KR20110030248A - Blind slat having two fluid path for tem(thermoelectric element module) or solar cell hybrid tem embedded - Google Patents

Abstract

PURPOSE: A blind slat having two fluid paths for a TEM(Thermoelectric Element Module) is provided to supply high-temperature air in a rainy day or cooled air for dehumidification through embedded TEMs and solar cell modules and two fluid paths. CONSTITUTION: A blind slat comprises blind slat housings(7), a fitting member(1419), and a protective cap(1420). The blind slat housings, which have the same or different sizes, are formed with two inner slat fluid paths and connected through intermediate fine tubes(1415) of metal material.

Description

Thermoelectric flow slat {Blind slat having two Fluid path for thermoelectric element module (TEM) or solar cell hybrid TEM embedded}

The present invention relates to a blind slat. More particularly, the present invention relates to a thermoelectric flow path slat provided with a flow path through which flow oil such as air flows inside the blind slat, and including a thermoelectric module and a solar cell module inside the slat.

Conventional blinds have a large potential for solar energy utilization in terms of light receiving area and time for sunlight in individual generations of apartments, such as apartments, but do not allow overlapping and withdrawal of slats unlike fixed windows or building walls. It is very flexible to be applied to various purposes because it has the possibility of random release of solar light receiving area or time through it, the application of various solar energy applications, the low cost economical and the removable convenience, the structure solar driving possibility. In addition, as the conventional simple solar shade screen role, it is necessary to combine various application technologies.

For example, the blind can be applied to the technology applied to the dehumidifier, the thermoelectric module is arranged on the blind slat can be applied to the dehumidification of the room, the solar cell module can be mounted to generate power.

First, referring to FIG. 1, since the electromotive force generated by the photovoltaic effect in the unit photovoltaic device 7031 is very small in practical use, a plurality of photovoltaic cell devices 7031 are connected. A predetermined electromotive force is obtained, and an electromotive force of approximately 0.4 to 0.5 V is generated per one photovoltaic cell element 7031, and the generated current increases in proportion to the intensity of the solar radiation and the area of the total photovoltaic cell element 7031.

That is, the connection set of the photovoltaic cell elements 7031 is also referred to as a solar cell module 703, and is called a solar cell in general terms including the solar cell module 703.

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 The elements 7031 are generally connected in series with the conductor connecting ribbon 7044 to obtain as much power as necessary.

At this time, to connect the photovoltaic cell elements 7031, an inter connector ribbon 7044 is used, and the material of the conductor connection ribbon 7044 is Sn + Pb + Ag, Sn + Ag, Sn. + Ag + Cu, and the negative paste electrode wire having a negative polarity of 1-3 mm formed on the front side of the photovoltaic cell element 7031 when formed in series is formed on the back side of the other photovoltaic cell element 7031. The silver paste electrode wire having a positive polarity of 5 mm is connected through a conductor connecting ribbon 7042 and electrically connected to the solar cell connecting terminal 6702. Such a state is called a semi-finished solar cell module.

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 solar cell module is an electrically connected Bare state, which is only a set of connected solar cell elements 7031, and thus uses a protective film up and down for actual use. In order to protect the semi-finished product of the solar cell module against chemical corrosion, 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 or for other purposes.

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

The light incidence transparent film 7035 is basically made of a transparent film so that sunlight reaches the photovoltaic cell element 7031, 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, and antireflection for maximizing light incidence in the photovoltaic cell element 7031 according to the application of using each photovoltaic cell element 7031. And the like are applied.

In addition, the rear reinforcement film 7036 is excluded only the transparency requirements for the light incidence of the light incidence transparent film 7035 for the photoelectric effect, the reinforcement function as a basic premise, also needs to be considered according to various applications When installed on glass windows, various technologies such as transparency for securing a line of sight, weight for an installation place, heat conductive material for heat sinks, and insulation are applied.

Typically, two sheets of tempered glass are generally used as the light incidence transparent film 7035 and the rear reinforcement film 7036 used in the solar cell module 703 that are installed outdoors, but according to the application, a plastic plate or an insulating layer is used. Optionally provided metal plate.

For example, in the case of weight-critical applications, bags, mobile phones, portable chargers, etc., glass is adopted due to the load, and the light incident transparent film 7035 reduces the reflection of sunlight when irradiated with sunlight and reduces the light. In order to increase the 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 incidence 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 a variety of solar cell module 703 in consideration of the manufacturing cost and efficiency appropriate to those skilled in the art It may be manufactured and further detailed description thereof will be omitted below.

On the other hand, as a background technology applicable to the blind will be described with reference to Figures 2 to 4 with respect to the conventional thermoelectric application technology.

In general, the thermoelectric chip 7071 is used for cooling or heating equipment by the Peltier Effect. Among these applications, a cooling device, particularly a cooling device widely used in a high-efficiency cooler using a conventional refrigerant condensation or evaporation principle, is used. The use of a cooler using a thermoelectric chip 7071 to improve various problems arising from the structure has recently increased.

Such a trend is possible due to the small size and the high efficiency, so that the conventional cooling technology used for the cooling device of the enclosure during application of the thermoelectric chip 7071 will be briefly described as follows.

