DE212019000358U1 - Photovoltaic window blind - Google Patents

Abstract

Photovoltaic window blinds, comprising:
a plurality of photovoltaic louvre slats (100) each provided with a slat frame (110); a solar module (140) formed on the lamellar frame (110); and device portions (120) formed on facing opposite sides of the louvre frame (110);
a side cover (200) configured to overlap with the facility portions (120) of the louvre frame (110) while sliding thereon; and
a connector body (300) configured to be attached to mating portions (123) and (230) formed by the overlapping facility portion (120) and side cover (200), and solar modules (140) of the adjacent photovoltaic blinds ( 100) to be electrically connected to each other.

Description

[Technical area]

The present invention relates to a blind for photovoltaic energy generation, in particular a photovoltaic window blind, solar modules of adjacent photovoltaic blind slats of the same being effectively connected to one another via an electrical connector.

[State of the art]

Due to recent environmental pollution and fossil fuel depletion, the development of environmentally friendly alternative energy sources and diversification of future energy sources are emerging as international issues.

With such a background, solar cells utilizing solar energy are attracting attention as a potential alternative energy source in the future, and as solar cells become less expensive, associated world markets are also rapidly increasing in size. According to such a trend, photovoltaic window blinds have been introduced which enable power generation using sunlight during the day.

Here, in the case of a conventional electric connector for photovoltaic window blinds configured to electrically connect solar modules from adjacent photovoltaic window blind slats, the electric connector is attached to terminals of the solar modules by soldering, etc., so that there is a problem that the manufacturing process of solar window blinds is complicated and the manufacturing time is long, resulting in a decrease in manufacturing efficiency.

In order to improve the production efficiency of photovoltaic window blinds, a removable electrical connector that electrically connects solar modules from adjacent photovoltaic blind slats to one another has already been presented.

In the case of such a detachable electrical connector, however, water, moisture, dust, etc. can easily penetrate through gaps between photovoltaic blind slats, which can cause short circuits, corrosion and pollution. In addition, the electrical connector can easily be disconnected from the photovoltaic blind slats while pulling up or tilting photovoltaic blinds, and the disconnected electrical connector may cause a problem that electric shock may occur due to an exposed terminal.

[Prior Art Document]

[Patent document]

Korean Patent No. 10-1364497 (published April 3, 2014)

[Epiphany)

[Technical problem]

Therefore, the present invention has been made in view of the above problems, and it is an object of the present invention to provide a photovoltaic window blind incorporating an electrical connector, the electrical connector being improved in buildability in electrically connecting solar modules provided in photovoltaic blind slats. with each other, prevent discomfort in assembly and use due to unnecessary separation of the electrical connector from the photovoltaic louvre, and prevent electric shock due to exposure of a terminal of the electrical connector by disconnecting the electrical connector from the photovoltaic louvre.

The technical problem to be solved by the present invention need not be limited to the above technical problem, and other technical problems not mentioned herein will be apparent from the following description to those of ordinary skill in the art to which the The present invention belongs, clearly understood.

[Technical solution]

According to one aspect of the present invention, the above and other objects can be achieved by providing a photovoltaic window blind which includes: a plurality of photovoltaic blind slats each provided with a slat frame; a solar module formed in a longitudinal direction on a surface of the fin frame; and facility portions formed on facing opposite sides of the sipe frame;

a side cover configured to be coupled to the furnishing portions of the louvre frame while overlapping therewith to complete the furnishing portions; and

a connector body configured to be coupled to the facility portion overlapping with the side cover, and To connect solar modules of the neighboring photovoltaic blind slats electrically with each other.

More preferably, rail grooves may be formed on facing opposite sides of the facility portions of the lamellar frame, and rail parts may be formed on facing opposite sides of the side cover to fit in and move on the rail grooves.

More preferably, a through hole may be formed at the installation portion of the louvre frame so that a lever line passes through the through hole, and the side cover is provided with a protrusion that is elastically fitted into the through hole and communicates with the through hole and has a hole formed in the Center of the projection is formed.

More preferably, a first fitting portion may be formed in an outside-in cut shape on an edge of the fitting portion, a second fitting portion may be formed in an outside-in cut shape on an edge of the side cover, and, if the fitting portion with the Side cover is coupled in an overlapping state therewith, fitting portions formed of the facing first fitting portion and second fitting portion, be coupled to the connector body.

