RU2213912C2 - Solar power complex - Google Patents

Abstract

FIELD: solar power engineering, namely plants for producing heat, cold and electric energy by means of solar energy. SUBSTANCE: complex includes helioreceiver having heliocoating with ducts separated by means of cross partitions forming lifting steps and made of porous material with height equal to height of liquid rising in capillary tube and hollow vapor chambers with height equal to diameter of vapor bubble. Said ducts are provided with lower collector and upper drum. Complex also includes ejector, condenser, heat accumulator, evaporator, cold accumulator, throttle, turbo-generator with condenser mutually connected through pipeline system with hydraulic lock. Turbo-generator is connected with electric power accumulator. EFFECT: enlarged functional possibilities, enhanced efficiency. 1 dwg

Description

 The present invention relates to solar technology, in particular to means for generating heat, cold and electricity using solar energy.

 A known system of solar heat supply to a building, containing a solar receiver, a heat accumulator associated with it through direct and return pipelines, a heat transfer heat exchanger, a circulation pump controlling a movable screen, an ejector installed in an air volume of a heat accumulator, shut-off and control valves [1].

 The disadvantages of the known device include the presence of a circulation pump and a control screen, which reduces the efficiency and efficiency of the device, as well as the dependence of the temperature of the cooled agent on the temperature of the outside air, which limits the parameters of the resulting energy source.

 Closer to the proposed device is a solar air conditioning installation, consisting of a solar collector made of a solar coating with channels for a coolant, circulation pump, compressor, evaporator, condenser, heat accumulator, choke, heat exchangers, shut-off and control equipment (magnetic valves), connected between a piping system that operates in the mode of receiving heat in the cold period and in the mode of receiving cold in the warm period [2, p. 323].

 The disadvantages of the known device are the need to use a circulation pump and compressor, which complicates its design, reduces efficiency and reliability, as well as the inability to simultaneously receive different types of energy: heat, cold, electricity, which limits the functional range of the device.

 The problem to which the invention is directed, is to increase the efficiency of use of solar energy and expand the functionality of the device.

 The task is realized in a solar energy complex containing a solar receiver made of heliocoating with channels that are separated by transverse partitions forming lifting steps made of a porous material with pores in the form of vertical conical capillaries facing the top of a truncated cone with a height equal to or less than the height liquid lifting by surface tension, and hollow steam chambers with a height equal to the diameter of the vapor bubble of the working fluid, and the lower and upper ends the channels of the solar collector are equipped with a lower collector and an upper drum, respectively, an ejector, a condenser, a heat accumulator, an evaporator, a cold accumulator, a choke, a turbogenerator with a condenser, interconnected by a piping system equipped with shut-off and control equipment and a water trap, the turbogenerator being connected by an electric wire to an electric battery .

 The technical result of the invention is the simultaneous production by means of solar energy of heat, cold and electricity.

The drawing shows the proposed solar energy complex. The Solar Energy Complex (SEC) contains a solar receiver 1, consisting of a solar coating 2, channels 3 for circulating the working fluid (vapor-liquid mixture), which are separated by transverse partitions forming lifting steps 4, made of a porous material with pores in the form of vertical conical capillaries 5 with a height equal to H ₁ , and hollow steam chambers with a height equal to H ₂ , the lower and upper ends of the channels 3 of the solar receiver 1 are connected to the lower manifold 7 and the upper drum 8, respectively, which in turn is connected by a pipe wires through a valve 9 with an ejector 10, a condenser 11, a heat accumulator 12, an evaporator 13, a cold accumulator 14 and through a choke 15 and a water trap 16 of height h with a lower manifold 7, and through a valve 17 with a turbogenerator 18 and a condenser 19, also connected to the rest a piping system, the turbogenerator 18 being connected by an electric wire to the electric battery 20.

где σ - коэффициент поверхностного натяжения, Н/м;
r' - средний радиус кривизны мениска жидкости в капилляре, м;
и подъем жидкости за счет этого давления на высоту (принятую за высоту ступени подъема)

где g - ускорение свободного падения, м/с²;
θ - угол смачивания, град;
r - радиус капилляра, м;
r=r'cosθ (в случае полного смачивания cosθ=1).The work of the proposed SEC, along with the use of solar energy, the principles of operation of an ejector chiller and a turbogenerator, is based on the property of a liquid to create capillary pressure in capillaries, determined by the Laplace formula

where σ is the coefficient of surface tension, N / m;
r 'is the average radius of curvature of the meniscus of the liquid in the capillary, m;
and the rise of the liquid due to this pressure to a height (taken as the height of the lifting stage)

where g is the acceleration of gravity, m / s ² ;
θ is the wetting angle, deg;
r is the radius of the capillary, m;
r = r'cosθ (in the case of complete wetting, cosθ = 1).