As shown in FIG. 2, the conventional refrigerator cooler 600 has both side ends of the thermoelectric chip 7061 coupled through the enclosure 601, respectively, inside and outside the enclosure 601. And a housing heat absorbing portion 602 and a housing heat generating portion 603 which are provided at both side ends of the thermoelectric element chip 7061, respectively. The housing heat absorbing unit 602 is composed of an enclosure cold sink 6021 attached to one side of the thermoelectric chip 7061 and an enclosure cooling fan 6022 located in front of the enclosure cold sink 6061, The housing heat generating unit 603 includes a housing heat sink 6031 attached to the other side of the thermoelectric chip 7091 and a housing heat dissipation fan 6032 provided at a predetermined distance from the housing heat sink 6031. .

Looking at the cooling action by the conventional enclosure cooler 600 as illustrated briefly, the high temperature inside the air is heat exchanged by the contact with the housing heat absorbing portion 602 is changed to low temperature air, The internal temperature can always be kept constant. On the other hand, the outside air at room temperature is exchanged by the contact with the housing heat generating unit 603 is changed to hot air. In this case, the greater the amount of heat discharged through the enclosure heat generating unit 603 to the outside, the greater the cooling performance of the enclosure heat absorbing unit 602, and thus the enclosure heat dissipation fan 6032 is typically provided in plural.

In addition to the enclosure cooler 600 briefly introduced above, there are various cooler structures to simultaneously induce dehumidification, cooling, heating, etc. in the same enclosure by inducing a flow of air in a specific direction. Detailed description thereof will be omitted.

However, FIG. 3 is a thermoelectric chip substrate module 7060 configured as a module by mounting the thermoelectric chip 7071 used in a cooler, and a plurality of thermoelectric chip circuit boards 7003 having a circuit pattern formed therein. It will be described later.

The thermoelectric chip substrate module 7060 includes a thermoelectric chip 7071 in which thermoelectric heating and thermoelectric cooling are respectively performed on surfaces facing each other when power is applied, and a thermoelectric chip circuit board 7037 mounted by the thermoelectric chip 7071. It is composed of

At this time, the plurality of thermoelectric chip 7071 is made of a thermoelectric element 70706 as a chip, and penetrates the thermoelectric chip circuit board 7003 through a thermoelectric chip circuit board 7063 having a pattern for electrically connecting therewith. On both sides of the thermoelectric chip 7071, the sides of the thermoelectric chip circuit board 7071 are provided so as to protrude outside the thermoelectric chip circuit board 7063, and are connected to each other in series or in parallel, and the thermoelectric chip substrate module 7060 is connected to an external connector. The thermoelectric chip substrate module 7060 is provided to be connected to the thermoelectric connection terminal 7082 of the thermoelectric chip circuit board 7063 to be connected to the receptor or another thermoelectric chip substrate module 7060. Although not shown, the housing cold sink 6021 and the housing heat sink 6031 attached to one side of the thermoelectric chip 7091 described above may be further provided on both sides of the thermoelectric chip substrate module 7060, respectively. Each is provided for use in practical applications.

The thermoelectric element 70710 may include a plurality of Ns provided between a pair of ceramic substrates 70613 and 70614 spaced by a predetermined distance and the pair of ceramic substrates 70613 and 70614 and arranged in a predetermined pattern. Upper and lower conductive electrodes 70612 and 70616 electrically connecting the type and P-type thermoconductors 70701, the plurality of N-type and P-type thermoconductors 70706, and the conductive electrodes 70706 and 70706. And an electrode terminal 70141 for joining to end portions of the plurality of N-type and P-type thermoelectric semiconductors 70706, respectively.

In this case, a filling layer (not shown) such as a silicon layer is provided in the spaced space between the pair of ceramic substrates 70613 and 70614 to prevent the components from being spaced apart from each other by external force, and therein, moisture To prevent it from entering.

Herein, the structure or principle of the thermoelectric element 70010 including the ceramic substrates 70706 and 70714, the plurality of N-type and P-type thermoelectric semiconductors 70715, the conductive electrodes 70812, 70616, and the silicon layer are conventionally used. Since it has been previously filed, a detailed description thereof will be omitted.

In addition, the above-mentioned thermoelectric chip 7071 and the thermoelectric chip substrate module 7060 have also been previously applied in a number of prior arts, and the present invention only utilizes the thermoelectric chip substrate module 7060, and thus, further details thereof will be described. The description will be omitted.

However, instead of manufacturing the thermoelectric element 70610 as a single chip, a plurality of thermoelectric elements 70610 may be configured as the thermoelectric module 70706 as shown in FIG. 4, as in the general solar cell module 703. A plurality of thermoelectric elements 70010 may be collectively wired using the conductor connecting ribbon 7004, integrated using ceramic substrates 70706 and 70714, and silicon filled films (not shown).

The thermoelectric module 70706 functions in the same way as the thermoelectric chip substrate module 7060, and as for the use thereof, the present invention uses only the thermoelectric module 70706 as a conventionally known technique. The description will be omitted, but the thermoelectric chip substrate module 7060 and the thermoelectric module 70706 will be collectively referred to as a thermoelectric module 706.

On the other hand, various technologies have recently been applied to some blinds and have evolved. The main contents are technological improvements such as indoor reflection of sunlight and solar power blinds, and they are distributed in balconies and double windows of apartment houses such as apartments. This is spreading, but this is a level to be utilized or mounted on the slat surface of the blind, the situation is not properly extended to the inside of the slat of the blind.