Particularly preferably, engagement grooves can be formed in each case on opposite sides on an inner surface of the side cover opposite to one another with respect to the first fitting section and engagement projections can be formed on opposite sides of the connector body for elastic attachment to the engagement grooves which are formed on opposite sides of the first fitting section.

Particularly preferably, the connector body can include a housing in which opposite sides of a lower part thereof are provided with wire sections for electrically connecting the solar modules of the adjacent photovoltaic blind slats to one another, and a connection part, one end of which is received within the housing for connection to each of the wire sections and from which another end protrudes from the housing to the outside.

More preferably, the housing of the connector body may include a receiving part configured to be received in the fitting portions and a protrusion configured to be stepped and protruding inward from surfaces of the receiving part and a smaller size than the receiving part so that an outer periphery of the protrusion is in contact with the edge of the fitting portions.

Particularly preferably, a pressed part can protrude from the connecting part of the connector body and make elastic contact with the conductor of the device section.

Particularly preferably, an outer circumference of the projection, which is intended to be in contact with the edge of the fitting portions, is further provided with an airtight holding member.

[Beneficial Effects]

As can be seen from the foregoing, the present invention provides an electrical connector configured to electrically connect solar modules provided in photovoltaic louvre blades to one another. The electrical connector according to the present invention can assemble adjacent photovoltaic louvre blades quickly and easily, thereby being able to improve assembly convenience and decrease assembly labor time, thereby doubling manufacturing efficiency.

In addition, the present invention can prevent unnecessary disconnection of the electrical connectors mounted on the photovoltaic blinds slats, thereby being able to eliminate the inconvenience of a fitter or a user and the occurrence of electric shock, corrosion, electrical leakage, etc. due to a Connection part exposed from a disconnected electrical connector.

Further, the present invention can prevent water, moisture, or dust from entering through connection portions between photovoltaic louvre blades and electrical connectors because the connection portions are in close contact, thereby being able to increase customer satisfaction through product performance improvement and improvement in product effectiveness.

Figure list

• 1 Figure 12 illustrates a front view of a photovoltaic window blind according to an embodiment of the present invention.
• 2 Figure 12 illustrates a perspective view of adjacent photovoltaic blind slats of a photovoltaic window blind in accordance with an embodiment of the present invention.
• 3rd FIG. 13 illustrates a perspective view of an electrical connector coupled to a photovoltaic louvre in accordance with an embodiment of the present invention.
• 4th FIG. 13 is an enlarged perspective view showing the major components of 'A' of FIG 3rd represents.
• 5 Fig. 14 is an enlarged, exploded perspective view illustrating a state before coupling a photovoltaic louvre to an electrical connector according to an embodiment of the present invention.
• 6th FIG. 13 is an enlarged, exploded perspective view of major components in a state before coupling a fitting portion of a photovoltaic louvre, a side cover, and an electrical connector according to an embodiment of the present invention.
• 7th Fig. 13 is an enlarged, exploded perspective view in a different direction of main components in a state before coupling a fitting portion of a photovoltaic louvre, a side cover, and an electrical connector according to an embodiment of the present invention.
• 8th Fig. 13 is an enlarged sectional view of major components of a coupled device portion of a photovoltaic louvre, a side cover, and an electrical connector according to an embodiment of the present invention.
• 9 Figure 12 illustrates a perspective view of components of an electrical connector in accordance with an embodiment of the present invention.
• 10 Figure 12 illustrates a perspective view of components of an electrical connector in accordance with another embodiment of the present invention.

[Best Practice]

In the following, the structure and functions according to a preferred embodiment of the present invention will be described in more detail with reference to the accompanying drawings.

These descriptions are provided so that those skilled in the art can easily implement the present invention, and are not intended to be limiting in the scope and spirit of the present disclosure.

In addition, when adding reference numbers to components of each drawing, it should be noted that the same reference numbers are assigned to the same elements as much as possible, even if they are shown in different drawings. The terms specifically defined with respect to the structure and functions of the present invention may be changed according to intent or conventional methods used by customers, operators and users. Accordingly, definitions of the terms should be understood on the basis of the entire description of the present specification.