To ensure the movement of the vapor-liquid mixture in the lifting stage 4 only upward, the capillaries 5 must have a positive capillary potential, for which they are made in the form of vertical truncated cones (the lower radius r _{1 is} greater than the upper radius r ₂ [3, p. 303, 304].

где d₀ - диаметр пузырька пара, м;
f - частота образования пузырьков пара, 1/с;
ρ′, ρ″ - плотность жидкости и пара, соответственно, кг/м³ [4, с. 153], размер которого принят за расстояние Н₂ между ступенями подъема жидкости 4 и, соответственно, высоту паровой камеры 6.To ensure the rise of the vapor-liquid mixture and increase the vapor pressure in the channels 3 of the solar receiver 1 from the pressure of the working fluid P _to the I-th stage 4 to the pressure P ₀ at the top, a step-wise rise of the vapor-liquid mixture to a height of H ₁ at each stage 4 is provided, for which the input in the capillaries 5 of each lifting step 4, a free surface of the liquid is created due to its ability to form vapor bubbles with a diameter when boiling

where d ₀ is the diameter of the vapor bubble, m;
f is the frequency of formation of vapor bubbles, 1 / s;
ρ ′, ρ ″ - the density of the liquid and vapor, respectively, kg / m ³ [4, p. 153], the size of which is taken as the distance H ₂ between the steps of raising the liquid 4 and, accordingly, the height of the steam chamber 6.

 Water, ammonia, various types of freons can be used as the working fluid of SEC, depending on the purpose of the resulting steam and the parameters of the coolant.

 SEC works as follows.

Before starting work, the SEC circuit is filled so that the lifting stages 4, the steam chambers 6 in the channels 3 of the solar receiver 1 are filled until the upper drum 8 is half full. As the solar receiver 1 is heated, the working fluid heats up and starts to move upward in the channels 3, and in the circulation the loop formed in a downward conduit with a hydraulic lock 16, which provides resistance to the height h equal to the difference of the operating pressures within the upper drum 8, R ₁ and the capacitor 11, P ₂ and condensate from the throttle portion 15 BC lower pole collector 7, down due to F _e natural circulation pressure forces similar to the movement of liquid coolant in the heating [5, p. 300], thereby creating a general fluid movement in the circulation circuit of the solar receiver 1 and releasing steam from the heated fluid. As the working fluid heats up at the walls of the channels 3 adjacent to the helium-receiving coating 2, it begins to boil, which entails the formation of steam bubbles, which are localized in the steam chambers 6, whose height H ₂ is determined by the diameter of the vapor bubble d ₀ and is determined by the equation ( 3). In this case, part of the steam chambers 6, remote from the solar coating 2, is still filled with a working fluid, and here the fluid continues to move due to the natural circulation pressure P _e . With increasing heat fluxes from the solar coating 2, the width of the vapor layer in the steam chambers 6 increases to a value of S, the value of which is taken depending on the intensity of solar radiation and the properties of the solar coating 2.

The vapor interlayers in the steam chambers 6 cause the free surface of the liquid formed by the outer film of the vapor bubble at the entrance to each stage of the rise 4 and, accordingly, at the entrance to each capillary 5, thereby ensuring the rise of the vapor mixture due to capillary forces in each stage of the rise 4 through capillaries 5, which form a cone tapering towards the top with radii r ₁ and r _2, respectively, determines the movement of vapor-liquid mixture only upwards towards the apex of the cone (cone angle of received recommendation Tapered nozzles [6, p. 298]. Thus in the capillaries 5 creates a capillary pressure that allows to raise vapor-liquid mixture in each stage 4 to a height less than or equal to H _1, defined by formula (2) and the updated value is taken for As a result, the pressure in each of the next stage 4 increases compared with the pressure in the previous stage by the capillary pressure P _c determined by formula (1), and thus, the vapor pressure at the outlet of the drum 8 will be greater than the pressure by the liquid inlet to the lower collector 7 of the solar receiver 1 by the amount
ΔP = P _c n ... (4),
where n is the number of steps of capillary rise, pcs.