In order to improve this, the present inventors pay attention to the application of the inside of the slat, for use in a food waste treatment machine, etc., the angle is adjusted to form a space in which the oil can flow inside the blind slat directly facing the sun slat A flow channel slat (hereinafter referred to as a "flow slat") formed with an inner flow path that leads to the inside, and flows the flow oil heat-exchanged by flowing the flow oil on the flow path connected in multiple stages using a connecting oil pipe. The patent application (10-2009-0087802) (hereinafter referred to as "prior application") of a blind having a flow passage for use (100, hereinafter referred to as "euro blind") will be described briefly. With respect to what is normally required for blind operation to adjust the angle and to overlap or draw out, the present invention further provides the flow path slats and connecting oil pipes. Since it is intended to improve the reference, except for the channel slat and the connecting oil pipe, refer to the prior application, detailed description thereof will be omitted. Hereinafter, the background according to the present invention will be briefly described with respect to the conventionally known flow channel and the connecting oil pipe. As a technology

To help those skilled in the art will be described below with reference to FIG. 5.

FIG. 5E shows the connecting oil pipe 143 consisting of a connecting oil capillary 1432 and an oil pipe connector 1431 provided at at least one end of the connecting oil capillary 1432. FIG. 5A illustrates at least one slat oil pipe 1411 and at least one slat oil pipe connected to the slat oil pipe 1411 and coupled to the at least one connecting oil pipe 143. A conventional flow path slat 141 composed of a passage customs pipe 1412 is shown.

The slat oil pipe 1411 is manufactured by connecting a flat hollow partial aluminum plate tube (see FIG. 5 (b)) having both ends of the slat housing 1410 integrated therein as shown in FIG. 5 (b). Or an intact aluminum plate tube (see FIG. 5 (a)), or as shown in FIG. Final bending at both ends may be directly connected to the slat oil passage customs 1412 used for discharge and draw, respectively, and may be a flat rectangular copper pipe 1416 or an aluminum pipe as shown in FIG. Slat sealing cap 1418 provided with slat oil passage tubulars 1412, each of which is bonded to a thin aluminum sheet in an array using a 1416, and each is used for discharge and retracting having a threaded portion at both ends. ) One by one It forms a flow path within the slat in such a manner.

In addition, as shown in FIG. 5A, the slat housing 1410 may be integrally manufactured with the slat oil pipe 1411 so that sunlight may flow into the flow path slat 141. When manufacturing by extrusion drawing, open the top and press the light receiving window (14101) on the top, but can be produced by airtight processing using adhesive, it is possible to manufacture by injection or extrusion drawing with transparent plastic instead of aluminum plate tube 14101 may be manufactured to be integral with the slat housing 1410 from the beginning.

In addition, to the slat oil passage customs 1412 attached to the slat oil pipe 1411 of different flow path slats 141.

The connection oil pipe 143 is connected, and a plurality of flow path slats 141 are connected to each other in multiple stages, and the connection oil custom pipe 1432 is provided with a flexible hose to overlap when the flow path slats 141 overlap. When it is withdrawn, it is withdrawn.

For example, the flow path blind filed by the present applicant focuses on a set of slats constituting a conventional blind, and expands the functionality of the slat to the inside of the slat so as to utilize natural energy, an air circulation device, and a cooling device. There are aspects that have evolved to a considerable degree so that they can be used.

However, in the applicant's previously filed technology, the flow path slat 141 also has a flat internal structure, so that the thermoelectric module 706 and the solar cell module 703 are not easily disposed together in the slat. The hot air is supplied instead of hot air during rainy weather without solar light by the thermoelectric module 706, or while the cooled air by the thermoelectric module 706 is used for dehumidification, the heated air is supplied to a food waste processor, At the same time, there was a problem in allowing the solar cell module 703 to generate power while cooling.

The present invention has been made in view of the above-described problems in the prior art, and is provided to solve the problem, and provided with a thermoelectric module and a solar cell module inside the slat, and separately used for the oil heated by the thermoelectric module and the cooled oil. It is an object to provide a thermoelectric channel slat in which at least two oil passages are formed.

According to the present invention, in the slat provided in the blind, the thermoelectric slat housing having two inner slat oil passages so that the flow oil flows through the inside; inserted into the open end of the thermoelectric slat housing A fitting member for sealing (closing); and a connecting oil pipe passing through the fitting member to communicate the flow oil on the inner slat oil passage into another thermoelectric slat housing, the thermoelectric flow path slat achieved do.

The thermoelectric slat housing is provided with a plurality of the same size or different sizes, each of which is communicated by a metal tubular tube, among the slab housing for thermoelectric modules, solar cells and slat housings for thermoelectric modules Use any one selected.

At least one row of the thermoelectric module slat housing is divided into a first inner slat oil passage and a second inner slat oil passage by the partition wall having at least a portion thereof hollowed out to form two inner slat oil passages. A dedicated housing member; a female thread passage or a coupling fitted to the thermal housing member to hermetically seal the two inner slat oil passages of the thermal housing member or to communicate the inner slat oil passages of the two thermal housing members. At least one fitting member having a ball formed therein;

In addition, the thermoelectric module slat housing, at least one power connection line; a thermoelectric module connected to the power connection line and installed in the partition portion; is configured to further include, supplying power to the thermoelectric modules or the thermoelectric modules And the inside of the thermoelectric module slat housing is heated or cooled and forced to blow through the heat absorption and heat generated by the thermoelectric module by being electrically connected to the external thermoelectric module control means for controlling. .