First, the configuration of a photovoltaic window blind according to the present invention can be broadly divided into photovoltaic blinds, a side cover coupled to facility portions of each of the photovoltaic blinds, and an electrical connector connected to each of the facility sections to which the side cover has been coupled to electrically connect solar modules from neighboring photovoltaic blind slats to one another.

The components of the present invention are described in detail below with reference to exemplary drawings.

First of all, as in 1 and 2 shown, a photovoltaic window blind 1 from several photovoltaic blind slats 100 formed, that is, the photovoltaic blind slats 100 are unit elements that make up the photovoltaic window blind 1 form. The multiple photovoltaic blinds 100 can be set up in such a way that they are supported by a lifting line 410 and tilt lines 420 are connected to each other and by a mounting frame 400 are suspended, which is set up on a window system or window frame.

On the mounting frame 400 may include a lifting operating line (not shown in the drawing) for raising and lowering the lifting line 410 and a tilting operation tool (not shown in the drawing) for adjusting the tilting lines 420 to adjust the angle of the photovoltaic blind slats 100 be connected.

The above lifting operation line is used to rotate a drum (not shown in the drawing) attached to one end of the lifting line 410 is attached, in the mounting frame 400 . When the lifting line 410 is wound up by rotation of the drum, a lowermost photovoltaic blind slat is pulled up, and accordingly several photovoltaic blind slats that are are located above the lowest photovoltaic blind slat, sequentially folded in and raised.

When the tilting tool pushes the drum in the mounting frame 400 Turning clockwise or counterclockwise about a half turn becomes one side of the tilt ropes 420 , which are formed in a ladder shape, pulled up according to the operation and the angle of the side of the photovoltaic blind slats 100 running through the tilting lines 420 is stored and attached to it, set.

The lift operating line and the tilt operating tool are components common to the photovoltaic window blind 1 applied and used with it. The lifting operation line and the tilt operation tool are not limited to the above-described manner and can be modified and applied in various ways as long as the photovoltaic blinds are used 100 can be easily raised or lowered, or their angle can be easily adjusted.

As in 3rd shown, each of the photovoltaic blinds can 100 a bar-shaped lamellar frame 110 with a predetermined length and a solar panel 140 included that is on a surface of the louvre frame 110 is set up as a specific embodiment.

The louvre frame 110 can be made of a synthetic resin or aluminum material. In view of durability, buildability, etc., an aluminum material is preferred. When the louvre frame 110 is made of an aluminum material, is a side surface of the sipe frame 110 on which the solar panel 140 should be stored, preferably insulated by electroplating, film application, etc.

Several of the solar panels 140 are along a longitudinal direction of the sipe frame 110 set up for electrical connection with each other. Solar cells are on a front face of each of the solar modules 140 provided for forming a light-collecting surface, and (+) (-) electrodes are rear-contacting on a rear surface of the solar module 140 educated.

Because the solar cells in a vertical direction with respect to a longitudinal direction of the solar module 140 are arranged, electricity is generated in the solar module 140 does not affect, even if shadows on an upper or lower portion, in a horizontal direction, of the light collecting surface due to adjacent photovoltaic louvre blades 100 falls.

There long sides of strip unit cells of the solar module 140 array-shaped in a width direction of the photovoltaic blind slats 100 are arranged, the entirety of each solar cell is not in a shadowed state. The delivery of each solar module 140 may be decreased according to a ratio of a shaded area, but the total output is not significantly decreased since none of the solar cells among the series solar cells is completely shaded.

As in 6th shown are facility sections 120 having a predetermined size in a longitudinal direction at both ends of the lamellar frame 110 provided, and a side cover 200 is to the facility sections 120 coupled. The furnishing sections 120 are from opposite ends of the louvre frame 110 made to run or can be mounted such that they are at opposite ends of the lamellar frame 110 attachable / detachable from it.

An interior surface of each of the facility sections 120 is with a ladder 130 provided with an electrode 141 of the solar module 140 connected is. As in 8th shown is the head 130 with a connecting part 330 that is contained in each of the connector bodies described below 300 is included, electrically connected when the connector body 300 within the facility section 120 is added, so that the respective solar modules 140 that are in the neighboring photovoltaic blind slats 100 are contained by the connector body 300 be supplied with energy.

