with respect to the sun is adjusted secondly so that all the mini horizontal flow path slats are controlled by the sun's bearing and Opposed to an elevation angle, and the mini horizontal flow path slats are interconnected in multiple stages through the connecting oil pipe and the manifold oil pipe to form a flow path, whereby the oil introduced into the mini horizontal flow path slat or the manifold oil pipe is A two-axis solar driven drive vertical flow path blind is characterized in that it flows through the flow path.

In addition, the vertical frame slat, the upper end is fixed to the hollow rotating pin and rotated to the left and right, having a predetermined width in the horizontal direction, the horizontal slat mounting frame of the long rectangular frame shape in the vertical direction; and the horizontal slat Rotating balls formed in multiple stages at predetermined intervals on both sides of the mounting frame in a vertical direction; A plurality of mini horizontal rotating rods inserted into the rotating holes and freely rotating; the inclination angle adjusting means includes a winding drum inserted into the first rotating shaft and provided with a wire rope fixing member; One end is fixed to the winding drum through the wire rope fixing member, and the other end is pulled out downward through the hollow rotating pin without contact, and then the wire rope is bound to rotate the mini horizontal slats up and down; It is characterized by.

And the mini horizontal flow path slat comprises at least one slat oil pipe; and at least one slat oil passage tubular pipe connected to the slat oil pipe and coupled to the connecting oil pipe. Is formed by a hollow slat housing, the slat housing further comprises a light receiving window for receiving external light.

In addition, the manifold oil pipe is further connected to the oil supply pipe, the oil supply pipe is characterized in that it has a hollow through which the oil is moved, and a slat oil passage tubule for connecting the hollow to the connecting oil pipe, The supply pipe and the manifold oil pipe may further be provided with an oil control unit having at least one oil pump to control the supply and discharge of the oil flowing through the flow path (flowing), the oil control unit is the solar illuminance inside the flow path Sensors for measuring temperature, humidity, and pressure; A communication module for transmitting the detected value of the sensor to a control unit; It is characterized in that it comprises a microcontroller for controlling the opening and closing of the valve and the drive of the oil pump for oil supply, discharge according to the detection value.

Also preferably, the guider includes a guide rail having a predetermined open guide slot in the center; a guide rotating member including a bearing inserted into a slot of the guide rail and horizontally moving and freely rotating. Located at the bottom of the vertical frame slat parallel spaced intervals and is fixed to the wall or floor of the building is characterized in that it is installed.

More preferably, the solar cell module is further installed inside the mini horizontal flow path slat, and the solar cell module is guided to intensively irradiate the solar cell with the casein / gregorian main reflection role inside the mini horizontal flow path slat. A linear mirror member is further installed, and a linear optical module further includes a concave or convex mirror surface having a constant curvature corresponding to a casein grain / gregorian sub-reflection mirror inside the mini horizontal flow path slat. The light collecting efficiency to be irradiated can be maximized, and further comprising a power generation unit electrically connected to the solar cell module.

In addition, the mini horizontal euro slat has a feature that a mini solar collector tube and a solar collector module can be installed.

According to the present invention, it is possible to trace both the azimuth and altitude angles of the sun while performing a blinding or lightening function unique to the blinds, easy to mount and cool the solar cells, maximize the efficiency of solar energy use, and install a simple structure. Easy to install, not bulky enough to be installed indoors, manufacturing costs can be obtained inexpensive.

1 is an exemplary view showing the structure of a typical vertical blind
2 is a view showing a typical solar cell module
3 is a perspective view of a two-axis sun tracking drive vertical channel blind according to the first embodiment of the present invention
4 is an exploded perspective view illustrating main flow paths between different oil flow blind mini horizontal flow path slats;
5 is a perspective view of the type of connecting oil pipe and the manifold oil pipe
6 is a configuration diagram of an oil control unit;
7 is a perspective view of a two-axis solar driven drive vertical channel blind mounted with a solar cell module and a power generation unit according to a second embodiment of the present invention;
8 is a diagram illustrating a configuration of a power generation unit according to a second embodiment of the present invention.
9 is a view showing the configuration of a high concentration mini horizontal flow path slat according to a third embodiment of the present invention
FIG. 10 is a view illustrating a light focusing process of casee grain and Gregorian main reflecting mirror / sub-reflecting mirror. FIG.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment according to the present invention.

(First embodiment)

Figure 3 is a perspective view of a two-axis solar driven drive vertical flow channel blind according to the first embodiment of the present invention, Figure 4 is an exploded perspective view showing the main part formation and configuration between different mini horizontal flow path slats, Figure 5 is a connection An oil pipe and a manifold are perspective views of types of oil pipes, and FIG. 6 is a configuration diagram of an oil control unit.

As shown in FIG. 3, the biaxial sun driven drive vertical flow path blind 1 according to the present invention includes a cover 9, which is embedded in the cover 9, and a spline is formed on an outer circumferential surface thereof, and rotates by a driving source. And a pair of first and second rotary shafts 93a and 93b provided at intervals up and down; first and second motors 80a which are power sources for driving the first and second rotary shafts 93a and 93b. (80b); blind control means (81) for controlling the first and second motors (80a, 80b); a worm (94c) that is inserted into the second rotary shaft (93b) and slidable; A worm gear 94d, which is coupled to 94c) and vertically power-shifted, and a hollow rotating pin 96 fixed to the rotation shaft of the worm gear 94d, horizontally horizontally horizontally by a vertical gap adjusting line 92b. At least one second angle adjustment module 97b provided to be movable; fixedly coupled to the outer circumferential surface of the hollow rotating pin 96 and supported to rotate left and right Vertical frame slats (S2); a pair of oil flow blind mini horizontal flow path slats (S1), which are provided in parallel to the vertical frame slats (S2) in a plurality of downwards and are formed with oil flow paths in each; At least one connection oil pipe 143 connected between the flow path slats S1 and forming a flow path therebetween; at least one manifold oil pipe communicating with the plurality of flow paths through the connection oil pipe 143. (143m) ;, the oil supply pipe 142 connected to the manifold oil pipe (143m), the oil pump 32 is provided and installed on the cover 9 ;, is fitted to the first rotary shaft (93a) sliding Possible, one to one fixedly coupled to the upper end of the second angle adjustment module (97b) with a fixing member (F) and through the inside of the hollow rotating pin 96 is provided with an inclination angle adjusting means to be pulled downward and the set of Of mini horizontal Euro slats (S1) A first angle adjustment module 97a for adjusting the inclination angle; It is configured to include; an oil control unit 40 for controlling the oil pump 32.