The slat housing for the solar cell and the thermoelectric module may include a light receiving window made of a transparent material, and separated into two first inner slat oil passages and a second inner slat oil passage by at least a portion of the hollow partition wall. At least one solar cell and thermoelectric module housing member having an inner slat oil passage formed therein and having a fitting slot for pressing the light receiving window on one side thereof; two inner slat oil passages of the housing member for the solar cell and the thermoelectric module; At least one fitting member having a female screw passage or a coupling hole fitted to the solar cell and the thermoelectric module housing member so as to be hermetically treated or communicate with the inner slat oil passages of the two solar cell and the thermoelectric module housing members; Done,

The slat housing for the solar cell and the thermoelectric module may include at least one power connection line, at least one thermoelectric module installed at the partition wall, and at least one lower end of the light receiving window of the slat housing for the solar cell and the thermoelectric module. The solar cell module further comprises; is electrically connected to the thermoelectric modules or external thermoelectric module control means for supplying and controlling power to the thermoelectric modules through the power connection line, the solar cell modules or the solar The interior of the slat housing for the solar cell and the thermoelectric module through the endothermic and heat generated by the thermoelectric module is electrically connected to the power generation module control means for supplying and controlling the battery module and the inverter or storage battery through the power connection line Heated or cooled and forcedly blown, and the cooled oil is heat exchanged with the solar cell module. And that is characterized.

The present invention is arranged to generate a solar cell module inside the slat for power generation, or instead of supplying high-temperature air during rainy weather without solar light by the thermoelectric module, or utilizing the cooled air by the thermoelectric module for dehumidification and heated at the same time Air can be supplied to food waste disposal equipment, which increases the utility value of the blinds, reducing the payback period and greatly extending the application range of the blinds.

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

Figure 6 is a view showing a thermoelectric channel slat (1) using a thermoelectric module slat housing 771 of an embodiment according to the present invention, Figure 7 is a view showing a fitting member, a protective cap and a power connection line, FIG. 8 is a perspective view of combining two plates using a fitting member, and FIG. 9 illustrates a thermoelectric channel slat 1 using a slat housing 772 for a solar cell and a thermoelectric module according to an embodiment of the present invention. Drawing.

[First Embodiment]

As shown in FIG. 6, the first embodiment includes a thermoelectric slat housing 7 using a slat housing 771 for thermoelectric modules, and is fitted to both open ends of the thermoelectric slat housing 7 to seal it. (Closing) the fitting member (1419) ;, the protective cap (1420) to be fitted over the fitting member (1419), comprising a, the horizontal to heat or cool the flow fluid flowing through the thermoelectric module 706 It is for the thermoelectric flow path slat (1) to be mounted.

As shown in FIG. 7A, the fitting member 1419 is provided with a female thread passage 1419a or a coupling hole 1419b that penetrates the body, or has a coupling female thread portion 1419c to a predetermined depth. It is a plastic or aluminum bar that is screwed together with a vertically mounted clip, or that forms nothing at all. In addition, one side may be formed with a sealing tip (1419e) is a part of the elongated body sticking out to be fitted for a specific purpose. As shown in FIG. 8, the fitting member 1418 is fitted to face the interior of the two thermoelectric slat housings 7 'A' / A "or B '/ B", respectively, and is primarily used in thermoelectric slab housings. 7) A female thread passage 1419a or a coupling hole 1419b, which seals and secondly penetrates the body, is formed, and the metal tubular pipe 1415 is connected to the fitting members 1419 on both sides to form A '. / A "or B '/ B" flow path can be used to communicate or physically connect, as shown in Figure 7 (a) can be sealed both ends of the thermoelectric slat housing (7), As shown in (b) of FIG. 7, a power line passage 1418 d is formed to pass the connection power line 1320, and the connection power line 1320 is passed through.

In addition, the protective cap 1420 is formed with a top opening surface 1420c, a side hole 1420b, a body 1420a, and the other end of the side hole 1420b is fitted to the outer peripheral surface of the thermoelectric slat housing 7 is coupled. .

The thermoelectric module slat housing 771 includes three thermoelectric slat housing members 7710, A ′, A ″, A ′, four fitting members 1418, two protective caps 1420, and four tubules. 1415, two thermoelectric modules 706, and a plurality of power connection lines 1434.

In addition, the first ends of the thermoelectric slat housing 771 using the thermoelectric module slats 771 are provided with one fitting member 1418 and a protective cap 1420, respectively. The thermoelectric flow path slat 1 of the embodiment is constituted.

First, the hollow space and the left and right linear heat sinks 7711 are formed by the partitions 7712 respectively provided at the centers of the heat-only slat housing members 7710, A ', A ", and A'. First, the thermally exclusive slat housing member 7710 (FIG. 6A) formed divided into the right space is provided.