As in 6th shown is the side cover 200 at the facility sections 120 of the above louvre frame 110 furnished, creating inner surfaces of the furnishing sections 120 are completed, exposing the electrode 141 of the solar module 140 or the head 130 on the interior surfaces of the furnishing section 120 are arranged, is blocked and the connector body 300 is attached, which is in one state in the installation section 120 is fitted in which he is at the furnishings section 120 is coupled.

The side cover 200 can be accessed in a number of ways on the facility sections 120 be set up such as non-positively or fastened using a fastener. In one embodiment of the present invention, the side cover is 120 configured to slide into the facility sections 120 to be fitted in and coupled to it.

That is, facing opposite front ends of the device sections 120 for forming rail grooves 121 are bent inwards and rail parts 210 at facing opposite front ends of the side cover 200 are formed in the rail grooves 121 intended to be fitted and coupled to while sliding. If necessary, rail grooves can be made on opposite front ends of the side cover 200 may be formed and rail members at opposite front ends of the device sections 120 be trained.

As in 1 shown, the connector body serves 300 for connecting the solar modules 140 the neighboring photovoltaic blind slats 100 with each other so that the solar panels 140 each on the multiple photovoltaic blind slats 100 are set up, are connected in parallel. This is done through a process of fitting the connector body 300 into the setup section 120 of the louvre frame 110 achieved on the side cover 200 was coupled.

When fitting the connector body 300 into the setup section 120 to which the side cover 200 has been coupled, it is necessary to prevent the connector body 300 unnecessarily from the facility section 120 is separated. A first pass section can be used for this purpose, for example 123 by trimming the facility section 120 inwardly by a predetermined amount from a longitudinally extending outer edge of the device section 120 are formed and also a second fitting portion 230 by trimming the side cover 200 inward by a predetermined amount from a longitudinally extending outer edge of the side cover 200 be trained as in 6th and 7th shown.

When the side cover 200 correctly at the facility sections 120 is arranged to overlap them, are the first fitting portion 123 and the second pass section 230 facing each other and coincide with each other, creating a fitting section 123 and 230 train as in 5 shown. The connector body 300 is in the pass section 123 and 230 fitted.

As in 9 (a) and 9 (b) shown, the connector body 300 a housing 320 that with wire sections 340 which are formed on opposite sides of a lower end thereof, and the connecting part 330 contain. One end of the connecting part 330 is inside the case 320 added to with each of the wire sections 340 to be electrically connected, and another end, opposite to one end, of the connecting part 330 stands through an upper part of the case 320 to the outside.

As in 8th shown is the connector 330 of the connector body 300 electrical with one side of the conductor 130 , which is in the setup section 120 is provided in the process of fitting the connector body 300 into the setup section 120 connected to the side cover 200 was set up and assembled with it, making it electrically connected to the solar panel 140 that is connected to another end of the conductor 130 is connected via an electrode.

The connector body 300 are each set up on the plurality of photovoltaic louvre blades to be connected to each other. In particular, as in 2 shown, a section of wire 340 the wire sections 340 that are located on lower opposite sides of the case 320 of the connector body 300 are connected to a connecting part of another connector body 300a which is connected to a solar module 140a contained in a photovoltaic louvre 100a, the one side of the photovoltaic louvre 100 is adjacent, and the other wire section 340 the wire sections 340 is connected to a connecting part of another connector body 300b which is connected to a solar module 140b included in a photovoltaic louvre 100b that is the other side of the photovoltaic louvre 100 is adjacent.

Accordingly, if the connector body 300 , 300a and 300b each with the multiple photovoltaic blind slats 100 , 10a and 100b are connected and the connector bodies 300 , 300a and 300b through the wire sections 340 are connected to each other, the solar modules 140 , 140a and 140b, which are respectively in the photovoltaic blind slats 100 , 100a and 100b are included via the respective connector bodies 300 , 300a and 300b connected to each other.

The connector body 300 should be rigid in the pass sections 123 and 230 be fitted by coupling the side cover 200 with the facility sections 120 and formed by the first fitting portion 123 and the second pass section 230 are formed. There are also engagement projections 210 with elasticity increasing toward the top thereof, symmetrically formed so as to be mutually opposite on opposite sides of an upper part of the housing 320 of the connector 300 are facing, and engaging grooves 240 are so on both sides within the side cover 200 formed that they are mutually related to the second fitting portion 230 faced and recessed to a predetermined depth while having a shape corresponding to the engaging protrusions 310 corresponds to, as in 7th shown.

