AT515807A4 - Generation of vacuum using solar thermal to pump water - Google Patents

Abstract

The invention relates to a solar-powered water pump, comprising a solar collector for generating heated water, a fresh water reservoir (2) with a steam chamber (3) and a suction chamber (4), wherein between the steam chamber (3) and the suction chamber (4) has a movable membrane (5) is arranged, a connected to the steam chamber (3) via a steam line evaporator (17), which is acted upon to produce steam with the water heated by the solar collector, a supply line for the water to be pumped, a derivative for the pumped Water, wherein in the steam chamber (3) a fresh water vapor condenser (7) is provided for condensing the water vapor, which is connected on the one hand to the supply line and on the other hand with the suction chamber (4), so that the water to be pumped through the fresh water vapor condenser (7) and through the suction chamber (4) flows, wherein in the suction chamber (4) the discharge is arranged above a predetermined level, so that after Carrying out a pumping process always a residual amount of water in the suction chamber (4) remains.

Description

The invention relates to a solar-thermal powered water pump.

The system sucks water into the fresh water tank using a vacuum created by evaporation and condensation.

The system consists of: 1. Fresh water storage:

This has the shape of an upright circular cylinder and is covered with a thermal insulation and an aluminum sheath. The volume of the fresh water reservoir includes the water, the steam condenser, the valves and the controllers. Through a temperature-resistant membrane layer, the memory, air- and waterproof divided into two parts (steam and suction chambers). This membrane layer is attached to condensation channels on the storage wall. These, in turn, are mounted with a slope to the circular area so that the condensate can be returned to the steam separator. The suction chamber (the lower part of the fresh water reservoir) must be large enough to hold the required water and valves. The steam chamber (the upper part of the fresh water reservoir) is used for pressure and vacuum generation by evaporation and condensation. It includes the steam condenser, the steam supply and the condenser discharge, taking into account that this part is air and watertight divided by a steel plate and used as a flat capacitor. The cooling water lands on the flat capacitor and is used as a heat sink, where there is a pressure difference between the space above the flat capacitor and the steam chamber (the space below the flat capacitor).

The fresh water line is equipped with a non-return flap and connected to the steam condenser inlet in the steam chamber. At the condenser outlet, the fresh water line is continued outside the store into the lower part.

The steam condenser consists of inclined, equal length, parallel guided copper smooth tubes with manifolds as inlets and outlets at both ends.

Attached to the steel jacket of the fresh water storage tank is a heating coil consisting of a spiral steel water-flow channel with a three-way valve. The three-way valve is controlled by a capillary tube thermostat, which is dependent on the return temperature of the cooling water.

The fresh water is forwarded from the fresh water storage tank to the cold and hot water storage tanks by means of a check valve installed in the fresh water storage tank with a float.

In both reservoirs, a valve is installed with a float which regulates the incoming water quantity.

A ventilation line ventilates the suction chamber when water is removed.

The floats of the water and ventilation pipes are controlled in parallel. They are prevented from flaring by a mechanical interlocking solenoid until the incoming water has reached a pre-set water level.

Once this is the case, a float, which is mounted at a certain height in the suction chamber, drives and triggers a mechanism that pulls the latch away from the lower float. This immediately drives up, opening the water and ventilation valves. The valves are open until the reservoir is completely empty and the process is repeated.

Two exhaust air and sewage pipes, each with an airtight non-return valve, are connected to the lower part of the suction chamber. The exhaust duct allows the air to escape from the lower chamber of the fresh water storage to the environment during the evaporation phase. Subsequently, the sewer pipe passes the desired amount of residual water to the cooling water storage. This process is controlled by a switching mechanism in the air separator. It consists of two shut-off valves that are switched by a float. The check valves mentioned above prevent the ingress of air during the conditioning phase. 2. Solar collectors

This consists of flat collectors with harp-shaped absorbers, the water flowing in the same direction in all the tubes of the absorber through the collectors.

The water heated by the energy radiation is directed to the hot water manifold through the upper port of the parallel connected collectors. The cooled water returns from the hot water manifold into the collectors through the lower port.

A radiator, which applies the same power of the collectors, is connected in parallel to the heating water distributor and equipped with a control valve. This in turn is controlled by a capillary tube thermostat. When a preset temperature is exceeded at the upper collector output, the valve is opened in proportion to the temperature gradient. The return line from the heater to the manifold is equipped with an expansion vessel.