The cover (9) enhances the appearance of the biaxial sun-driven vertical flow path blind (1) of the present invention, a pair of angle adjusting first and second rotary shafts (93a) (93b) and oil supply pipe (142) and a plurality It includes the first, second angle control module (97a) (97b).

At this time, the first rotary shaft (93a) is a rotary shaft for the mini horizontal flow path slat (S1), the second rotary shaft (93b) is a rotary shaft for the vertical frame slat (S2), where the mini horizontal flow path slat ( S1) is a slat of the concept applied to the existing horizontal blind, vertical frame slat (S2) is a slat of the concept applied to the existing vertical blind.

In addition, the first rotary shaft 93a and the second rotary shaft 93b have splines formed on the outer circumferential surface thereof, and the first rotary shaft 93a is positioned above the second rotary shaft 93b. Between them, a certain interval is maintained up and down.

In addition, the first rotation shaft 93a is provided with a plurality of first angle adjustment modules 97a. The first angle adjustment module (97a) is formed in a substantially rectangular box shape, is configured to be slidable in the longitudinal direction while being fitted to the first rotary shaft (93a), it is provided to maintain a constant interval when it is unfolded The second angle adjusting module 97b is fixedly coupled to the second angle adjusting module 97b horizontally moved by the vertical spacing adjusting line 92b to be described later and moved horizontally together with the vertical spacing adjusting line 92b. The horizontal spacing function of the vertical frame slats (S2) is the same as that of the existing vertical blind.

That is, the vertical gap adjusting string 92b is a pull line passage P provided at the bottom of the body of the second angle adjusting module 97b from the second angle adjusting module 97b to the rightmost second angle adjusting module 97b. It passes through), and is fixed to each of the second angle adjustment module (97b), and includes a draw restricting ribbon (92a), which is limited to prevent excessively drawn out, a pull line (92c) connected to the draw restriction ribbon (92a). At this time, the tow line 92c is connected to the vertical space adjusting line 92b and the drawout limiting ribbon 92a, and the vertical space adjusting line 92b and the drawout limiting ribbon 92a are also connected to each other.

Accordingly, the second angle adjusting module 97b is horizontally moved to the left by the vertical gap adjusting string 92b fixed to the second right angle adjusting module 97b by pulling the one tow string 92c (overlapping operation). The other second angle adjusting module 97b is pulled to overlap all the second angle adjusting modules 97b, while the other pulling line 92c is pulled out (pulling operation) while the connected draw restriction ribbon 92a is horizontally moved. The rightmost second angle adjustment module 97b is dragged so that all second angle adjustment modules 97b are drawn out at regular intervals.

In addition, a winding of the wire rope fixing member 94b fitted to the first rotation shaft 93a as an inclination angle adjusting means of a pair of mini horizontal flow path slats S1 is provided inside the first angle adjusting module 97a. One end is fixed to the drum 94a and the wire rope fixing member 94b, and the other end is pulled out downward through the hollow body rotating pin 96 without contact with the hollow body rotating pin 96 to be described later. A wire rope 95 wound around 94a is provided.

Since the winding drum 94a is splined to the first rotation shaft 93a, the winding drum 94a may be rotated together when the first rotation shaft 93a is rotated, and also in the longitudinal direction of the first rotation shaft 93a. It is configured to be freely slidable.

On the other hand, the second rotation shaft (93b) is provided with a second angle control module (97b) is provided to be movable in the horizontal direction, wherein the second angle control module (97b) is the first angle control module described above It is provided in the same structure as 97a.

However, the second angle adjustment module (97b) is different from the built-in configuration of the first angle adjustment module (97a), the second angle adjustment module (97b) in the worm (94c) to convert the power to be transmitted vertically And a worm gear 94d.

A hollow body rotating pin 96 is fixed to the worm gear 94d by penetrating the lower surface of the second angle adjusting module 97b and being fixed on the rotation shaft of the worm gear 94d.

At this time, the hollow rotating pin 96 is made of a hollow hollow shape, one end of the wire rope 95 wound on the winding drum (94a) hollow inside of the hollow rotating pin 96 It penetrates through and pulls out downward. In addition, the vertical frame slat (S2) is fixed to the lower outer peripheral surface of the hollow rotating pin (96).

The oil supply pipe 142 is supported by the cover 9 and is embedded therein, and includes a hollow through which the oil moves, and a slat oil passage tubule 1414 (see FIG. 4) connecting the hollow to the connecting oil pipe 143. It is preferable to be installed at a position that does not interfere with the overlapping, withdrawal and angle adjustment of the vertical frame slats S2.

The mini horizontal flow path slat (S1), as shown in Figure 4 (a), is provided in connection with the slat oil pipe (1411); and the slat oil pipe (1411) to the connecting oil pipe (143) It is configured to include; slat oil passage customs 1412 to be coupled.

The vertical frame slat (S2) is fixed to the upper end is coupled to the hollow rotating pin 96 and rotated to the left and right and has a predetermined width in the horizontal direction, the horizontal slat mounting frame of the long rectangular frame shape in the vertical direction (S2a); Rotating hole (S2b) formed in a plurality of stages at predetermined intervals on both side frames in the vertical direction of the horizontal slat mounting frame (S2a); A plurality of mini horizontal rotating rods (S1a) supporting the slat oil pipe (1411) and inserted into the rotary hole (S2b) and freely rotated, and a plurality of pairs are formed on the outer peripheral surface of the lower end of the hollow rotating pin (96). Is installed.

And the mini horizontal pivot rod (S1a) is positioned at the top of the center of gravity so that the mini horizontal flow path slat (S1) is vertically parallel to the horizontal slat mounting frame (S2a) in the longitudinal direction by the load of the slat oil pipe (1411) It is attached to the mini horizontal flow path slat (S1) so that the other end is fitted to the rotary hole (S2b) is provided to rotate freely. In addition, the mini horizontal rotating rod (S1a) may be further mounted with a leaf spring (not shown) so that the horizontal horizontal slat mounting frame (S2a) and the mini horizontal flow path slat (S1) can be mounted vertically parallel to the longitudinal direction even if the load is not. have.