Such heat-only slat housing member 7710 is preferably manufactured by aluminum extrusion and drawing. In particular, the aluminum material is light and has excellent thermal conductivity, so it is used as a material for producing most heat sinks. The partition portion 7712 includes a linear heat sink 7711 at left and right sides, and is manufactured in consideration of thickness to insert the thermoelectric module 706 by cutting the upper portion thereof, and a drawn linear heat sink using aluminum material. It is very advantageous in many aspects to manufacture the portion 7711 to be formed integrally.

Typically, about 30 slats are mounted on the blind, so the material to be manufactured should be as light as possible. In terms of weight, aluminum is a suitable material.

The width of one linear heat sink fin constituting the linear heat sink 7771 is about 1 mm or less, and the width is about 5 mm.

In addition, rather than separately fabricating and assembling the partition wall part 7712 having the linear heat sink part 7711, the partition wall part 7712 is formed to be empty by using aluminum drawing, and the linear heat sink part 7111 is integrated at the left and right sides. Therefore, it is very economical to form a batch in the extrusion process, and in order to insert the thermoelectric module by cutting only the upper portion of the partition portion 7712 (FIG. It is cheaper.

Such incision is preferably cut precisely using a cutting laser. Such aluminum extrusion production and cutting method is well known, and further detailed description thereof will be omitted in the first embodiment.

However, since the aluminum material has high thermal conductivity, when the linear heat sink 7311 of the central partition wall part 7712 is integrally formed with the heat-only slat housing member 7710, the heat-dissipating slat housing member 7710 is provided. It can be delivered internally.

Although the cross-sectional area is very small, it may have an influence even if there is not so much influence, so that it can be attached to the thermoelectric module 706 after drawing out the heat-only slat housing member 7710 except for the linear heat sink 7711. It may be more preferable to separately prepare the linear heat sink 7711, attach it to the thermoelectric module 706, and install the linear heat sink 7711 inside the thermo-only slat housing member 7710.

In addition, since the heat loss through the outer surface of the heat-exclusive slat housing member 7710 made of aluminum is large, it is preferable to form a heat insulation layer by attaching a heat-insulating paint or an infrared ray-blocking film to which color is added. Insulating paint or infrared-blocking film added to the color is more preferable because it affects the aesthetic color of the slat. In the first embodiment, the linear heat sink 7711 is integrally manufactured, and the outside of the heat-only slat housing member 7710 is thermally insulated and finished using heat insulating paint.

Insulation paints or infrared-blocking film added with color can be easily obtained anywhere, many of which are well-known techniques and will not be described in further detail. The thermally exclusive slat housing member 7710 provided in this way is provided by cutting and defining a blind size.

As shown in (d) of FIG. 6, about 20 centimeters at both ends of the thermoelectric flow path slat 1 to support or withdraw the plurality of thermoelectric flow path slats 1 through spaces (not shown). Since it is preferable to have a spacing line (not shown) at a distant position, two thermally-oriented slat housing members 7710 A 'having a length of about 20 centimeters are provided, and an A "having a length of about 1.5 meters is provided. In the first embodiment of the present invention, the widths of A 'and A "are about 7 to 10 cm and the height is about 7 to 10 mm.

In addition, after the upper end of the partition portion 7712 of the thermally exclusive slat housing member 7710 A is inserted in the longitudinal direction of the thermally exclusive slat housing member 7710 to insert the thermoelectric module 706, the two thermoelectric modules 706 are cut. ) Is inserted, and is installed in close contact with the linear heat sink (7711) provided on both sides of the partition portion (7712) using an adhesive such as silicon having good thermal conductivity (Fig. 6 (c)).

In addition, in order to electrically connect the thermoelectric connection terminals 7082 of the thermoelectric module 706, the slat housing member 7710 is connected in series along the space of the central partition wall 7712 using a connecting power line 1434. Withdraw to the end of A.

In the next step, since the heat-only slat housing members 7710, A ', A ", A' are provided, one of the four fitting members 1418 forms three female thread passages and two coupling holes. One is formed with two female screw passages and two coupling holes, the other two are formed by forming two coupling holes, and then the three female screw passages and two coupling holes are provided on the right side of FIG. A fitting member 1419 having two coupling holes is inserted into A 'of 20 centimeters long so that one fitting member 1419 and one fitting member 1419 having two coupling holes are paired to face each other. The fitting member 1419 formed with three female threaded passages and two joining holes was inserted into A ″ of the length, and then the facing fitting member 1419 formed by using the prepared solid metal tubing 1415 of the metal material was formed. Coupling to the coupling hole.

One of the remaining two fitting members 1419 includes one fitting member 1419 having two coupling holes and two female threaded passages, and one fitting member 1419 having two coupling holes formed at the left side of FIG. The fitting member 1419 having two coupling holes is formed in A '20 cm long, and the fitting member 1419 having two coupling holes and two female threaded passages is inserted in A "having a length of 1.5 meters. By coupling the tubular pipe 1415 to the coupling hole, the three thermal-only slat housing members 7710, A ', A ", and A' are physically connected to each other, and a passage is formed so that one slat housing 771 for the thermoelectric module is provided. A)

In the next step, the fitting member 1419, in which female thread passages or coupling holes are not formed, is inserted into and sealed at both ends of the slat housings 771 and A for the thermoelectric module, and two protective caps 1420 are also fitted and closed. The thermoelectric flow path slat 1 of the first embodiment is completed.