The transfer between the heating coil in the hot water tank and the fresh water supply system is made by 2 thermostatic three-way valves. One of these valves is fitted with a capillary tube thermostat whose sensor is fixed to the end of an angular funnel. This funnel allows the sun's rays to reach the probe every day for only a certain amount of time, thus warming it up. When the probe is heated, the valve is opened allowing the process to begin. The heat from the water flowing through it keeps the valve open until the flow of water from the other series-mounted three-way valve, which is controlled by the temperature of the heated cooling water. is prevented, the sensor cools and the valve is switched again.

The evaporator is also in the form of an upright circular cylinder, and is covered with a thermal insulation and an aluminum sheath. It is connected to the steam chamber by means of a steam and a condensed water line. The escaping steam is conducted from the steam line into the steam chamber and thus separated from the still unevaporated water. The condensed water line returns the condensed water from the condensate channels to the evaporator. A float valve is attached to the two steam lines, which is closed as soon as the water level drops below a pre-set level.

In the evaporator there is a heating coil, through which, through the solar collectors heated, water flows. It is connected to the hot water manifold with flow controlled by two valves mounted in series. One of these valves is located in the evaporator and is controlled by a float. The second is a three-way valve which switches between the fresh water heating coil and the heater in the evaporator. This process is controlled by a capillary tube thermostat, which depends on the return temperature of the fresh water heating coil.

Also located in the evaporator is a spiral-shaped, smooth-tube cooling coil, which is submerged and connected to the cooling water reservoir. Its job is to cool the rest of the hot water in the evaporator.

The cooling water reservoir has the shape of a horizontal cuboid, and is divided into three spaces by non-ceiling partitions. These are filled by a line running over them, with water pressed out of the fresh water reservoir. The inflow of water is controlled separately for each room by a float valve.

At the bottom of each room is a, with a float, valve that controls the drain. With the help of the upper float, the valve is then opened when the water has reached a pre-set level. The valve remains open with the lower float until the space is empty.

Two chambers of the cooling water accumulator are connected to the flat steam condenser and the fresh water storage jacket cooling coil, respectively, by means of check valves.

The heated cooling water is passed separately from the evaporator cooling coil or from the fresh water storage jacket cooling coil in each case into a steam separator, where the steam is separated from the water. The flow of water is controlled by a control valve controlled by a capillary tube thermostat. This thermostat is in turn controlled by the temperature of the flowing water.

From the third chamber, the water is directed into the flat condenser, where it receives condenser heat and is further directed through a conduit equipped with a thermostatic control valve into the hot water storage tank in parallel with the other cooling water outlets.

The exhaust steam is passed from the steam separators and the flat condenser to the hot water storage tank to condense there and deliver its heat to the hot water.

process flow

The water heated by the collectors is passed through three-way valve-1 into three-way valve-2 which carries the water further into the hot water storage heater coil for the water to heat the storage water there. Then it returns to the collectors and the cycle repeats.

The process begins with the sun reaching a certain angle where the sunbeams can penetrate the funnels. The sensor is heated by solar radiation and switches the three-way valve-2. By switching, the water continues to be passed through three-way valve-3 into the fresh water storage jacket heater to heat the fresh water tank itself. The cooled water subsequently returns to the collectors.

This cycle continues until the fresh water storage has reached the desired temperature and the return temperature of the water has reached a certain level. The valve is switched by the capillary tube thermostat so that the water flows from the collectors into the evaporator heater coil, heats the water in the evaporator, and thus also the evaporator, and then back to the collectors. The evaporating water in the evaporator is passed through a steam line into the steam chamber.

The incoming steam does not condense due to the high temperature of the fresh water storage and because of the overpressure of the steam, the membrane is expanded into the suction chamber. As a result, the air escapes from the suction chamber due to the pressure through the air separator to the environment. By expanding the membrane and by venting all the air, the water spud rises in the air separator, switching a float, which is coupled to two flaps, between the air and water drains. Then the rest of the

Water due to the overpressure in the cooling water tank, where it fills three chambers. The filling of each individual chamber is adjusted by a float when the water in the respective chamber reaches a certain level.

When the water level in the evaporator drops to a pre-set level due to evaporation, a valve controlled by a float prevents further flow of hot water from the collectors through the evaporator heater register, thus stopping evaporation.

When the cooling water in the cooling water storage chambers reaches a predetermined level, valves are opened with a float. These valves are installed in each chamber and are open until the chamber is empty.

The water in chamber-1 is directed into the fresh water storage tank to land thereon on the flat condenser to absorb the surrounding heat. Due to the sinking of the temperature, the vapor condenses in the steam chamber. The vapor arising from contact of the water with the hot surface above the flat condenser is directed into the hot water storage tank via a steam discharge, as mentioned. When the remaining water reaches a predetermined temperature, a thermostatic valve is opened to guide the warmed water into the hot water storage tank.