In addition, the slat oil pipe 1411 is formed by a slat housing 1410 having an upper opening and fitted with a fitting slot 1410a, and each slat housing 1410 includes a light receiving window 14101 for receiving external light. Air tightly inserted to form a hollow inside.

The slat oil pipe 1411 further includes a fitting member 1419 fitted to both open ends of the slat housing 1410 to seal (close) the slat oil pipe.

As shown in (b) of FIG. 4, the fitting member 1419 has a female thread passage formed therein that is coupled to the connecting oil pipe 143 and penetrates the body, or the female thread portion 1412a is provided to a predetermined depth. Is provided is an aluminum or plastic bar screwed to the mini horizontal rotating rod (S1a).

In addition, various sensors 1419d may be installed in place of the connecting oil pipe 143 in the female threaded passage of the fitting member 1419 so as to measure the physical quantity of the provided slitting oil pipe 1411.

The slat oil passage customs 1412 communicates between the slat oil pipes 1411 (A / B) of different mini horizontal flow path slats (S1) through a connecting oil pipe (143), and the connecting oil pipe (143). A threaded portion is formed at one side to be connected and the other side is fitted into a coupling hole 1423b of the fitting member 1419 or is formed as a female screw passage in the fitting member 1418 as shown in FIG. The oil pipe connector 1431 of the pipe 143 may be provided to be directly connected. In the first embodiment of the present invention, the slat oil passage tubular pipe 1412 is formed as a female screw passage by a pair of left and right on the fitting member 1419 so that the oil pipe connector 1431 is directly connected.

Accordingly, a plurality of mini horizontal flow paths each consisting of a slat oil pipe 1411 composed of a light receiving window 14101, a slat housing 1410, and a fitting member 1419, and a slat oil passage customs 1412 formed in the fitting member 1419. The slats (S1) are screwed to the mini horizontal rotating rod (S1a) one by one, and a pair of horizontal slat mounting frame (S2a) is installed in multiple stages below.

The connecting oil pipe 143 may be provided at at least one end of the flexible connecting oil custom pipe 1432 and the connecting oil custom pipe 1432 as shown in FIGS. 5A to 5E. It is included; oil pipe connector (1431). The oil pipe connector 1431 may be an air pit formed by connecting the oil customs pipe 1431 and the connecting portions of many-to-one or one-to-one, and the shape thereof may be a T-type, and the oil customs pipes 1432 for the connection may be made of a flexible material. desirable.

Using such a connecting oil pipe 143, the oil connected to the slat oil passage customs 1412 in the upper multi-stage except for the one of the slat oil passage customs 1412 opened to suck outside air into the lowermost mini horizontal flow path slat S1. The oil pipe connector 1431 of the pipe 143 is screwed to form a flow path, and is connected to the manifold oil pipe 143m at the uppermost mini horizontal flow path slat S1. In the first embodiment of the present invention provided with a manifold oil pipe (143m) in pairs to communicate with the flow paths formed in each of the plurality of vertical frame slats (S2) and connecting oil customs pipe (1432) constituting the manifold oil pipe (143m) ) Is provided with a sufficient length so that it does not interfere with the rotation when rotating from side to side, and is flexible so that the connecting oil customs 1432 are drawn out when it is drawn out, and the connecting oil customs 1432 overlap when overlapping. Prepare using a castle hose.

A partial wire rope fixing member 1435 is formed in the oil pipe connector 1431 to couple the partial wire rope 1434. The partial wire rope fixing member 1435 and the partial wire rope 1434 may replace the wire rope 95.

In addition, the connecting oil pipe 143 may be provided with a plurality of connecting oil custom pipes 1432 per one oil pipe connector (1431) as shown in FIG. It can be divided into the connecting oil customs (1432) through which the connecting power line (703a) passes, and thus the flexible support for collectively supporting the multiple connecting oil customs (1432) and the partial wire ropes (1436) so as not to swing or entangle. It may be configured to further include a support member 1434.

And the manifold oil pipe (143m) is a flexible oil pipe for connection, which is a flexible hose connected through various types of connection connectors (C, C ', C ", as shown in Figure 5 (f), (g) ( 1432. Here, the connection connector (C, C ', C ") may have a variety of forms not shown, including'-'type,' T 'type, elbow type and the like.

In addition, the oil supply pipe 142 is connected to the manifold oil pipe (143m), the manifold oil pipe (143m) the oil is circulated, the oil is not affected by the overlap and withdrawal of the vertical frame slat (S2) A cover 9 is provided in the cover 9 as shown in FIG. 3, and the manifold oil pipe 143m is connected to the slat oil path pipe 1414 of the oil supply pipe 142 having a female threaded path.

In addition, the oil pump 32 is further included in an oil supply port (not shown) of the manifold oil pipe 143m, and is electrically connected to the blind control means 81. In the first embodiment of the present invention, the oil pump At 32, an aspirator is preferable, and at this time, the oil flowing through the flow path uses air.

Accordingly, except for one slat oil passage tubular tube 1412 formed of the lowermost open female thread passage per vertical frame slat S2, the oil supply pipe (143m) is connected through the connecting oil tube 143 and the manifold oil tube 143m. A flow path is formed up to 142.

In addition, the second angle adjustment module 97b and the first angle adjustment module 97a are fixed to each other by the fixing member F.

Therefore, when the vertical gap adjusting string 92b is pulled, the second angle adjusting module 97b moves horizontally in the left or right direction along the second rotation shaft 93b, and is fixed to the second angle adjusting module 97b. Naturally, the first angle adjustment module 97a fixed by the member F also moves together.

In addition, the wire rope 95 drawn downward through the hollow rotating pin 96 may be formed in multiple stages on the horizontal slat mounting frame S2a by passing through an upper end of the horizontal slat mounting frame S2a, and connecting oil. It is bound to the uppermost mini horizontal flow path slat S1 among a set of multiple mini horizontal flow path slats S1 in which a flow path is formed by the pipe 143.

Accordingly, the wire rope 95 is to adjust the inclination angle of the mini horizontal flow path slat (S1) arranged in parallel in multiple stages up and down, the wire rope 95 pulls up the top mini horizontal flow path slat (S1) or The inclination angle of these uppermost mini horizontal flow path slats (S1) is adjusted, and since the upper and lower mini horizontal flow path slats (S1) are connected by the partial wire ropes (1436), at the same time to the lowest mini horizontal flow path slats (S1). Tilt angle is adjusted.

