ES2272174B1 - SYSTEM OF FLAT SOLAR COLLECTORS. - Google Patents

Abstract

Flat solar collector system. A heat transfer fluid circulates inside the collectors and they are associated forming a battery of solar collectors, in connection with consumptions or heat exchangers (15) of a heating installation, sanitary hot water or similar, and limiting means of the temperature, which comprise a heat sink (10), arranged in parallel with the solar collectors (1) and enclosed in an enclosure or fairing. The outflow (23) and return (24) connections of the heatsink are arranged above the flat solar collectors, which makes the hotter heat transfer fluid of the collector forced to stir due to the pressure gauge of the fluid plus cold and dense heat sink, producing a circulation of fluid in one direction or another.

Description

Flat solar collector system.

Technical sector of the invention

The present invention relates to a system of flat solar collectors, through which a fluid circulates heat carrier and that are associated forming a battery of solar collectors, in connection with consumptions or exchangers of heat of a heating installation, domestic hot water or similar, and temperature limiting means, comprising a heat sink, arranged in parallel with the collectors solar.

Background of the invention

It is increasingly frequent that facilities Domestic hot water (DHW) and domestic heating thermally powered by flat solar collectors, with the consequent advantages of being able to dispense with the supply of fossil fuels, to improve overall energy efficiency and of being absolutely harmless from the point of view environmental.

Systems to flat solar collectors conventional usually includes a field of collectors, associated in series and in parallel, inside which a liquid circulates, which it can be water, which is heated by the effect of solar radiation. To improve performance, collector liners they are currently made of radiation selective materials, which allow the passage of solar radiation in one direction and not in the direction On the contrary, so that all the radiant energy passes into the liquid. The liquid, once heated, can circulate by convection natural or by pumping to the domestic installation, where its energy content is consumed in the ACS installation, heating, pool air conditioners or similar systems, the liquid cooling, and from where it returns, at a lower temperature, at collector field.

The new European Standard EN12828 on systems of heating in buildings and design of heating systems by water, which is also applicable to ACS systems (water sanitary hot) dictates that the systems must be equipped with safety devices against maximum excess temperature of functioning. This standard is applicable to the systems of heating and ACS whose thermal generation system, or generator heat, either by solar collectors.

The Standard indicates that when this temperature Maximum operating on the primary side of consumption is 105ºC, it is only necessary to have a temperature regulation of operation on the side of the secondary. However it would be optimal have means to ensure that the temperature in the primary does not exceed 105 ° C (except the obvious peaks by thermal inertia up to 115 ° C).

The European Standard EN 12828, transposed in Spain through the CTE Standard (Technical Building Code), HE4, Section 3.2.2.3.1 (Protection against overheating), indicates that " solar installations must be equipped with control devices manual or automatic to avoid overheating of the installation ", and proposes some installation examples.

The technical problem you are trying to solve as a goal by the present invention are the usual ones and inconveniences overheating in summer of this kind of facilities with their innumerable negative consequences, such how:

- oversized closed expansion vessels and water and anti-freeze losses;

- degradation of the selective surfaces of the collectors;

- discomforts in manually covering the solar collector surfaces;

- installation of supplementary deposits; electric pumps and electric fans with their corresponding dependence and consumption of electricity supply;

- formation of scale and corrosion; pump cavitation; etc.

These overheats occur so more pressing when, in summer, the installation pump stops or stops, due to breakdown or any other cause there is a sunstroke About the captadote. The present invention aims at provide a new heating and hot water installation sanitary by solar thermal energy with means temperature limiters that facilitate the achievement of this objective in an easy, autonomous and efficient way.

Installations of heating and domestic hot water using solar energy thermal, comprising a circuit known per se primary with a solar collector system with functions of heat generator, through which a thermal fluid circulates, in series with the consumptions or heat exchangers of a heating or sanitary hot water installation, and means temperature limiters, which prevent the temperature of the thermal fluid in the primary circuit increases above a maximum predetermined temperature, and a safety circuit with an expansion vessel, arranged in parallel with the collectors solar. It is also known that said limiting means of temperature comprise a heat sink, arranged in parallel With solar collectors. Preferably the heat sink is a copper fin heat exchanger.

