NO781230L - SOLAR CELL PANEL. - Google Patents

Description

The invention relates to a device for socelle panels.

Solar panels have worked satisfactorily in clean environments such as in outer rooms, empty areas and high altitudes. In other environments, and particularly for marine applications, solar panels have been shown to have unexpectedly short lifetimes when exposed to typical degrading conditions including moisture, salt water, atmospheric pollution, chemicals, dirt, sulfur compounds, bird droppings, degrading sunlight (as well as ultraviolet such as infrared) and extreme temperature changes. While a partial use of glass has been proposed in the U.S. patents no. 2,946,945 and 2,823,245, the more modern tendency has been to use different plastic materials to cover the solar cells. However, the various types of solar cell packaging in use have been generally unsatisfactory at that time

has been exposed to adverse conditions, such as in marine use due to the different types of decomposition. The most common type of failure is separations that occur between the different layers in the solar panel which result in extensive light reflection with a consequent reduction in electrical yield and possible failures in the electrical connections between the photo-element cells. Errors have most often been traced back to errors in the panel covering as opposed to errors in the cells and are caused by the above-mentioned degradation that occurs in exposed environments.

The present invention is directed towards the provision of a solar cell panel with an enclosure which is suitable for use in extreme, exposed environments.

The present invention is aimed at a solar panel with a top and bottom glass plate. The glass plate is advantageous in that they (1) are relatively impervious to degrading substances, (2) they are not degraded by ultraviolet light, (3) the glass top cover reduces the transmission of degrading ultraviolet radiation which attacks the composition compounds, -(4) glass and the commonly used solar photovoltaic cell materials have a similar thermal expansion and thus minimize mechanical stresses, (5) the bottom glass plate allows the transfer of unused infrared radiation through the panel and results in a cooler, more efficient panel, (6) the chemically inert properties of glass provides stability in the presence of corrosive organic and inorganic substances, (7) the surfaces of glass are easily washed by rain and (8) unwanted coatings are easily removed from the glass plates.

Another purpose of the present invention is

to provide a solar cell panel with top and bottom stopped glass plates where each of the plates has a downwardly directed side wall that extends around the outer circumference in which the bottom plate is placed below and in the side wall of the top plate and thereby directs the opening towards the chamber formed between the top

and the bottom plates in a downwards direction to avoid direct exposure to rain, spray from sea water and foam spray.

A further purpose of the invention is to provide tapers that are plugged into either the bottom of the top plate or the top of the bottom plate for receiving the solar cells, whereby the thickness of the chamber is kept as small as possible. The socket cells are placed in each of the tapers and an insertion compound with a refractive index equal to the refractive index of the glass fills the chamber. The arrangement of the tapers provides the following advantages: (l) uniform thickness of the embedment connections results in more uniform loading, (2) reduction of the embedment connection volume with consequent cost savings, (3) reduction in thickness of the embedment connection, thereby overcoming the problem of thermal expansion of the embedment connection , and (4) the solar cells float in the embedding compound and reduce contact point stresses. The thickness of the chamber must, however, be made sufficient to allow the embedding compound to withstand temperature changes.

A further purpose of the present invention is to provide a solar cell panel where the inner surface of the top and bottom glass plates is textured to increase the adhesion of the embedding compound to the glass plates by

increase the effective bonding area.

It is also a purpose of the present invention to provide a passage from each taper to an adjacent taper for adaptation of the electrical connections between adjacent solar cells and to allow solar cells and electrical connections to flow in the embedded connection.-In addition, there is a purpose of the present invention , to provide electrical connections for the solar cells that sealingly extend downwards through the bottom plates. The electrical connections include an extended inner path leading to one of the tapers with a pin extending from the path through the base plate, an ore placed in the path and soldered to the pin with the ore electrically connected to a solar cell and a sealing material filling the path . The electrical connections provide a slack connecting wire that allows strain relief for the fragile solar cells and provides a strong mechanical end part and. is directed downwards and sealed to prevent the entry of harmful substances from the surroundings.