For example, the inclination angle adjusting means may use the inclination angle adjusting means disclosed in Patent No. 48382 as it is, and as another example, a separate adjustment shaft (not shown) is arranged in parallel on each of the horizontal slat mounting frames S2a. Then, a wire rope 95 is provided between the winding drum 94a and the adjustment shaft (not shown), and the ends of the wire rope 95 are wound together, and another wire rope 95 is disposed on the adjustment shaft (not shown). ) Or the partial wire rope (1436) to be wound, and the other end may be configured to support and mount the mini horizontal flow path slat (S1). This is the same as one conventional horizontal blind is formed per horizontal slat mounting frame (S2a). For easy description, it may be understood as a mini horizontal blind disposed on each vertical slat of a conventional vertical blind, and even a mini horizontal blind may have the same basic configuration as a conventional horizontal blind. However, the length of one mini horizontal flow path slat S1 is only the same as the width of a conventional vertical slat, and accordingly, the inclination angle of a set of mini horizontal flow path slats S1 provided in the horizontal slat mounting frame S2a or Any conventional horizontal blind drive means for adjusting the spacing can be applied.

In addition, the two-axis sun tracking drive vertical flow path blind (1) according to the present invention, as shown in Figure 3, the guider 26 for protecting the horizontal slat mounting frame (S2a) of the vertical frame slat (S2) to prevent rocking It may further include.

The guider 26 may include a guide rail 261 having a guide slot 262 having a predetermined opening in the center thereof, and a guide rotating member including a bearing to be inserted into a slot of the guide rail 261 to move horizontally and freely rotate ( 263); and positioned below the vertical frame slat (S2) in parallel with a predetermined interval spaced apart from the cover (9) and is fixed to the wall or floor of the building.

6, the oil control unit 40 circulating oil in the flow path for cooling the solar cell module 703 includes an oil pump 32, an oil flow controller 42, and an operation switch 41. A management remote controller 48 for managing oil for user convenience, a humidity sensor 1422c for measuring humidity to measure a physical quantity in the flow path, a temperature sensor 1422a, and an illumination sensor for measuring the amount of sunlight 1422b, pressure sensor 1422d for measuring oil pressure, various gas sensors or physical quantity measuring sensors such as electronic nose 47, and oil flow controller 42.

In addition, the oil flow controller 42 may include a microcontroller 4101, a remote controller 4105, a flow valve controller 4106, a data storage device 4107, a motor & rocker controller 4109, an alarm lamp, and a buzzer 4108. ), A power supply control unit 4102, an oil pump control unit 4103, and a communication module 4104. The oil pump 32 further includes a flow valve (not shown) controlled by the flow valve control unit 4106. It can be included to control the opening and closing of oil.

The sensors for measuring the physical quantity are mounted inside or outside the mini horizontal flow path slat S1 and are electrically connected to the microcontroller 4101 using a connection power line 703a.

In addition, the humidity sensor 1422c provided on the flow path measures the humidity of the oil flowing in the flow path, and the temperature sensor 1422a installed on the flow path measures the temperature of the oil flowing in the flow path, The illuminance sensor 1422b installed measures the illuminance of the flow path, and the pressure sensor 1422d installed on the flow path measures an oil flow pressure around the flow path, and is installed on the flow path or the oil control unit 40. Various gas sensors or electronic noses 47 measure the surrounding harmful gas concentrations, odor concentrations, oxygen concentrations, and hazardous chemical concentrations and report them to the microcontroller 4101, and the microcontroller 4101 stores the measured values and The oil pump 32 is operated to cool the solar cell module 703 by comparing the temperatures. In addition, the external device or the management remote control unit 48 transmits the information to the external device, the external computer, and the management remote control unit 48 in a predetermined combination through the communication module 4104.

In addition, the alarm lamp and the buzzer 4108 operate when the sun is not exposed to the malfunction of the measured physical quantity, for example, the oil pump 32 controlled by the oil pump controller 4103, or the specific gas concentration is high. It is controlled by the microcontroller 4101 to inform the user when a specific state, such as a large amount, lack of oxygen, or a particular smell is severe, is detected by the logic executed by the microcontroller 4101.

In addition, the data storage device 4107 may store logic to be used when the microcontroller 4101 boots, or may replace logic data by a separate external device (not shown), and the azimuth and elevation angles of the sun may be used. It is provided to store information by time, date, season, yearly data, and to store the measured value by the physical sensor, provided to preserve the record even if the power is turned off, under the control of the microcontroller 4101 USB Data is moved, recorded, or archived by inserting an external medium such as, and transmits and receives data with the USB device through the communication module 4104.

In addition, the data storage device 4107 may be configured to store the GPS information received in real time through the communication module 4104, the latitude, longitude information of the sun transmitted from a remote transmission device or a mobile phone, the microcontroller 4101 To control.

In addition, the management remote control 48 is provided to provide an interface to the user and to communicate with the communication module 4103 and is controlled by the microcontroller 4101.

The motor & rocker control unit 4109 can be configured to control a driving motor which is a power source of the electric blind or a locking means (not shown) for locking a specific rotating body. However, in the present embodiment, the blind control means 81 for controlling the first and second motors 80a and 80b is used, and the motor & rocker control unit 4109 and the locking means (not shown) are not used.

In addition, the oil flow controller 42 may be connected to the MIC 110 through the power control unit 4102, and may be configured to control the MIC 110 (see FIG. 8) passively or actively. However, in this embodiment, it is provided to operate independently.

The two-axis sun tracking drive vertical flow path blind 1 according to the first embodiment of the present invention may be configured to be driven, in which case it may be configured without the oil pump 32 and the oil control unit 40. The oil supply pipe 142 or the manifold oil pipe 143m and a pipe cable (not shown) may be directly sucked into the oil to an external device.

The biaxial sun driven drive vertical channel blind 1 according to the first embodiment of the present invention having such a configuration has the following operating relationship.

First, when the user pulls the vertical gap adjusting string 92c for shading, the second angle adjusting modules 97b connected thereto are extended in the longitudinal direction along the second rotation shaft 93b and unfolded at a predetermined interval. It is the same function as the existing vertical blinds.

