RU91144U1 - HOT WATER SUPPLY SYSTEM - Google Patents

Abstract

1. A hot water supply system, comprising at least one solar battery, consisting of solar collectors with a heat transfer pipe, a heat storage tank with a coil heat exchanger, hot water pipes, a control unit and measuring devices, characterized in that each solar collector includes a tubular a heat exchanger with circulating water, equipped with a thermometer and internal glasses located in a longitudinal row, the open end of each glass is directed outward, and the shank of the hollow copper tube with a sealed other end and filled with working fluid is fixed to the inner cavity of each glass with the provision of reliable heat transfer, while the body of the copper tube is equipped with external heat bridges made in the form of longitudinal plates located radially along its perimeter, with free longitudinal ends connected thin-walled cylinder, the outer surface of which is provided with a selective coating, while the tube with the cylinder are located inside the stack an evacuated flask, and the gap between the inner diameter of the flask and the outer surface of the cylinder is selected to exclude heat loss by convection and heat conduction from the beam-receiving cylinder into the environment, moreover, one end of the tubular heat exchanger is connected by a supply pipe to a tubular coil heat exchanger, and the second end is a discharge a pipeline with the same tubular coil heat exchanger built into the storage tank, equipped with inlet and outlet pipelines, a thermometer

Description

The utility model relates to decentralized heat supply systems using the conversion of solar energy into heat using it to heat water in domestic and industrial conditions and can be used in hot water systems of individual houses (cottages, summer cottages), utilities (hotels, boarding houses, campsites, summer recreation centers and camps, and agricultural production facilities (farms, greenhouses, etc.).

The well-known "Double-circuit heliosystem of hot water", RF patent No. 2045714, class. F24J 2/42, 1992, containing a series-mounted collector field, a heating element of a capacitive heat exchanger and a circulation pump, as well as a heated water circuit with a backup heater, the annular space of a high-speed heat exchanger. The disadvantage of this design is its low efficiency and design complexity.

The well-known "Solar Heating System", RF patent No. 2187050, class. F24J 2/42, 2001, containing solar collectors, a storage tank with a heat exchanger located in it, a pump for pumping the coolant, the corresponding pipelines with shut-off elements and devices. The disadvantage of this system is its low profitability and the lack of possibility in the warm season without a pump. Due to the natural circulation of the coolant when it is heated.

The well-known "Combined heating system with a solar installation of hot heat supply", patent of the Russian Federation No. 2110017, class. F24D 3/08, 1993, containing an expansion tank-accumulator, a built-in tubular water heater for the heating system in winter, a solar energy collector, a piping system with locked-control equipment, and a circulation pump. However, this system is very complex due to the use of two sources of heat: heated flue gases and solar energy collectors.

The closest technical solution is "Hot water supply gel", RF patent No. 2268444, F24D 15/00, 2005, containing at least one solar cell from heat collectors with transverse tubes for a liquid coolant, connected by a pipeline to a heat storage tank, heating system and hot water system equipped with serpentine heat exchanger, temperature sensors, circulation pump. However, this technical solution has low thermal efficiency due to the metal housings, the complexity of collector designs, as well as the entire installation, since a software device and a tracking mechanism for the perpendicularity of solar radiation panels are required.

The objective of the claimed utility model is to increase the thermal efficiency of the system, as well as reducing its cost by simplifying its design.

This object is achieved in that in a hot water supply system including at least one solar battery, consisting of solar collectors with a heat transfer pipe, a heat storage tank with a coil heat exchanger, hot water supply pipelines, a control unit and measuring devices, characterized in that each solar collector includes a tubular heat exchanger with circulating water, equipped with a thermometer and inner glasses located in a longitudinal row, open The end face of each glass is directed outward, and the shank of the hollow copper pipe with a sealed other end and filled with working fluid is fixed in the internal cavity of each glass with reliable heat transfer, while the body of the copper pipe is equipped with external heat bridges made in the form of longitudinal plates located radially around its perimeter moreover, the free longitudinal ends are connected by an enclosing beam-sensing thin-walled cylinder, the outer surface of which is provided with a selective coating, while a tube with a female cylinder is located inside a glass evacuated flask, and the gap between the inner diameter of the flask and the outer surface of the cylinder is selected to exclude heat loss both by convection and heat conduction from the beam-receiving cylinder into the environment, with one end of the tubular heat exchanger connected to a tubular coil heat exchanger, and the second end - the discharge pipe with the same tubular coil heat exchanger built into the storage tank OP equipped with inlet and outlet pipelines, a thermometer interacting with a controller configured to measure and compare the measured temperatures in the tubular heat exchanger and the storage tank, with the subsequent inclusion of an additional electric heater for the storage tank to ensure a given temperature in the system, and in the supply pipe installed, equipped with a switch-on sensor from the controller, a pumping station with an expansion tank. The battery tank can be dual-circuit.

The system can be equipped with additional equipment, such as a distributor, for supplying water from the storage tank to other buildings or a heating system and other heat-consuming objects. The tubular heat exchanger and the tubular coil heat exchanger are filled with a non-freezing fluid, such as an alcohol-containing fluid.

The storage tank can be equipped with a stratification device that ensures the exclusion of convection movement of the liquid along its height.

Figure 1 presents a diagram of a hot water supply system, figure 2 - the device of the solar collector.