In the following, the invention will be explained in more detail with the help of an embodiment which is shown in the drawing, which shows: Fig. 1 an elevation of the bottom to the top plate of the solar cell panel according to the invention,

fig. 2 an elevation of the top of the base plate of the solar cell panel, according to the invention,

fig. 3 a cross-section along the line 3-3 in fig. 1 with the solar panel in assembled state,

fig. 4 a cross-section along the line 4-4 in fig. 1 of the solar panel in assembled state,

fig. 5 an enlarged partial cross-section along the line

5-5 on fig. 4 and

.fig. 6 an enlarged partial cross-section along the line

6-6 on fig. 3-

In fig. 3 shows the reference number 10 the solar cell panel according to the invention which is a solar-photocell energy converter, which, although it can be used for many purposes, is particularly intended for charging a battery system during the hours of daylight for the • operation of marine aids to navigation. The panel 10 includes a top part 12 and a bottom part 14. The top part 12 and the bottom part 14 are designed as a stiffened glass plate. The glass components are particularly advantageous in that (1) they are relatively impermeable, especially in comparison with plastic, (2) they are not exposed to ultraviolet degradation, (3) the top glass plate reduces the transfer of degrading ultraviolet radiation which could affect the embedding compounds, (4) glass as well as the commonly used photo-element cell materials have an equal thermal expansion and thereby minimize mechanical stresses, (5) the bottom glass plate allows the transfer of unused infrared rays through the panel 10, which results in a more efficient, and more efficient construction of the panel, (6) the chemically inert properties of the glass provide stability in the presence of corrosive organic and inorganic agents, (7) the outer surfaces of the plates 12 and 14 are easily washed by rain, and (8) unwanted coatings can easily removed from the surfaces of the glass plates 12 and 14.

The top plate 12 is stiffened in one piece with a downwardly directed side wall 16 that extends around the outer circumference of the plate 12. In a similar way, the bottom plate 14 is designed as a stiffened glass plate in one piece with a downwardly directed side wall 18 that extends around the outer circumference of the bottom plate 14 When the top plate 12 and the bottom plate 14 are assembled, as can best be seen from fig. 3-5, the bottom plate will be placed under and in the side wall 16 of the top plate 12 with the side wall 18 close to the inside of the side wall 16 to. the top plate 12. For this reason, the opening 20 between the top plate 12 and the bottom plate 14, which leads to a chamber 22 which is formed between the top plate 12 and the bottom plate 14, will be directed downwards. The close fit in the downward opening 20 minimizes the sealing area between the plates 12 and 14 and inhibits entry of substances from the surroundings into the chamber 22.

In fig. 1 and 3 you can see several pockets or tapers 24, here as an example shown sixteen tapers 24, which are built either in the top plate or the bottom plate 14 and preferably as shown in the bottom of the top plate 12 for recording ordinary solar cells, such as solar-silicon photo -element cells of type P on N or N on P type. Preferably, the tapers .24 are dimensioned and shaped as shown here in circular form, to be adapted to the size and shape of the solar cells 26 which they are to accommodate. In addition, a passage has been designed from each step-off 24 to at least one adjacent step-off 24 for placing an electrical connection 25 between adjacent solar cells 26 in the step-offs 24. As can best be seen from fig. 1, the tapers 24 are preferably placed in longitudinal and transverse rows with a passage from each taper 24 which extends both longitudinally and transversely and thereby allows the cells 26 to be connected either in series or in parallel according to