The total vapor pressure P ₁ at the output of the upper drum 8 will be equal to
P ₁ = P _to + ΔP ... (5),
where p _k is the fluid pressure at the inlet to the lower manifold 7.

 The transfer of liquid and steam in the steam chambers 6 from the upper surface of the lower stage of rise 4 to the lower surface of the upper stage 10 and, accordingly, to the entrance to the capillaries 11 is carried out by diffusion and convection in accordance with the law of heat and mass transfer [7, p. 132, 262].

Then, in the upper drum at a pressure of P ₁ , steam is released from the vapor-liquid mixture, which is divided into two parts, and the separated liquid is lowered into the circulation circuit. In this case, one part of the obtained steam from the upper part of the drum 8 through the control valve 9 enters the ejector 10, which sucks the secondary steam from the evaporator 13, creating a vacuum P _{3 there} and reducing the pressure to P ₂ , from where the steam goes to the condenser 11, where it is conditioned, giving condensation heat the coolant that is directed to the consumer and in the heat accumulator 12 and the resulting condensate _to a pressure P ₂ ≈R (excluding resistances) enters partly into the lower reservoir 7, mixed in the circulation circuit with a boiler zhidkos Strongly and partly via the throttle 15, which is throttled to vacuum pressure P _3, the evaporator 13 where at rarefaction R _3, reduced working fluid boiling point occurs its evaporation at low temperature to form the vapor sucked in the ejector 10, cooling the refrigerant, which is then sent to the consumer and into the cold accumulator 14.

Another part of the obtained steam with a pressure P ₁ from the upper drum 8 is sent through an adjustment valve 17 to a turbogenerator 18 that generates an electric current, which is sent to the consumer and to an electric accumulator 20, and the “crushed steam” after the turbogenerator 18 with a pressure P ₃ enters the condenser 19 where it condenses, giving off heat to the coolant sent further to the heat accumulator 12, the condensate formed is mixed with the rest of the condensate entering the evaporator 13 after the inductor 15.

 The quantity and parameters of steam received in the solar collector 1 and, accordingly, the quantity and parameters of all types of energy generated by the solar collectors depend on the intensity of solar radiation, the number of lifting steps 4 and their cross-sectional area in the channels 3 of the solar collector 1, the quantitative and qualitative characteristics of the solar collector 2 and other equipment, as well as the properties of the working fluid.

 Thus, the proposed SEC provides the simultaneous production of heat, cold and electricity using surface tension forces, which increases efficiency and extends the range of application of solar energy.

Sources of information
1. A.S. USSR 1657895, M.cl. F 24 J 2/42, 1991.

 2. V.N. Bogoslovsky et al. Air conditioning and refrigeration. M .: Stroyizdat, 1985, 367 p.

 3. A.V. Lykov, Heat and mass transfer. Directory. M .: Energy, 1978, 480 p.

 4. A.M. Kutepov et al. Hydrodynamics and heat transfer during vaporization. M.: Higher. School, 1977, 352 pp.

 5. V.N. Bogoslovsky, A.N. Scanawi. Heating. M .: Stroyizdat, 1991, 736 tf.

 6. A. D. Altshul, P.G. Kiselev. Hydraulics and aerodynamics. M .: Stroyizdat, 1975, 328 p.

 7. A.I. Planovsky, P.I. Nikolaev. Processes and devices of chemical and petrochemical technology. M .: Chemistry, 1972, 496 p.

Claims (1)

 Solar energy complex containing a solar collector, consisting of a solar coating with channels, an evaporator, a condenser, a heat accumulator, a throttle, an ejector, interconnected by a piping system with shut-off and control valves, characterized in that the solar collector channels are separated by transverse partitions forming lifting steps, made from a porous material, with pores in the form of vertical conical capillaries facing the top of a truncated cone, a height equal to or less than the height of the liquid by forces of surface tension, and hollow steam chambers with a height equal to the diameter of the steam bubble of the working fluid, the lower and upper ends of the channels are equipped with a lower collector and an upper drum, respectively, connected to other equipment, which also includes a cold accumulator, a turbogenerator with a condenser, a piping system with a water lock, and the turbogenerator is connected by an electric wire to an electric battery.