As in 7th shown is a set of surfaces of the engaging grooves 240 in one open state before going to the setup section 120 are coupled, and the open surfaces of the engagement grooves 240 are closed while being an inner surface of the furnishing section 120 contact, via a process, in which they are sent to the facility section 120 be coupled. In addition, if the housing 320 of the connector body 300 in the pass sections 123 and 230 is used, the connecting part 330 from an upper part of the case 320 protrudes within the facility section 120 used as in 8th shown so that the connecting part 330 electrically with the conductor 130 connected to the electrode 141 of the solar module 140 is connected, and the engaging protrusions 310 that are on top opposite sides of the case 320 are formed resiliently with the engaging grooves 240 the side cover 200 engaged and secured thereto by the fitting section 120 are closed.

As in 9 shown is a pressed part 331 that to the head 130 protrudes out at a front end of the connecting part 330 of the connector body 300 formed and enables the connecting part 330 in close contact with the leader 130 stands while exerting a certain pressure thereon, whereby it is able to unnecessarily short-circuit between the connecting part 330 and the head 130 to prevent.

It should when the side cover 200 at the facility sections 120 is arranged to overlap therewith, the first fitting portion 123 of the setup section 120 with the second pass section 230 the side cover 200 match to the pass sections 123 and 230 to train exactly that from the first fitting section 123 and the second pass section 230 are formed. When the pass sections 123 and 230 are accurately formed, the connector body 300 accurately to the pass sections 123 and 230 be coupled.

It should, for the accurate formation of the pass sections 123 and 230 , the side cover 200 attached to the furnishing sections 120 is stopped while sliding thereon and at an accurate position of the installation sections 120 be attached after sliding on it. In one embodiment is a through hole 122 at the facility section 120 formed so that the lifting line 410 through the alternately coupled side cover 200 and setup section 120 runs, and a hole 221 , the one with the through hole 122 of the setup section 120 is on the side cover 200 trained as in 7th shown. Here is an inner circumference of the hole 221 with a head start 220 provided which is a predetermined length to the inner surface of the side cover 200 protrudes. The appearance of the ledge 220 can change the appearance of the through hole 122 of the setup section 120 be designed accordingly.

Accordingly, when the side cover moves 200 at the facility section 120 established while sliding on the ledge 220 the side cover 200 along the interior surface of the facility section 120 , and at this point should be the lead 220 a protrusion height for pressing the inner surface of the device portion 120 with a minimal external force. In addition, if the lead 220 with the through hole 122 of the setup section 120 matches while the side cover is on 200 moved, the outer periphery of the protrusion 220 in close contact with the inner periphery of the through hole 122 of the setup section 120 and is fitted into it, as in 8th shown, causing the movement of the side cover 200 stopped and an accurate position of the side cover 200 at the facility section 120 can be set.

In addition, if the facility section 120 so accurate with the side cover 200 is coupled, the pass sections 123 and 230 that came from the first pass section 123 of the setup section 120 and the second pass section 230 the side cover 200 are also formed accurately. Accordingly, the connector body 300 accurately to the pass sections 123 and 230 be coupled.

It is when an upper part of the case 320 of the connector body 300 in the pass sections 123 and 230 is fitted, if necessary, the upper part of the housing 320 to be configured in such a way that it does not enter the fitting sections at a greater depth than necessary 123 and 230 is fitted. This can be done in the upper part of the housing 320 a receiving part 321 that is in the pass sections 123 and 230 should be included, and a head start 322 included, the inward in the central direction on front and rear surfaces of the receiving part 321 is arranged to protrude therefrom in stages, as in FIG 9 (b) shown. Accordingly, if an upper part of the housing 320 of the connector body 300 in the pass sections 123 and 230 is fitted, the receiving part 321 in the pass sections 123 and 230 recorded and the lead 322 in edges of the fitting sections 123 and 230 detected.