bnsk. Any suitable embedding compound 27, which has a refractive index corresponding to the refractive index of glass, fills the chamber 22 (Figs. 4-6). A suitable type of embedding compound is a rubber silicone vulcanized at room temperature, e.g. of the type marketed under the name "Seal-gard" (Dow Corning). In recent times, the embedding compounds have caused problems in solar panels as they generally have a thermal expansion greater than the thermal expansion of the panels and have sometimes caused cracking and breaking of the solar panels. In the present arrangement, the tapers 24 minimize the pressure and volume of the chamber 22 and thereby reduce the thickness and volume of the embedding compound required and thereby reduce the problem of thermal expansion of the embedding compound 27. Other advantages of the tapers 24 are that they provide a uniform thickness for the embedding compound 27 somewhat which results in more uniform stress, reduces the volume of embedding compound 27 required with the following cost savings, causes the cells 26 to flow in the tapers 24 and thus reduces point contact stresses. Preferably, both the bottom 30 of the top plate 16 and the top 32 of the bottom plate 14 are textured or made rough, for example by chemical etching or mechanical roughing. Textured surfaces 20 and 32 are therefore cleaned and increase the adhesion of the embedding compound 27 by increasing its effective bonding surface. The tapers 24 also allow

a reduced thickness of the chamber 22 which improves the bonding of the top layer 12 to the bottom plate 14.

However, the thickness of the chamber 22 must be sufficient to maintain the elasticity of the embedment compound 27. That is, the embedment compound 27 expands and contracts with variations in the ambient temperature and extremely thin sections of embedment compound 27 tend to pull away when they are subjected to the thermal cycle. , Therefore, spacers such as hemispheres 29 (shown in Figs. 1 and 5__, but not in. Figs. 3 and 4 due to the scale of the figures) are stbpt on either the top plate 12 or the bottom plate 14, here shown on the top plate 12 to maintain the thickness to chamber 22 above a predetermined minimum. E.g. the height of the spacers 29 in one embodiment is 0.5 mm and thereby keeps the thickness of the chamber 22 at 0.5 mm. Preferably, the thickness of the tapers 24 is 0.5 mm and the thickness of the solar cell is 0.35 mm. Plus. to provide a minimum thickness of the chamber 22 and the embedment compound 27, it should therefore be advised that the thickness of the embedment compound 27 over the entire chamber 22 is the same, which helps the embedment compound 27 to withstand thermal variations.

Electrical connections are arranged at the solar cells, and these extend sealed through the bottom plate 14. Fig. 1, 2, 4 and 5 show an opening 34 which is stuck into the bottom plate 14 and a taper 36 is stuck into the top plate 12. A pin bolt 38 is placed with its head 4b in the opening 36 and extends through the opening 34 in the bottom plate 14. A bre 42 is soldered to the pin 38 and is placed in a path 44 which is stbpt in the top plate 12 to provide a slack connection which is connected with a solar cell and allows strain relief which is desirable due to the fragile design of the solar cells 26. Preferably, the web 44 has an extended length and is filled with a suitable sealing compound to prevent entry of foreign matter into the interior of the chamber 22. An electrical end piece 45 is threaded to the pin

38 against an 0-ring 46. Thus, the downward-directed electrical connections will provide mechanically strong and weatherproof end parts for

connection with an external electrical connection 48 by means of a threaded screw 50 on the end piece 45.

It is preferred that the steps 24 are at the bottom of the top plate 12 to facilitate the assembly of the solar panel 10. This allows the top plate 12 to be placed downwards with the bottom 30 directed upwards. Electrically connected cells 26 are placed in the embedment connection 27 which fills the tapers 24, and the bottom plate 14 is inserted into the bottom of the top plate 12. The sealing around the opening 20 between the top plate 12 and the bottom plate 14 can be carried out by filling the chamber 22 completely with embedding agent 27 so that this will strbmme_over_and_through the opening 20 and form a seal in it. However, the opening 20 can also be sealed with other materials such as epoxy glue or the opening 20 can be sealed by melting the side walls 16 to the walls 18.

The invention is therefore suitable for achieving the purposes mentioned at the outset and achieving the thereby desired advantages. Although a preferred embodiment has been described, the invention is not limited to this, but many modifications can be made within the scope of the invention.