The heat sink can be arranged in the same safety pipe downstream from the expansion vessel, extending the descending section of said safety pipe until the return or entry of the solar collectors through a check valve

Alternatively, the installation comprises a thermostatic sensor valve incorporated at the outlet of the solar collectors, to which it pours the descending section of the safety pipe of the safety circuit and connected to a first end of the heat sink; and a pipe of by-pass and a connection from the second end of the heat sink to the expansion pipe.

This known solar collector system does not requires permanent personal attention, no additional facilities or additional electrical, does not require supplementary deposits, nor appliances with moving elements, such as pumps or fans. He additional fact that it does not require automatisms also collaborates in that Less breakdowns occur. In addition, it does not require electrical consumption supplementary, so, as experts in the technique, the overall energy efficiency increases with respect to current conventional solar collector systems.

Explanation of the invention.

The known system cited above gives place to two possible schemes, among others, in which the going to heatsink is above the collectors and the return to the heatsink It is below the collectors.

The present invention aims at variants and improvements with respect to the known collector system previously cited, and regardless of the security system to glass of expansion.

Specifically, the present invention has for object a system of flat solar collectors, applicable to conventional collectors whose interior circulates, in a way known, a heat transfer fluid and that are associated forming a solar collector battery, in connection with consumption or heat exchangers of a heating, water installation hot sanitary or similar, and limiting means of the temperature, which comprise a heat sink arranged in parallel with solar collectors. In its essence, the present invention is characterized, according to the characterizing part of claim 1, for the fact that both go to the heatsink as the return to it is made above the collectors flat solar, which makes the heat transfer fluid more hot collector is forced to stir by the effect of gauge pressure of the coldest and dense heatsink fluid heat, producing a fluid circulation in one direction or other.

In claims 2 to 12 are described Preferred embodiments of the present invention, among the which should be noted the fairing of the heatsink, along with the condenser battery valve elements, which eliminates connection operations and greatly facilitates assembly and commissioning operations of the collectors

Brief description of the drawings

The detailed description will be made below of the preferred embodiments of the present invention, for whose best understanding is accompanied by some drawings, given merely by way of non-limiting example, in which:

Figs. 1 and 2 are two embodiments of the flat solar collector system of the present invention, in particular for collector mounting batteries in parallel;

Figs. 3 to 5 are three other ways of realization of the system of flat solar collectors of the present invention, but for series mounting manifold batteries; Y

Fig. 6 is a schematic view of a heat sink formed by two parallel finned tubes with square fins, enclosed in a fairing with perforations, corresponding in particular to the realization of double tube of the Fig. 3.

Detailed description of the drawings

In these drawings it can be seen that the system of flat solar collectors of the present invention, by which a heat transfer fluid circulates inside, for example water with additives, are associated forming a battery of solar collectors 1, 1 'in connection with consumption or heat exchangers 15 of a heating installation, hot water, swimming pool heated or similar, whose water is driven by pump 16, in series with consumptions 15 and collectors (or collectors) 1, 1 'a through a conduit 8. In particular these are collectors 1, 1 'low temperature, the type of those who work at about 60-70 ° C and are typically formed by upper 27 and lower 28 tubes connected by tubes for connection in serial interior configurations (Figs 1 and 2) or parallel (Figs. 3, 4 and 5) as coils. Only in Fig. 1 said tubes 27 and 28 and the outline of the recess have been represented 26 of the collectors 1, having omitted said recessed in the rest of figures, for reasons of greater clarity.

The installation is complemented by means temperature limiters, which comprise a heat sink 10, arranged in parallel with the solar collectors 1. Said heat sink is preferably a heat exchanger 10 of 20 copper fins.

In Figs 1 to 5, pump cases are represented stop, so the flows through the pump 16 and the exchangers or consumptions 15 is null, and have been represented with dashed line, while there is a flow through the heat sink 10, shown with continuous stroke. The arrows indicate, therefore, possible directions of circulation "at pump stop" of the flow through manifolds 1 and 1 'of the heatsink, according to be the embodiment of the invention.