Here is the shape of the outer circumference of the protrusion 322 configured to match the edge shape of the fitting portions 123 and 230 corresponds so that the outer periphery of the projection 322 in close contact with the edge of the mating sections 123 and 230 stands as in 4th shown. Accordingly, it is possible to prevent water, moisture and dust from passing through a connecting part between the fitting portions 123 and 230 and the connector body 300 penetration.

When the outer periphery of the protrusion 322 that is the edge of the fitting sections 123 and 230 should contact, with an airtight retaining member 332 such as rubber or silicone is provided with elasticity, as in FIG 10 shown, ie the outer periphery of the projection 322 in close contact with the edge of the fitting sections 123 and 230 via the airtight retaining member 322 which is interposed, airtightness can be achieved between the outer periphery of the protrusion 322 and the edge of the fitting sections 123 and 230 more stable can be maintained, and, since the housing 320 that is about the airtight retaining member 332 with elasticity in the fitting sections 123 and 230 is fitted, experiences a repulsive force in a direction opposite to the fitting direction, the engaging projections experience 310 with the engaging grooves 240 the side cover 200 are engaged, also a repulsive force in a direction opposite to the direction in which the connector body 300 in the pass sections 123 and 230 is fitted so that the front ends of the engaging protrusions 310 corresponding inner surfaces of the engagement groove 240 press. Accordingly, the engagement protrusions 310 firmly attached to the engaging grooves without moving 240 be attached.

Here, the present invention is configured such that the connector body 300 on each of the photovoltaic blinds 100 is arranged not to be unnecessarily separated, the connector body 300 however from the pass sections 123 and 230 can be disconnected for reasons such as maintenance and repair of the photovoltaic window blind. Although not shown in the drawings, there is a pin hole on each outer surface of the facility section 120 formed to which the side cover 200 was coupled to the internal engagement grooves 240 to penetrate. Accordingly, to disconnect the connector body 300 from the pass sections 123 and 230 a pin inserted into the pin hole to make the engagement protrusions 310 of the connector body 300 that are in the engaging grooves 240 the side cover 200 are captured to move to one side.

In addition, in another embodiment not shown in the drawings, engaging projections for sliding in opposite directions may be provided on opposite sides of an upper part of the housing 320 of the connector body 300 may be configured, springs may be arranged on the sliding path so that the respective engagement projections may maintain a state in which they are elastically moved to the outside due to the elasticity of the springs, an elongated hole on a front surface of the housing 320 may be formed and a lever on a lower side of the engagement projections for protruding from the outside of the elongated hole formed in the front of the housing 320 formed while moving in a vertical direction toward the front of the housing 320 runs. The connector body 300 can from the pass sections 123 and 230 be separated by moving the engaging projections inward through the operation of the lever.

The following describes a process of connecting the solar modules provided in the plurality of louvre photovoltaic louvers according to the present invention to each other through the electrical connector installed in the louvre photovoltaic louvers.

To the side cover 200 at the facility section 120 to set up the outside of the louvre frame 110 of the photovoltaic blinds 100 is arranged, slide and move the upper and lower rail parts 121 of the setup section 120 initially in an overlapping state so that the upper and lower rail parts 210 in the upper and lower rail grooves 121 be fitted.

By moving the side cover 200 becomes the lead 220 the side cover 200 into the through hole 122 of the setup section 120 fitted, and the side cover 200 will be at a specific position on the facility section 120 about the engagement between the ledge 220 and the through hole 122 attached.

When the first pass section 123 of the setup section 120 with the second pass section 230 the side cover 200 for the accurate formation of the fitting sections 123 and 230 due to accurate coupling between the side cover 200 and the setup section 120 matches, the connector body 300 in the pass sections 123 and 230 fitted.

When the connector body 300 in the pass sections 123 and 230 is fitted, the connecting part becomes 330 that is from the top of the case 320 of the connector body 300 protrudes with the head 130 connected on an inner surface of the facility portion 120 arranged and with the solar module 140 and the electrode 141 is connected, whereby the solar modules of the adjacent photovoltaic blind slats are electrically connected to each other via wire sections.

In addition, when the engagement protrusions 310 that are on opposite sides of the case 320 of the connector body 300 are provided in the engagement grooves 240 the side cover 200 are detected and attached thereto and the outer periphery of the protrusion 322 located on the upper part of the case 320 of the connector body 300 is in close contact with the edge of the fitting sections 123 and 230 is detected, the connection section between the photovoltaic blind slats 100 and the connector body 300 without separating the connector body 300 from the photovoltaic blinds 100 Maintain airtightness.