When inserting the fitting member (1419) is an airtight bond using an adhesive, a silicone-based adhesive with good heat resistance is used.

Accordingly, the thermoelectric slat housing members 7710, A ′ and A ″ are physically connected by the metal tubing 1415 of the metal material, and the partition walls 7712 of the slat housings 771 and A for the thermoelectric module are physically connected. The first inner slat oil passage 1421 is formed in the left side space, and the second inner slat oil passage 1422 is formed in the right side space. With the exception of the four female threaded passages each, the thermoelectric module slat housings 771 and A are hermetically sealed, and the thermoelectric flow channel slats horizontally mounted between the metal tubing 1415 installed on both sides. A drawbar passage is formed to draw out and overlap).

Then, the connecting oil pipes 143 each provided with a pair of partial wire rope connecting rings 1435 are coupled to female threaded passages on both sides of the two parts, and the partial wire ropes 1437 are tied.

Finally, as shown in FIG. 6D, the protective cap 1420 is fitted to complete the thermoelectric channel slat 1 using the slat housings 771 and A for the thermoelectric module.

In addition, the connection power line 1434 drawn out through the other female screw passage of the right shaft portion of FIG. 6 (D) passes through the inside of the oil pipe connector 1431 and the connecting oil pipe 1432, which is not shown. Connect to thermoelectric module control means.

Accordingly, as shown in FIG. 6D, the left space formed inside the thermally exclusive slat housing members 7710, A ′, A ″, and A ′ is defined as the first inner slat oil passage 1421 and the right space as the second space. The inner slat oil passage 1422 is formed, and the first inner slat oil passage 1421 and the second inner slat oil passage 1422 are connected to two connecting oil pipes 143, respectively, so that the first inner slat oil passage ( Two separate flow paths P1 and P2 are formed in the 1421 and P1 and the second inner slat oil passages 1422 and P2.

In addition, the thermoelectric flow path slat (1) provided as described above is mounted on the conventional flow path blinds in multiple stages, and the details of the overlapping, withdrawal, and angle adjustment of the thermoelectric flow path slats (1) may be referred to a prior application. do.

The thermoelectric flow path slat 1 used for the thermoelectric module according to the first embodiment is basically provided as described above. The operation process will be described below.

Power is applied to the thermoelectric module 706 by thermoelectric control means (not shown), which is electrically connected to the thermoelectric module 706, and thus the thermoelectric module 706 is a housing cooler 600 described in the background art. In accordance with the Peltier effect, the linear heat sink 7311 included in the first inner slat oil passage 1421 is heated, and at the same time, the linear heat sink inside the second inner slat oil passage 1422. Start cooling 7771.

At this time, since a flow oil such as air flows through the first inner slat oil passage 1421 formed above by the first blowing means (not shown), the linear stream included in the heated first inner slat oil passage 1421 is heated. The flow oil is heated by heat exchange with the heat sink 7311 to supply the heated air through the formed flow path P1 to an externally necessary device or another thermoelectric flow path slat 1.

In addition, since the flow fluid such as air flows through the second inner slat oil passage 1422 formed above by the second blowing means (not shown), the linear heat included in the cooled second inner slat oil passage 1422 is cooled. The heat flow is exchanged with the sink 7311 to simultaneously cool and supply the cooled air through the formed flow path P2 to an externally necessary device or another thermoelectric flow path slat 1.

In this manner, the blind mounted with the thermoelectric flow path slat 1 used for the thermoelectric module according to the present invention can supply the flow oil heated by the first blowing means (not shown) to the food waste processor or the like, and the second not shown. The flow oil cooled by the blowing means is supplied to the condenser or room used for dehumidification and is used for the purpose of lowering the temperature of the room.

In addition, a temperature sensor (not shown) may be included in the first inner slat oil passage 1421 and the second inner slat oil passage 1422, and thermoelectric control means (not shown) may be provided. Many are well known and detailed descriptions thereof will be omitted.

In addition, the thermoelectric channel slat (1) consisting of the slat housing 771 for the thermoelectric module can be applied to the vertical blind.

Second Embodiment

As shown in FIG. 9, the second embodiment of the present invention is a thermoelectric slat housing 7 using a slat housing 772 for a solar cell and a thermoelectric module, and open ends of the thermoelectric slat housing 7. A fitting member (1419) inserted into and sealing (closing) it; a protective cap (1420) fitted over the fitting member (1419); and configured to include the solar cell module 703 by the thermoelectric module 706. Cooling or generating power by the solar cell module 703, the thermoelectric module 706 is used for dehumidification of indoor air, or at night when the sun is not shining. It is for the thermoelectric flow path slat (1) to be mounted.

The slat housing 772 for the solar cell and the thermoelectric module includes the slat housing members 7720, A ′, A ″, and A ′ for the solar cell and the thermoelectric module, four fitting members 1418, and four tubules 1415. Two thermoelectric modules 706, a plurality of power connection lines 1434, and one solar cell module 703 are provided.

First, the inside is divided into a left space and a right space by a partition wall 7712 having hollow and linear heat sinks 7711 respectively disposed on the left and right sides thereof, and having a specific height above the left, right, and partition walls 7712. A housing member 7720 for a solar cell and a thermoelectric module having a fitting slot 1413 capable of protruding to couple the light receiving window 14101 is provided.