At this time, the first angle adjustment module 97a, which is fitted to the first rotation shaft 93a and connected to the second angle adjustment module 97b in a one-to-one correspondence, is also moved together.

In this way, when the plurality of vertical frame slats S2 are unfolded and the gap adjustment is completed, the second rotation shaft 93b is rotated by using a power source, such as a second motor 80b capable of forward and reverse rotation.

Here, the first rotary shaft 93a may be linked to the second rotary shaft 93b by using a power transmission means such as a belt, a chain, a gear, or the like, and a power clutch may be provided by putting a clutch if necessary. It may be configured.

However, in the present invention, the first and second rotary shafts 93a and 93b are provided as a power source for independently driving each of the first and second motors 80a and 80b, and the blind control means 81 are provided to control all of them. Equipped to.

First, since the second rotary shaft 93b is rotated by the driving of the second motor 80b and the plurality of worms 94c are rotated at the same time, the worm gear 94d coupled with the worm 94c is rotated. Rotating pin 96 is rotated so that a plurality of vertical frame slats (S2) as well as a pair of mini horizontal flow path slats (S1) provided in the horizontal slat mounting frame (S2a) is rotated together and the left and right angles are primarily adjusted. This can be performed by combining a light shielding function or a function opposite to the azimuth angle of the sun.

On the other hand, the first rotation shaft (93a) is rotated by the drive of the first motor (80a) to rotate a plurality of the winding drum (94a), the winding drum (94a) wound the wire rope 95, which is a wire The rope 95 is pulled up and down to pull out the uppermost mini horizontal flow path slat S1 of the set of mini horizontal flow path slats S1 to adjust the inclination angle, which results in a pair of multi-step wire ropes 1436 connected to each other. By adjusting the inclination angle of all of the mini horizontal flow path slat (S1) it can be performed as a function of shielding or opposing the altitude angle of the sun.

At the same time, the air flowing inside the mini horizontal flow path slat S1 is heated by solar energy and supplies hot air to the outside through the oil pump 32, and the air flows on the flow path communicated by the suction force. Will flow.

(Second Embodiment)

FIG. 7 is a perspective view of a two-axis solar tracking drive vertical flow path blind mounted with a solar cell module and a power generation unit according to a second embodiment of the present invention, and FIG. 8 is a diagram illustrating a configuration of a power generation unit.

In the second embodiment of the present invention, a two-axis solar driven vertical flow path blind 1 'in which a solar cell module 703 is mounted on a power generating unit and a mini horizontal flow path slat S1 will be described.

For convenience of description, the same configuration as the first embodiment of the present invention is assigned the same member number, and further description thereof is omitted, and has a similar function to the two-axis sun tracking drive vertical channel blind 1 of FIGS. 3 to 6 described in the first embodiment. For the configuration, similar parts are assigned, and only the differences will be described.

In the second embodiment of the present invention, the solar cell module 703 is provided inside the mini horizontal flow path slat S1, but considering the size of the mini horizontal flow path slat S1, the rectangular solar cell module as shown in FIG. 8 ( 703). In addition, the cover 9 is installed with the power generation unit 100 built-in.

At this time, the power generation unit 100 outputs direct current (DC) electricity as shown in (a) of FIG. 8 and maintains a maximum output. An inverter 112 that converts AC power; And it is configured to include a MIC (110, Module Integrated Controller) for controlling them.

And the solar cell module 703 provided in each mini horizontal flow path slat (S1) is electrically connected between the battery connection terminal (7032, see Fig. 1) through a connecting power line (703a), and finally the power generation unit (100) MPPT (111, Maximum Power Point Tracker) is configured to be electrically connected to each of the mini horizontal flow path (S1), to maintain the maximum output power MPPT (111, Maximum Power Point Tracker) circuit Generates a constant direct current through the, and is configured to supply to the external power device by the control operation of the MIC (110) including an inverter 112 for converting the direct current to alternating current.

In addition, as shown in (b) of FIG. 8, it is also possible to use a self-produced power itself, the blind control means 81 measures the power output through the MPPT 111 and the inverter 112, blind power source Used for the first and second motors 80a and 80b and configured to control the first and second motors 81a and 81b which are the blind power sources through a switching operation to supplement the insufficient power in the external power device when the power supply is insufficient. You may.

In this case, the surplus power that is delivered to the first and second motors 80a and 80b, which are the blind power sources, may be configured as a linked power connection system supplied to an external power device by the control operation of the blind control unit 81. It may be.

In addition, as illustrated in FIG. 8B, the storage battery 113 may be further used in the configuration of the power generation unit 100. That is, the electricity produced from the solar cell module 703 may be stored in the storage battery 113 and then used for drawing / overlapping or rotational driving of the blinds and sending the remaining electricity to the external power device. However, in the selection of the first and second motors 80a and 80b used as the blind power source, care should be taken so that alternating currents and direct currents do not occur frequently, and vertical blinds having a double-axis solar tracking function installed indoors ( In the case of 1 '), it is preferable to use an alternating-current motor and not add the storage battery 113, and it is preferable to use the storage battery 113 and use a direct current motor for outdoor use. Since the second embodiment of the present invention does not consume much electricity in the blind power source, it does not need to be complicatedly integrated so that the power generation unit 100 and the blind control means 81 are configured independently, and the battery 113 is installed indoors. It is not equipped.

In addition, since the detailed configuration and operation principle of the MPPT 111 and the inverter 112, the MIC 110, and the storage battery 113 for controlling the same, the detailed description thereof will be omitted.

On the other hand, the solar cell module 703 may be provided in the finished state inside the slat oil pipe 1411, only up to the conductor connecting ribbon (7034, see Fig. 1) connecting the solar cell elements (7031, see Fig. 1). It is better to use the formed solar cell module 703 semi-finished product because it can reduce the load of the mini horizontal flow path slat (S1) and the manufacturing cost is low.

In addition, since the solar cell module 703 semi-finished product is only barely connected to a bare state, it is only a set of connected solar cell elements 7031 (see FIG. 1), and thus a protective film is used up and down for actual use. First, a light incidence transparent film 7035 having electrical insulating properties to protect the semi-finished product of the solar cell module 703 against external shock or chemical corrosion while allowing the sunlight to pass through is well formed. Is placed on. On the other side, the back side reinforcing film 7036 (see FIG. 1) made of metal, plastic, or resin is disposed for the strength of the semi-finished product of the solar cell module 703 or other purposes.