While the embodiments of the present invention have been described in the detailed description, those skilled in the art will recognize that numerous modifications and changes can be made in the present invention without departing from the spirit and essential characteristics of the present invention. Therefore, it is to be understood that there is no intention to limit the disclosure to the disclosed embodiments, but instead the disclosure is intended to cover all modifications, equivalents, and alternatives that come within the spirit and scope of the disclosure as defined by the appended claims.

List of reference symbols

1:

photovoltaic window blind

100:

photovoltaic blind slat

110:

Louvre frame

120:

Setup section

121:

Rail groove

122:

Through hole

123:

first pass section

130:

ladder

140:

Solar module

141:

electrode

200:

Side cover

210:

Rail part

220:

head Start

221:

hole

230:

second pass section

240:

Engagement groove

123, 230:

Pass section

300:

Connector body

310:

Engagement lead

320:

casing

321:

Receiving part

322:

head Start

330:

Connecting part

331:

Pressed part

332:

airtight retaining member

340:

Wire section

400:

Mounting frame

410:

Lifting line

420:

Tilting leash

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• KR 101364497 [0007]

Claims (9)

Photovoltaic window blinds, comprising: a plurality of photovoltaic louvre slats (100) each provided with a slat frame (110); a solar module (140) formed on the lamellar frame (110); and facility portions (120) formed on facing opposite sides of the louvre frame (110); a side cover (200) configured to overlap with the facility portions (120) of the louvre frame (110) while sliding thereon; and a connector body (300) configured to be attached to mating portions (123) and (230) formed by the overlapping facility portion (120) and side cover (200), and solar modules (140) of the adjacent photovoltaic blinds ( 100) to be electrically connected to each other. Photovoltaic window blind after Claim 1 wherein rail grooves (121) are formed on facing opposite sides of the facility portions (120) of the lamellar frame (110), and rail parts (210) are formed on facing opposite sides of the side cover (200) for fitting in and moving on the rail grooves (121) . Photovoltaic window blind after Claim 1 wherein a through hole (122) is formed at the facility portion (120) of the louvre frame (110) such that a lever line (410) passes through the through hole (122), and wherein the side cover (200) having a protrusion (220) having a hole (221) which is elastically fitted in the through hole (122) and communicates with the through hole (122). Photovoltaic window blind after Claim 1 wherein the fitting portions (123) and (230) are formed by mating and matching a first fitting portion (123) formed by trimming an outer periphery inward in a longitudinal direction of the fitting portion (120) with a second fitting portion (230), which is formed by trimming an outer periphery in a longitudinal direction of the side cover (200) inward. Photovoltaic window blind after Claim 4 wherein engaging grooves (240) are formed on opposite sides on an inner surface of the side cover (200) so as to oppose each other with respect to the first fitting portion (123), and wherein engaging protrusions (310) are formed on opposite sides of the connector body (300), to be elastically attached to the engaging grooves (240). Photovoltaic window blind after Claim 4 the connector body (300) comprising: a housing (320), opposite sides of a lower part thereof being provided with wire sections (340) for electrically connecting the solar modules (140) of the adjacent photovoltaic blinds (100) together; and a connector (330) one end of which is received in an inner lower side of the housing (320) to be electrically connected to each of the wire portions (340) and another end of which is received by an upper part of the housing (320) ) protrudes. Photovoltaic window blind after Claim 6 wherein the housing (320) of the connector body (300) comprises: a receiving part (321) configured to fit into the fitting portions (123) and (230) in a process of fitting an upper part of the connector body (300) into the Fitting portions (123) and (230) to be fitted; and a protrusion (322) formed to be stepped inward from front and rear surfaces of the receiving part (321) to be caught in the edge of the fitting portions (123) and (230) and to be in contact therewith . Photovoltaic window blind after Claim 6 wherein the connecting part (330) of the connector body (300) comprises a pressing part (331). Photovoltaic window blind after Claim 7 wherein an outer periphery of the protrusion (322) is intended to be in contact with the edge of the fitting portions (123) and (230) and is further provided with an airtight holding member (332).

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