In addition, the two ends of the thermoelectric slat housing 7 using the solar cell and the thermoelectric module slat housing 772 provided as described above with one fitting member 1419 and a protective cap 1420 respectively. The thermoelectric flow path slat 1 of the second embodiment is configured, and only the slat housing members 7720, A ′, A ″, and A ′ for solar cells and thermoelectric modules are different, and the solar cell module 703 and the light receiving window 14101 are different. Since it is different, the connection, material, fabrication, and cutting method of the slat housing members 7720, A ', A ", A' for solar cells and thermoelectric modules to provide the slat housings 772 and A for solar cells and thermoelectric modules. Since the installation of the thermoelectric module 706 is the same as that of the first embodiment described above, a detailed description thereof will be omitted.

Hereinafter, only matters related to the additional installation of the solar cell module 703 will be described.

Before the finishing operation using the finishing cover member 7713 in the housing member 7720 for the solar cell and the thermoelectric module provided as described above, the light receiving window 14101 is prepared. The light-receiving window 14101 is made of a transparent plastic material that transmits sunlight, but is prepared by cutting to close the closing cover member 7713.

In addition, the solar cell module 703 described in detail in the background art is installed on the upper part of the housing member 7720 for solar cells and thermoelectric modules, and the light receiving window 14101 manufactured as described above is fitted to the fitting slot 1413. do.

At this time, the installation of the solar cell module 703 has a matter to consider. That is, the heated heat is transferred to the solar cell module 703 in the portion of the solar cell and the thermoelectric module housing member 7720 that are heated when the thermoelectric module 706 operates, so that the lifespan and power generation of the solar cell module 703 are increased. Since it affects the efficiency, the solar cell module and the thermoelectric module housing member (7720) and the solar cell module 703 is provided with a heat insulation layer between the corresponding portion or the solar cell module 703 to install the It is preferable.

In addition, as described in the background art, the light receiving window 14101 and the housing member 7720 for the solar cell and the thermoelectric module are electrically connected to the solar cell connecting terminal 7702 by a conductor connecting ribbon 7704. (703) Installing semi-finished products should also be considered in terms of cost reduction and generation efficiency.

In addition, the solar cell module 703 is electrically connected to a thermoelectric module and a solar cell module integrated control means (not shown) and an inverter (not shown).

The thermoelectric flow path slat 1 additionally provided with the solar cell module 703 according to the second embodiment is basically provided as described above. The operation process will be described below.

Power is supplied to the thermoelectric module 706 by a thermoelectric module and a solar cell module integrated control means (not shown) electrically connected to the thermoelectric module 706. Accordingly, the thermoelectric module 706 is a housing described in the background art. Cooling the heat sink 7712 inside the second inner slat oil passage 1422 by heating the heat sink 7712 contained within the first inner slat oil passage 1421 according to the Peltier effect in the same principle as the cooler. To start.

At this time, the solar cell module 703 installed on the upper inner slat oil passage 1421 side of the solar cell and the thermoelectric module housing member 7720 is cooled, and the solar cell module 703 is not shown. It is electrically connected to the city and develops when the sun shines.

At this time, a flow oil such as air is supplied to the first inner slat oil passage 1421 formed by the first blowing means (not shown) controlled by the thermoelectric module and the solar cell integrated control means (not shown). Since it flows, the flow oil is heated by heat exchange with the heat sink 7712 included in the heated first inner slat oil passage 1421.

In addition, a flow oil such as air is provided in the second inner slat oil passage 1422 formed by the second blowing means (not shown), which is controlled by the thermoelectric module and the solar cell integrated control means (not shown). Since it flows, the flow oil is cooled at the same time by heat exchange with the heat sink 7712 included in the cooled second inner slat oil passage 1422.

In this manner, the blind on which the thermoelectric flow path slat 1 further including the solar cell module 703 according to the second embodiment is mounted, is used for flowing fluid flow heated by a first blowing means (not shown). The liquid oil which can be supplied to a food waste processor or the like and is cooled by a second blowing means (not shown), which is supplied to a condenser such as dehumidification or the like, can be used for lowering the indoor temperature and mounted as described above. The solar cell module 703 is cooled to increase power generation efficiency. The thermoelectric module 706 generates electricity generated from the solar cell module 703 by a thermoelectric module and a solar cell integrated control means (not shown). It can be used to maximize the use of solar energy, and can be operated by supplying power to the thermoelectric module 706 in the rainy sky or at night when the sun is not shining, the application range is very large In addition, the waste heat generated at this time may be supplied to a food waste processor and recycled.

In addition, a thermoelectric module and a solar cell integrated control means (not shown) and a storage battery (not shown), an inverter (not shown), etc. for generating a solar cell are well known and detailed description thereof will be omitted.

1 is a view showing a conventional solar cell module

2 is a view showing a conventional housing cooler

3 is a diagram illustrating a thermoelectric chip substrate module, which is a type of a conventional thermoelectric module.

4 is a diagram illustrating a thermoelectric module which is a type of a conventional thermoelectric module.

5 is a cross-sectional view showing the type of the conventional flow path slat 141.