In the first exemplary embodiment of the present invention, there is no light incident transparent film 7035 (see FIG. 1) and a back side reinforcing film 7036 (see FIG. 1) on the semi-finished product of the solar cell module 703. The solar cell device 7031 is sealed using a cell filling film 7033 (see FIG. 1) made of a thermosetting resin material having high transparency, light weight, small volume, and easily damaged by external physical impact. Using the solar cell module 703, the light receiving window 14101 replaces the role of the light incident transparent film 7035 (see FIG. 1), and the slat housing 1410 has a rear reinforcement film 7036 (see FIG. 1). ) Configure it to take over the role.

In addition, the slat housing 1410 is preferably provided with a heating fin, it is preferable that the slat housing 1410 is molded by extrusion in aluminum at the time of manufacture.

The solar cell module 703 can reduce the weight applied to the mini horizontal flow path slat (S1), and even if the transparent material is provided with a light receiving window in multiple layers, the light transmittance is lowered. Therefore, this is improved, and using only one light receiving window 14101 without using the light incidence transparent film 7035 and the back reinforcement film 7036, the finished solar cell module 703 inside the mini horizontal flow path slat (S1) In addition to improving the power generation efficiency than installed in the light incident transparent film 7035 and the rear reinforcement film 7036 to reduce the load, manufacturing cost can be reduced and the thickness of the mini horizontal flow path slat (S1) is also reduced.

In addition, when the solar cell module 703 is sealed inside the mini horizontal flow path slat S1 using the cell filling film 7033 (see FIG. 1), the thermal conductivity is good. It is preferable to attach using an adhesive, because the present invention is the flow of oil flowing inside the mini horizontal flow path slat (S1) by directly contacting (cooling) the application to be cooled, such as the solar cell module (703) heat exchange Therefore, the adhesive quickly transfers heat of the cooling target application device such as the solar cell module 703.

The light receiving window 14101 preferably utilizes an acrylic-based transparent plastic material to further reduce the load of the mini horizontal flow path slat (S1) instead of tempered glass, and to perform an anti-reflective treatment to improve light transmission performance. Preferably, since the plastic is easily deteriorated in the ultraviolet rays of sunlight, it is preferable to have an ultraviolet reflective layer for durability, and a number of materials for manufacturing are well known and detailed description thereof will be omitted.

As described above, as shown in FIG. 7, the mini horizontal flow path slat S1, which is composed of the slat oil pipe 1411, the slat oil passage customs 1412, and the solar cell module 703, is illustrated in FIG. 7. Mounted on the sun tracking drive vertical flow path blind (1 '), a plurality of mini horizontal flow path slats (S1) are provided and installed in a multi-stage group.

In addition, the plurality of mini horizontal flow path slats are connected to each other to form a flow path through the connection oil pipe 143, and each of the solar cell modules 703 inside the mini horizontal flow path slats connects the connection power line 703a. In order to electrically connect in series or in parallel, the plurality of solar cell modules 703 are electrically connected in series by passing the connection power line 703a through the inside of the connecting oil pipe 143.

The biaxial solar driven drive vertical flow path blind 1 'on which the solar cell module 703 of the second embodiment of the present invention is mounted is basically configured as described above, and as in the first embodiment, a mini horizontal flow path slat S1. This is drawn out and unfolded to receive the sunlight, and a detailed description of the operation process will be omitted since it will be referred to the first embodiment, but in this state the two-axis solar driven drive vertical equipped with a solar cell module 703 The operation of the flow path blind 1 'will be described.

That is, the sun rises and the mounted solar cell module 703 starts to generate power. At the same time, the air flowing inside the mini horizontal flow path slat S1 is heated by solar energy and supplies hot air to the outside through the oil pump 32, and the air flows on the flow path communicated by the suction force. The solar cell module 703 is cooled by heat exchange with the solar cell module 703 by external air introduced into the flow path inside the mini horizontal flow path slat S1.

(Third Embodiment)

FIG. 9 is a diagram illustrating a configuration of a highly focused mini horizontal flow path slat according to a third embodiment of the present invention, and FIG. 10 is a view illustrating a light focusing process of a casein grain and a Gregorian main reflection mirror / sub-reflection mirror.

As shown in FIG. 9, the high-concentration biaxial sun tracking drive vertical flow path blind 1 “according to the third embodiment of the present invention includes a linear mirror member 701 serving as a case mirror and a Gregorian main reflecting mirror and a sub reflecting mirror. Further comprising a linear optical module 702 is a mini horizontal flow path slat (S1) (hereinafter referred to as "highly focused mini horizontal flow path slat" only in the third embodiment of the present invention) for highly focused and generated incident sunlight By mounting a plurality, it is possible to reduce the cost by reducing the area of the solar cell module 703 is required, it is possible to increase the power generation efficiency using the crystalline solar cell module 703.

For convenience of description, the same configuration as the first and second embodiments will be denoted by the same reference numerals, and further description thereof will be omitted, and have a similar function to the two-axis sun trailing vertical flow path blinds 1 and 1 'of FIGS. The configuration will be given similar parts and only the differences will be explained.

The highly focused mini horizontal flow path slat S1 ″ is a linear mirror member 701 serving as a casein and Gregorian main reflection mirror and a casee grain and Gregorian portion inside the mini horizontal flow path slat S1 of the first and second embodiments of the present invention. The support member 701a serving as a reflecting mirror and positioned between the linear optical module 702 provided in the light receiving window 14101 and the light receiving window 14101 and the linear mirror member 701 is used to support the light receiving window 14101. As shown in Fig. 9, the method further includes.

The linear mirror member 701 is formed integrally with a plurality of first linear concave mirrors 7002 having a predetermined curvature in consideration of the width and thickness of the highly focused mini horizontal flow path slat S1 ″ and the slat housing 1410. It is inserted into the insertion slot 1410a provided at the bottom of the light receiving window (14101) of the), and the linear light transmitting slit 7002a is formed in the center of the first linear concave mirror 7002. The linear light transmitting slit 7002a may be formed by cutting in the longitudinal direction of a predetermined width, and may be formed of a transparent material to transmit the highly focused light.