An example of such can be seen in Fig. 6 heatsink, formed, for example and not exclusively, by two tubes 18, 19 finned with fins 20 flat shaping copper rectangular.

The essential and novel thing about the invention is that, at unlike other embodiments of the technique, both the connection outflow 23 of heatsink 10 as the return connection 24 to it They are arranged above the flat solar collectors 1. This setting allows the hottest collector water to be forced to stir due to the manometric pressure of the colder and denser water from the heat sink 10, producing a fluid circulation in one direction or another.

In Figs. 1 and 2 two forms of realization of the system of flat solar collectors of the present invention, in particular for collector batteries 1, 1 'of parallel connection or assembly.

Specifically, in Fig. 1 between the exit of the heatsink 10 and the entrance to the manifolds is a valve of retention 9, preferably of light clapper. It is valid for at least two collectors 1 with lower inputs and outputs superior.

In this case of assembly, when the pump pressure 16, check valve 9 remains open and allows the circulation between the tubular coils of the manifolds 1, 1 'and the finned tube heatsink 10. In this For example, the flow is descending by a collector 1 and ascending by the other collector 1 '.

Circulation occurs in the sense of left to right or inverse due to higher water density cold contained in the heatsink with respect to the hottest and by therefore of lower water density of the collectors 1. Therefore, this unstable equilibrium cannot be maintained and the water ends circulating in one way or another, producing the result sought to dissipate overheating of collectors 1, as safety measure, performance improvement and chasing the purpose of compliance with Standard EN12828.

A scheme is shown in Fig. 2 alternative for series manifolds, comprising a valve thermostatic sensor 12, instead of the check valve, incorporated between heat sink 10 and at least one outlet of the solar collector battery 1. The temperature sensor 17 it is incorporated in the middle path of the "T" formed to the collector battery output 1.

In Figs. 3 to 5 other three are represented alternative ways of realizing the collector system flat solar of the present invention, in particular in this case for collector batteries 1, 1 'of connection or assembly in Serie.

In the scheme of Fig. 3, enter the exit of the heatsink 10 and the entrance to the collectors there is arranged a check valve 9. That is, as in the case of Fig. 1, but applied to one or two round trip collectors on the part top of the collectors 1.

A variant with with respect to Fig. 3, equipped in this case with a valve thermostatic sensor 12, incorporated between the heat sink 10 and at least one serial output of the solar collector battery 1. Temperature sensor 17 is incorporated in the path of in middle of the "T" formed at the battery outlet of collectors

In the scheme of Fig. 5 a evolution of the scheme in Fig. 4, but applied to three collectors 1 in series, with a corresponding thermostatic valve 12 that communicates the input of each collector 1 of the series with a corresponding point 25, initial or intermediate, associated with heat sink 10. This embodiment is suitable to allow water circulation by gravity. It will be understood that it is expandable to another number of collectors greater than three.

In the case of Fig. 2, with the pump 16 stopped, a downward flow can be established through three tubes of the left of collectors 1 and 1 ', and ascending by three tubes of the right of the same collections 1, 1 ', which is represented, or vice versa. The establishment of the flow in each tube is random, so you can also go down, in the example of two collectors of 5 tubes each, lower the liquid Cold heat carrier only by three tubes and ascend by the seven remaining, depending on which areas are colder or more insolated than collectors

A heatsink is illustrated in Fig. 6 heat 10 formed by two tubes 18 and 19 in parallel, finned with square fins 20, enclosed in an enclosure fairing 21, provided with perforations or ventilation openings 22. The pipes 18 and 19 stand out for connection with the exit or return of the collectors.

The heatsink of Fig. 6, of which only distinguish the first of its 20 square fins, may correspond to the heatsink 10 illustrated in the case of Fig. 3.

As a preferred embodiment, the fairing 21 encloses check valve 9 and / or valve thermostatic 12, and even come mounted thus getting a modular element for easy transport and assembly.