The hot water supply system contains a solar battery 1, including solar collectors 2 installed in a tubular heat exchanger 3 with circulating water. The tubular heat exchanger is equipped with a thermometer 4 and inner glasses 5 arranged in a row, so that the open end 6 faces outward. Hollow copper tubes 9 are fixed into the inner cavity 7 of each of the glasses 5 by their shanks 8. Each copper tube 9 is made with a sealed bottom end 10, filled with a working fluid, and its body is provided with external ash bridges 11 made in the form of longitudinal plates, mounted on the body the tubes are radial, and the longitudinal ends of all the plates are connected by a thin-walled cylinder 12 enclosing a luminosensing cylinder, the outer surface of which is coated with a selective coating. The tube 9 with the cylinder 12 are located with a gap in the glass evacuated flask 13, and the gap "a" between the inner diameter of the flask and the outer surface of the cylinder is selected from the condition for eliminating heat loss, both convection and heat conduction into the environment. The ends of the tubular heat exchanger 3 are connected by a supply pipe 14 and a discharge pipe 15 with a tubular coil heat exchanger 16 integrated in the storage tank 17. In the supply pipe 14 to the tubular heat exchanger from the tubular coil heat exchanger, a pump station 18 is installed with a sensor 19 and an expansion tank 20 moreover, the pumping station 18 is connected to the controller 21, which also interacts with the thermometer 4 of the tubular heat exchanger 3. The tank battery 17 is equipped with an inlet pipe 22 of cold water and an outlet pipe hot water house 23, a thermometer 24, an additional electric heater 25, also associated with the controller 21. In addition, the storage tank is equipped with a stratification device 26, which is usually located above the tubular coil heat exchanger 16 and which eliminates the convective movement of liquid along the height of the storage tank 17. To provide a reliable supply of hot water, both the tubular heat exchanger 3 and the tubular coil heat exchanger 16 are filled with a non-freezing liquid, for example, an alcohol-containing liquid.

The proposed hot water system works as follows. The solar collector 1 is installed on the roof of the building or on a special frame at an angle of 30-45 degrees to the horizon, and all other elements of the system are placed in any convenient place of the premises. When the sun enters the solar collectors, the working fluid in the copper tubes evaporates and the steam rises through the copper tube into the shank, where it condenses and gives off heat through a glass of liquid circulating in the tubular heat exchanger 2. The heated fluid through the discharge pipe 15 enters the tubular coil heat exchanger 16, where transfers heat to the liquid located in the storage tank 17, from where the already heated water enters the consumer to various heat-consuming objects, distributed in the distributor 27. Thanks Alice controller and interacting with him thermometers tubular heat exchanger 3 of the solar collector, storage tank 17 and the pumping station 18 is provided with a positive temperature gradient in a tubular heat exchanger 3, the forced circulation of fluid in conduits 14, 15 of the pump station.

Thanks to the implementation of solar collectors in the form of round-shaped bulbs, a higher efficiency of solar energy perception by solar collectors, and, therefore, the entire solar battery, is provided, since the location of the solar battery with respect to changing its direction of the sun is not required.

The proposed hot water supply system makes it possible to increase the efficiency of converting solar energy into heat and the efficiency of its use due to the implementation of the bulb, which eliminates losses, both convection and thermal conductivity. The presence of the controller also improves the operating characteristics of the system, since it provides measurement and control of temperature parameters and, if necessary, namely, with a positive temperature gradient in the tubular heat exchanger 3, forced circulation of water is activated by means of the pump station 18. If the solar battery in the storage tank is not heated enough, according to the readings of the thermometer located in it, the controller includes additional water heating by an electric heater 25.

The proposed station is simple in design, easy to operate, it has been tested in operation, and has shown efficiency and reliability in operation.

Claims (4)

1. A hot water supply system, comprising at least one solar battery, consisting of solar collectors with a heat transfer pipe, a heat storage tank with a coil heat exchanger, hot water pipes, a control unit and measuring devices, characterized in that each solar collector includes a tubular a heat exchanger with circulating water, equipped with a thermometer and internal glasses located in a longitudinal row, the open end of each glass is directed outward, and the shank of the hollow copper tube with a sealed other end and filled with working fluid is fixed to the inner cavity of each glass with the provision of reliable heat transfer, while the body of the copper tube is equipped with external heat bridges made in the form of longitudinal plates located radially along its perimeter, with free longitudinal ends connected thin-walled cylinder, the outer surface of which is provided with a selective coating, while the tube with the cylinder are located inside the stack a vacuum flask, the gap between the inner diameter of the flask and the outer surface of the cylinder selected from the condition for eliminating heat loss by convection and heat conduction from the radiation receiving cylinder into the environment, with one end of the tubular heat exchanger connected by a supply pipe to a tubular coil heat exchanger, and the second end to a discharge a pipeline with the same tubular coil heat exchanger built into the storage tank, equipped with inlet and outlet pipelines, a thermometer ohm, interacting with the controller, configured to measure and compare the measured temperatures in the tubular heat exchanger and the storage tank with the subsequent inclusion of an additional electric heater for the storage tank to ensure a predetermined temperature in the system, and a pump station equipped with a sensor for switching on from the controller expansion tank. 2. The system according to claim 1, characterized in that it can be equipped with additional equipment, for example a distributor, for supplying water from the storage tank to other buildings or a heating system and other heat-consuming objects. 3. The system according to claim 1, characterized in that the tubular heat exchanger and the tubular coil heat exchanger are filled with a non-freezing liquid, for example an alcohol-containing liquid. 4. The system according to claim 1, characterized in that the storage tank can be equipped with a stratification device, ensuring the exclusion of convective movement of the liquid along its height.