The linear optical module 702 is a first linear concave mirror 7002, casee grain or Gregorian main reflective mirror of the linear mirror member 701, as shown in (a) of FIG. Role: see FIG. 10 is focused first, and reflected by the casein negative reflection convex mirror (70031, see a of FIG. 10), the casein secondary reflection convex mirror 70031 is a second linear linear light transmission slit 7002a Re-reflection on.

As shown in FIG. 10B, even when the Gregorian sub-reflection concave mirror 70032 is disposed, the highly concentrated light is reflected to the linear light transmitting slit 7002a to rear-side solar cell module 703. In general, the Gregorian sub-reflection mirror 70032 is behind the focal length of the first linear concave mirror 7002, and the casein sub-reflection mirror 70031 is the first linear concave mirror 7002. Place it in front of the focal length. The condensing of light through these casee or Gregorian primary reflection mirrors and secondary reflection mirrors has been known for a long time in the field of solar condensing, which collects and transmits sunlight through optical telescopes, parabolic antennas for transmitting and receiving radio waves, or optical cables. The detailed description of the principle will be omitted.

At this time, the highly concentrated linear light is a state of collecting the sunlight as a thin, highly integrated focused light, it is possible to generate a high efficiency by irradiating the solar cell module 703.

Preferably, since the highly focused light has a very high temperature, it is preferable to include an infrared reflecting layer in the linear light transmitting slit 7002a. The reason is that the solar cell module 703 is used for filtering out infrared rays because the power generation efficiency drops rapidly when the temperature rises. In addition, the recent generation of solar energy is not only a photoelectric method, but a thermoelectric solar cell has been developed.

More preferably, in consideration of this point, the space of the first linear concave mirror 7002 is formed as the first inner slat oil passage 1421 from the bottom of the light receiving window 14101, and the solar cell module 703 is provided. Divided space into a first inner slat oil passage 1421 and a separate inner slat oil passage, and the heated hot air in the first inner slat oil passage 1421 is separated by infrared rays and supplied to an external device. The solar cell module 703 may be further cooled by cooling oil flowing through the separate slat flow path.

Since it is the same as the second embodiment except for the high concentration mini horizontal flow path slat S1 ″, further detailed description will be omitted below.

In addition, a mini solar heat collecting tube (not shown) may be installed to reduce the size of a conventional solar heat collecting tube (not shown) as the mini horizontal flow path slat S1. At this time, the mini solar collector tube (not shown) may be configured by connecting a vacuum to form a heat exchange the internal heat with the oil flowing through the connecting oil pipe (143). When such a mini solar collector tube (not shown) is installed, the azimuth and altitude angles of the sun are simultaneously traced, thereby increasing the heat collection effect.

And a solar condensing module (not shown) can also be installed, and when the solar condensing module (not shown) is installed, cooling through the oil flowing through the connecting oil pipe 143 has the effect of preventing damage to the optical cable. have.

As such, one embodiment of the present invention described above should not be construed as limiting the technical spirit of the present invention. The scope of protection of the present invention is limited only by the matters described in the claims, and those skilled in the art can change and change the technical idea of the present invention in various forms. Therefore, such improvements and modifications will fall within the protection scope of the present invention, as will be apparent to those skilled in the art.

According to the present invention, it is possible to trace both the azimuth and altitude angles of the sun while performing a blinding or lightening function unique to the blinds, and is easy to mount and cool the solar cells, has high solar energy utilization efficiency, and has a simple structure. Easy and not bulky enough to install in the room, the manufacturing cost is low and can be produced immediately.

1: 2-axis sun driven vertical Euro blinds
1 ': 2-axis solar driven vertical Euro blinds with solar module and power generation unit
1 “: High altitude focusing 2-axis solar driven vertical Euro blinds
9: cover
80a, 80b: first and second motors 81; Blind control means
92a: withdrawal restriction ribbon 92b: vertical spacing 92c: towbar
93a, 93b: first and second rotary shafts
94a: winding drum 94b: wire rope fixing member 94c: worm 94d: worm gear
95: wire rope 96: hollow body rotation pin
97a: first angle adjustment module 97b: second angle adjustment module
S1: Mini horizontal Euro slat S1a: Mini horizontal rotating rod
1410: slat housing 1410a: fitting slot 14101: light receiving window
1411: slat oil pipe 1412: slat oil channel customs 1412a: coupling female threaded portion
1419: fitting member 1419b: coupling hole
1421: first inner slat oil passage
S2: vertical frame slat S2a: horizontal slat mounting frame S2b: turning hole
26: guider
261: guide rail 262: guide slot 263: guide rotating member
143m: manifold oil pipe 142: oil supply pipe
143: connecting oil pipe
1431: oil pipe connector 1432: oil pipe for connection 1434: flexible support member
1435: partial wire rope fixing member 1436: partial wire rope
40: oil control unit
32: oil pump 41: operation switch
1422a: Temperature sensor 1422b: Ambient light sensor 1422c: Humidity sensor
1422d: pressure sensor
42; Oil flow controller
4101: microcontroller 4102: power supply control unit 4103: oil pump control unit
4104: communication module 4105: remote control control unit 4106: flow valve control unit
4107: Data Storage 4108: Alarm Lamp and Buzzer 4109: Motor & Rocker Control
47: electronic nose 48: management remote control
100: power generation unit
110: Module Integrated Controller (MIC) 111: Maximum Power Point Tracker (MPPT)
112: inverter 113: storage battery
701: linear mirror member 702: linear optical module 701a: support member
7002: first linear concave mirror 7002a: linear light transmitting slit
70031: casein grain reflective convex mirror 70032: Gregorian minor reflective concave mirror
703: solar cell module 703a: connection power line
7031: photovoltaic cell element 7032: battery connection terminal 7033: cell filling film
7034: conductor connecting ribbon 7035: light incident transparent membrane 7036: rear reinforcement membrane

Claims (16)

Cover 9 ;,

A pair of first and second rotary shafts 93a and 93b embedded in the cover 9 and having a spline formed on an outer circumferential surface thereof and rotated by a driving source and spaced vertically;

First and second motors 80a and 80b for driving the first and second rotary shafts 93a and 93b;

Blind control means (81) for controlling the first and second motors (80a, 80b);