When the valve in chamber-2 is opened, the water flows into the fresh water storage jacket cooling coil, which runs around the fresh water storage body in a spiral pattern. As it cools, its temperature rises to be directed into the steam separator. A portion of the water which had evaporated in the first time in contact with the hot surfaces in the cooling register rises immediately in the form of steam and is thus separated from the water. A thermostatic valve is opened as soon as the temperature of the water flowing into the separator drops to a certain degree. Through a manifold, the water in the separator is fed into the hot water tank.

The cooling water flowing from the cooling water storage chamber 3 is led into the evaporator cooling register to receive heat there and to flow further into the steam separator-2. While the water is in the evaporator, part of the water evaporates during the first heat uptake, and then rises in steam separator-2 to be sent to the hot water tank via a steam line. The water remaining in the steam separator accumulates until it cools to a certain degree in the cooling water and a * thermostatic valve allows the flow of the water. The warmed water flows from the steam separator into a manifold in the hot water tank.

At the end of the process, the steam condensed in the steam chamber is returned to the evaporator via the inclined condensing channel through the likewise inclined condensation drainage.

When the air and the cooling water are discharged via the air separator and by the condensation of the steam, a low pressure is created in the suction chamber.

Due to the pressure difference between the atmospheric pressure and the low pressure in the suction chamber, the fresh water is pumped through the fresh water line via the fresh water vapor condenser into the suction chamber. Due to the low temperature of the fresh water, the remaining steam in the steam chamber condenses on the fresh water vapor condenser.

When the hot water tank is filled, there is a possibility to remove warm water.

PATENTANPRÜCHE

Claims (10)

Claims 1. A solar powered water pump comprising a. a solar collector for producing heated water, b. a fresh water storage (2) i. with a steam chamber (3) and a suction chamber (4), ii. wherein between the steam chamber (3) and the suction chamber (4), a movable membrane (5) is arranged, c. a steam generator (17) connected to the steam chamber (3) via a steam line, to be acted upon by the water heated by the solar collector to produce steam; d. a supply line for the water to be pumped, e. a discharge for the water to be pumped, characterized in that - in the steam chamber (3) a fresh water vapor condenser (7) is provided for condensing the water vapor, o connected on the one hand to the supply line and on the other hand to the suction chamber (4), o the fresh water vapor condenser (7) flows through the water to be pumped and is passed through the suction chamber (4), wherein in the suction chamber (4) the discharge is arranged above a predetermined level, so that a residual amount of water in the suction chamber (4) is present after a pumping operation has been carried out. remains. 2. Water pump according to claim 1, characterized in that a cooling water reservoir (13) having three chambers (14, 15, 16) is provided, which via an air separator (10) of the suction chamber (4) with that in the suction chamber (4) after the implementation a pumping water is acted upon. A water pump according to claim 2, characterized in that the three chambers (14, 15, 16) have float-controlled valves so that as the water is introduced into the cooling-water reservoir (13), one chamber after another is filled. 4. Water pump according to claim 2 or 3, characterized in that in the steam chamber (3) a flat capacitor (6) for condensation of the steam is arranged, which is acted upon by a first chamber (14) of the cooling water reservoir (13) with water. 5. Water pump according to one of claims 1 to 4, characterized in that in the suction chamber (4) a heating register (8) is provided, which is acted upon by a valve (20) with the heated water from the solar collector to the fresh water tank (2). bring to operating temperature. 6. Water pump according to one of claims 2 to 5, characterized in that in the suction chamber (4) a jacket cooling coil (9) is provided, which via a second chamber (15) of the cooling water tank (13) is Wasserbeaufschlagbar to the fresh water tank (2 ) to cool. 7. Water pump according to one of claims 2 to 6, characterized in that the third chamber (16) of the cooling water reservoir (13) with the evaporator (17) is connectable. 8. Water pump according to one of claims 1 to 7, characterized in that a cold water tank (11) and a hot water tank (12) are provided, which are connected to the drain. A water pump according to claim 8, characterized in that a first steam separator (24) and a second steam separator (25) are provided which collect the water from the jacket cooling coil (9) and the evaporator (17) and direct it into the hot water tank (12). 10. Water pump according to one of claims 1 to 9, characterized in that the fresh water reservoir (2) is designed as an upright cylinder, the fresh water vapor condenser (7), the heating coil (8) and the jacket cooling register (9) are arranged on the lateral surface of the cylinder.