The fairing 21 can be made of copper plate, brass, stainless steel, painted iron, etc., and preferably metallic, for proper heat transmission

The distance "d" between the sheet constitutive of the fairing and the edge of the fin 20 must be tending to zero, in order to achieve good thermal contact and collaborate perforated sheet metal to heat dissipation additional to convection through windows determined by the openings 22. The hot perforated sheet itself transmits heat to the outside by radiation.

The openings 22 may be made in the 4 faces of the fairing 21 or only on 3 of its faces being the fourth face, in this case the front, opaque, without loss of performance appreciable.

The openings 22 may be rectangular, such as in the case represented in Fig. 6, oval, circular or All other suitable form.

Those skilled in the art will understand that Installation of the present invention allows to solve the issues raised, yes how to get important type advantages technical-functional and economic. Among the advantages of a technical-functional type, the following:

i) avoid the usual and inconvenient overheating in summer of this kind of facilities with its innumerable negative consequences, such as:

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glasses oversized closed expansion and water losses and antifreeze;

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surface degradation selective collectors;

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discomforts in manually covering the solar collector surfaces;

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installation of supplementary deposits; electric pumps and electric fans with their corresponding dependence and consumption of electricity supply;

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inlay formation and corrosion pump cavitation; etc.

ii) the system fully complies with the temperature limitation of the Spanish and European standards UNE-EN 12828, without relying on any kind of electroautomatisms, nor of the power supply.

The main economic advantages of the Present invention are:

a) this system eliminates the direct cost of all class of automatic and manual air and gas traps and large closed expansion tanks;

b) the system supports, like any installation domestic plumbing, welding pipes and fittings copper by capillarity (tin-silver) instead of silver solder of very high price both in material of contribution as in its execution by qualified personnel;

c) minimum installation cost, not requiring valve connections in the running modes with fairing, and of transport, for the greatest compactness and the lowest number of packages required; Y

d) minimum maintenance cost, limited to Simple supervisions

Claims (12)

1. System of flat solar collectors, through which a heat transfer fluid circulates and which are associated forming a battery of solar collectors, in connection with consumptions or heat exchangers (15) of a heating installation, sanitary hot water or similar, and temperature limiting means, comprising a heat sink (10), arranged in parallel with the solar collectors (1, 1 '), characterized in that both the inlet connection (23) of the heatsink and the return connection (24 ) to it are arranged by the top of the flat solar collectors. 2. Flat solar collector system according to claim 1, characterized in that it comprises at least two flat solar collectors (1, 1 ') arranged in parallel. 3. Flat solar collector system according to claim 2, characterized in that between the outlet of the heatsink (10) and the inlet to the collectors comprises a check valve (9). 4. Flat solar collector system according to claim 2, characterized in that it comprises at least one thermostatic sensor valve (12), incorporated between the heat sink (10) and at least one serial output of the solar collector battery (1 , 1 '), said temperature sensor (17) being incorporated in the middle path of the "T" formed at the outlet of the collector battery. 5. Flat solar collector system according to claim 1, characterized in that it comprises at least two flat solar collectors (1, 1 ') arranged in series. 6. Flat solar collector system according to claim 5, characterized in that between the outlet of the heatsink (10) and the inlet to the collectors comprises a check valve (9). 7. Flat solar collector system according to claim 5, characterized in that it comprises at least one thermostatic sensor valve (12), incorporated between the heat sink (10) and at least one serial output of the solar collector battery (1 , 1 '), said temperature sensor (17) being incorporated in the middle path of the "T" formed at the outlet of the collector battery. 8. Flat solar collector system according to claim 7, characterized in that it comprises at least three flat solar collectors (1) in series, and a corresponding thermostatic valve (12) that communicates the input of each collector (1) of the series with an associated point (25) of the heat sink. 9. Flat solar collector system according to any one of the preceding claims, characterized in that the heat sink is a fin heat exchanger (10) (20). 10. Flat solar collector system, according to any one of the preceding claims, characterized in that the heatsink (10) comprises an enclosing fairing (21) that encloses it. 11. Flat solar collector system according to claim 10, characterized in that said fairing (21) is provided with ventilation openings (22) on at least one of its faces. 12. Flat solar collector system according to claim 10, characterized in that said fairing (21) encloses the check valve (9) and / or thermostatic valve (12).