6 is a diagram illustrating a thermoelectric channel slat 1 using the slat housing 771 for a thermoelectric module according to an embodiment of the present invention.

7 is a view showing a fitting member, a protective cap, and a power supply line;

8 is a perspective view of combining the two plate by using the fitting member

9 is a view illustrating a thermoelectric channel slat 1 using the slat housing 772 for a solar cell and a thermoelectric module according to an embodiment of the present invention.

♧ description of the symbols for the main parts of the drawing ♧

    1: thermoelectric euro slat

    7: thermoelectric slat housing

  100: Euro blinds

  141: Euroslat

14101: light receiving window

1413: fitting slot

 1435: partial wire rope hook

 1437: partial wire rope

 1436: connecting power line

 1412: slat oil passage customs 1420: protective cap 1419: fitting member

  143: connecting oil pipe 1431: oil pipe connector

 1432: Connected Customs

 1415: Customs House

 1421: first inner slat oil passage 1422: second inner slat oil passage

600: enclosure cooler

601 enclosure

602: housing heat absorbing unit 6021: housing cold sink 6022: housing cooling fan

603: enclosure heat generating unit 6031: enclosure heatsink 6032: enclosure heat dissipation fan

771: slat housing for thermoelectric modules

772: hybrid thermal slat housing

7710: thermal only slat housing member

7720: housing member for solar cell and thermoelectric module

7711: linear heat sink 7712: central bulkhead

7713: Finishing cover member

 703: solar cell module

7032: solar cell connector

7034: conductor connecting ribbon

706: thermoelectric module

7060: thermoelectric chip substrate module

7061: thermoelectric chip

7062: thermoelectric connector

7063: thermoelectric chip circuit board

70600: thermoelectric module 70600: solar power module

70610: thermoelectric element 70611: electrode terminal 70615: thermoelectric semiconductor

70612/70616: conductive electrode 70613/70614: ceramic substrate

Claims (7)

In the slat provided in the blind; A thermoelectric slat housing (7) having two inner slat oil passages so as to flow the flow oil therein; Fitting members (1419) fitted to both open ends of the thermoelectric slat housing (7) to seal (close) it; The protective cap (1420) is fitted over the fitting member (1419); thermoelectric flow path slats comprising a. The method according to claim 1; The thermoelectric slat housing 7 The thermoelectric flow path slats characterized in that a plurality of the same size or different sizes are provided, they are communicated by the metal tubular pipe (1415). The method according to claim 1; The thermoelectric slat housing 7 The thermoelectric module slat housing 771, the solar cell and the thermoelectric module slat housing (772) made of any one selected from the thermoelectric flow path slat. The method according to claim 3; The slat housing 771 for the thermoelectric module, At least one heat exclusively formed with two inner slat oil passages, the interior of which is separated into a first inner slat oil passage 1421 and a second inner slat oil passage 1421 by at least a portion of the hollow bulkhead 7712. Housing member 7710; Two inner slat oil passages of the thermal housing member 7710 to be hermetically sealed or inserted into the thermal housing member 7710 to communicate with the inner slat oil passages of the two thermal housing members 7710. At least one fitting member (1419) having a female threaded passage or a coupling hole formed therein. The method according to claim 4; The slat housing 771 for the thermoelectric module, At least one power connection line 1424; And a thermoelectric module 706 connected to the power connection line 1436 and installed in the partition wall 7712, and supplying and controlling power to the thermoelectric modules 706 or the thermoelectric module 706. Is electrically connected to the external thermoelectric module control means through the power connection line (1436), The inside of the thermoelectric module slat housing (771) through the endothermic and heat generated from the thermoelectric module 706 is heated or cooled and forced air blowing slats. The method according to claim 3; The slat housing 772 for the solar cell and thermoelectric module, A light receiving window 14101 of a transparent material; The interior is separated into a first inner slat oil passage 1421 and a second inner slat oil passage 1421 by at least a portion of the hollow wall portion 7712, which forms two inner slat oil passages, and on one side thereof, At least one solar cell and thermoelectric module housing member 7720 having a fitting slot 1413 for forcing the light receiving window 14101 into place; The solar cell to hermetically seal the two inner slat oil passages of the solar cell and the thermoelectric module housing member 7720 or to communicate the inner slat oil passages of the two solar cells and the thermoelectric module housing member 7720. And at least one fitting member (1419) formed with a female screw passage or a coupling hole fitted into the thermoelectric module housing member (7720). The method according to claim 5; The slat housing 772 for the solar cell and thermoelectric module, At least one power connection line 1424; At least one thermoelectric module 706 installed in the partition portion 7712; At least one solar cell module 703 is provided at the bottom of the light receiving window 14101 of the slat housing 772 for solar cells and thermoelectric modules; The thermoelectric modules 706 are electrically connected to each other or to an external thermoelectric module control means for supplying and controlling power to the thermoelectric module 706 through the power connection line 1424, The solar cell modules 703 are electrically connected to each other or the power generation module control means for supplying and controlling the solar cell module 703 and the inverter or storage battery through the power connection line (1436), The inside of the solar cell and the thermoelectric module slat housing 772 is heated or cooled and forcedly blown through the heat absorption and heat generation generated by the thermoelectric module 706, and the cooled oil is heated with the solar cell module 703. Thermoelectric flow path slats characterized by being exchanged

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