Worm 94c fitted to the second rotation shaft 93b and slidable, a worm gear 94d coupled to the worm 94c to vertically change power, and a hollow body fixed to the rotation shaft of the worm gear 94d. At least one second angle adjustment module 97b having a rotating pin 96 and horizontally movable horizontally from side to side by a vertical spacing line 92b;

A vertical frame slat fixed to the outer circumferential surface of the hollow rotating pin 96 and rotating left and right (S2);

A pair of mini horizontal flow path slats (S1) provided in the vertical frame slats (S2) in parallel in a plurality of downwards and having oil flow paths formed in at least a portion of each of them;

At least one connecting oil pipe 143 connected between the mini horizontal flow path slats and forming a flow path therebetween;

At least one manifold oil pipe 143m communicating with a plurality of flow paths through the connection oil pipe 143;

It is inserted into the first rotary shaft (93a) is slidable, one-to-one coupling fixed to the upper end of the second angle adjustment module (97b) and penetrates through the inside of the hollow rotating pin (96) downward A first angle adjusting module (97a) having an inclined angle adjusting means drawn out and adjusting an inclination angle of the pair of mini horizontal flow path slats (S1);

When the plurality of hollow body rotating pins 96 are simultaneously rotated by the rotation of the second rotating shaft 93b, the vertical frame slats S2 are rotated to adjust the left and right angles, respectively, the respective vertical frame slats S2. A set of mini horizontal flow path slats (S1) provided at the same time, the azimuth angle with respect to the sun is first adjusted at the same time, a set of mini horizontal flow path slats by the inclination angle adjusting means driven by the first rotary shaft (93a) By simultaneously rotating S1), the altitude angle with respect to the sun is secondarily adjusted so that all the mini horizontal flow path slats S1 face the azimuth and altitude angle of the sun, and the connecting oil pipe 143 and the manifold oil pipe 143m. Through the mini horizontal flow path slat (S1) is interconnected in multiple stages to form a flow path, so that the oil flowing into the mini horizontal flow path slat (S1) or manifold oil pipe (143m) flows in the flow path 2-axis solar driven drive vertical euro blinds, characterized in that. The method according to claim 1;

The vertical frame slat (S2),

The upper end is fixed to the hollow rotating pin 96 and rotates to the left and right, and has a predetermined width in the horizontal direction, the horizontal slat mounting frame (S2a) of the long rectangular frame shape in the vertical direction; and the horizontal slat mounting frame A rotating hole (S2b) formed in multiple stages at predetermined intervals on both sides of the vertical direction (S2a); 2-axis sun driven vertical flow channel blinds, characterized in that consisting of; a plurality of mini horizontal rotating rod (S1a) to be inserted into the rotating hole (S2b) freely rotated. The method according to claim 1;

Tilt angle adjustment means

A winding drum (94a) inserted into and driven by the first rotary shaft (93a) and provided with a wire rope fixing member (94b);
One end is fixed to the winding drum 94a through the wire rope fixing member 94b, and the other end penetrates through the hollow rotating pin 96 without contact and is pulled out downward, thereby pulling the mini horizontal slat S1. Wire ropes (95) bound to rotate up and down; biaxial sun driven drive vertical flow channel blinds, characterized in that consisting of. The method according to claim 1;

Mini horizontal euro slats (S1)

At least one slat oil pipe 1411; and
And at least one slat oil passage tubular tube (1412) coupled to the slat oil tube (1411) and coupled to the connecting oil tube (143). The method according to claim 4;

The slat oil pipe 1411,
A two-axis sun driven drive vertical flow path blind formed by a slat housing 1410 that is hollow inside. The method according to claim 5;
The slat housing 1410,
A two-axis solar trailing vertical flow path blind further comprising a light receiving window 14101 for receiving external light. The method of claim 1,
The oil supply pipe 142 is further connected to the manifold oil pipe (143m),
The oil supply pipe 142 is

A hollow through which the oil moves,
A two-axis solar driven vertical flow channel blind, characterized in that it has a slat oil passage tubular pipe (1412) for connecting the hollow to the connecting oil pipe (143). The method of claim 7;
The oil supply pipe 142 is a two-axis solar tracking drive further characterized in that the oil control unit 40 having at least one oil pump 32 to control the supply and discharge of the oil flowing through (flowing) the flow path Vertical Euro blinds. The method according to claim 1;
The manifold oil pipe (143m) is a two-axis aspect characterized in that the oil control unit 40 is further provided with at least one oil pump 32 to control the supply and discharge of the oil flowing through (flowing) the flow path Autumn driven vertical Euro blinds. The method according to claim 8 or 9;
The oil control unit 40 includes a sensor for measuring solar illuminance, temperature, humidity, and pressure inside the flow path; A communication module for transmitting the detected value of the sensor to a control unit; And a microcontroller for controlling the opening and closing of the valve and driving of the oil pump 32 for oil supply and discharge according to the detected value. The method according to claim 1;
The lower end of the vertical frame slat (S2) further comprises a guider 26,
The guider 26
And a guide rail 261 having a predetermined open guide slot 262 formed therein; a guide rotation member 263 including a bearing to be horizontally moved and freely rotated by being inserted into the slot of the guide rail 261. A two-axis solar driven vertical flow path blind, characterized in that the cover (9) spaced apart at regular intervals in parallel to the bottom of the vertical frame slat (S2) and is fixed to the wall or floor of the building. The method according to claim 4;
The two-axis solar tracking drive vertical flow path blind, characterized in that the solar cell module (703) is further installed inside the mini horizontal flow path slat (S1). The method of claim 12;
Inside the mini horizontal flow path slat (S1) is a linear mirror member 701 is further installed to guide the irradiation of sunlight to the solar cell module 703 through the role of casein / Gregorian main reflection 2 Axis sun driven vertical Euro blinds. The method of claim 12;
Inside the mini horizontal flow path slat S1, a linear optical module 702 further includes a concave or convex mirror surface having a constant curvature corresponding to a casein / gregorian sub-reflecting mirror to the solar cell module 703. Two-axis solar-driven vertical Euro blinds, characterized by maximizing the luminous efficiency to be irradiated. The method according to any one of claims 12 to 14;
A two-axis solar driven drive vertical flow path blind further comprising a power generation unit (100) electrically connected to the solar cell module (703). The method according to claim 1;
The mini horizontal flow path slat (S1) is a two-axis solar driven drive vertical flow channel blind, characterized in that the miniature solar collector tube (not shown) is installed.

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