Claims (12)

1. Enclosure device for receiving several solar cells, characterized in that it comprises a rigid top glass plate with a downwardly directed side wall extending along the outer circumference, a rigid bottom plate with a downwardly directed side wall extending around the outer circumference, which bottom plate is intended to be placed below and in the side wall of the top plate with the side wall of the bottom plate closely adjacent to the inside of the side wall of the top plate to provide a downwardly directed opening to the chamber formed between the top plate and the bottom plate, several tapers which are stbpt in either the bottom of the top plate or the top of the bottom plate for recording the solar cells whereby the thickness of the chamber is kept as small as possible, which tapers are dimensioned and shaped to suit the structure and shape of the solar cells, a passage from each taper to an adjacent taper for making electrical connections between the solar cells, and electrical connection extending from the chamber through the base plate. 2. Device according to claim 1, characterized by several spacers which are placed between the top plate and the bottom plate to keep the thickness of the chamber above a predetermined minimum. 3. Device according to claim 1, characterized in that the tapers are arranged in several longitudinal and transverse rows and that the passages extend from each taper in longitudinal and transverse direction for connecting the solar cells in parallel or in series. 4. Solar cell panel comprising a stiffened top glass plate with a downwardly directed sidewall extending around the outer periphery, a stiffened bottom glass plate positioned below and in the downwardly directed sidewall of the top plate with the outer perimeter of the bottom plate adjacent to the inside of the sidewall of the top plate to provide a downwards opening for the chamber formed between top plate and bottom plate, several ■ step-offs that are stuck in either the bottom of the top plate or the top of the bottom plate for receiving solar cells, whereby the thickness of the chamber is made as small as possible, a solar cell placed in each of the step-offs, embedding agents with a refractive index equal to the refractive index of the glass, for filling the chamber , and electrical connections to the solar cells, which in a sealed state extend through the bottom plate. 5. Device according to claim 4, characterized in that the step-offs are sized and shaped to suit the rod movement and the shape of the solar cells. 6. Device according to claim 4, characterized by several spacers which are placed between the top plate and the bottom plate to keep the thickness of the chamber above a predetermined minimum whereby the embedding agent can resist thermal variations. 7. Device according to claim 4, characterized in that the interior of the top plate and the bottom plate are textured surfaces which provide a curved adhesion for the embedding agent. 8. Device according to claim 4, characterized in that the tapers are designed at the bottom of the top plate. 9. Device according to claim 4, characterized by passage from each taper • to an adjacent taper for placing electrical connections between adjacent solar cells. 10. Device according to claim 4, characterized in that the electrical connections include an elongated internal path leading to one of the step-offs, a pin extending from the path through the bottom plate, a blade placed in the path and connected to the pin, which blade is electrically connected with a solar cell, and sealing material filling the path, an electrical end piece which is connected to the pin on the outside of the base plate, and a sealing ring between the end piece and the base plate. 11. Solar panel comprising a stiffened top glass plate with a downwardly directed sidewall extending along the outer circumference, a stiffened bottom glass plate with a downwardly directed sidewall extending along the outer circumference, which bottom plate is placed below and inside the sidewall of the top plate with the sidewall of the bottom plate closely adjacent to the inside of the side wall of the top plate to provide a downwardly directed opening for the chamber formed between the top plate and the bottom plate, several tapers that are stamped in either the bottom of the top plate or the top of the bottom plate for receiving solar cells, whereby the thickness of the chamber is made as small as possible, which tapers are dimensioned and shaped to suit the size and shape of the solar cells, a solar cell placed in each taper, a passage from each taper to an adjacent taper for placing electrical connections with adjacent solar cells, embedding agent with a refractive index corresponding to the refractive index of the glass and which fills the chamber, and electrical connections to the solar cells which, in a sealed state, extend through the bottom plate. . 12. Device according to claim 11, characterized by. multiple spacers placed between the top plate and the bottom plate to keep the thickness of the chamber above a predetermined minimum by which the embedding agent can withstand thermal variations.