SK5397Y1 - Water cooler for industrial technologies - Google Patents

Abstract

Cooler is composed of hot water inlet (3), large-capacity tank (1) with cooling water, cooling water outlet (2) and of heat pump consisting of heat exchanger (4) encased in a cooling water of tank (1), which is linked to the outer pipe (5) and the inner pipe (6) with an evaporator (7). Inside the evaporator (7) are mounted evaporator pipes (8) with outlets connected through the compressor (9) with an electric motor (M), condenser tube (11) of condenser (14) and injection reduction valve (10), wherein pipes are filled with working medium and the condenser (14) is equipped with a pressure inlet pipe (13) of cold water and outlet pipe (12) of heat water. The large-capacity tank (1) may be at least partially covered. The cooling water outlet (2) of the tank (1) may be connected with the pressure inlet pipe (13) of cold water into the condenser (14), which outlet pipe (12) of heat water is connected to the feed water boiler with a heat source, while in the pressure pipe (13) can be equipped with at least one water pump.

Description

Technical field

The technical solution concerns a water cooler, especially industrial technologies used for electricity production in thermal and atomic power plants, heating plants, rendering plants, sugar refineries, ingot casting cooling and the like.

BACKGROUND OF THE INVENTION

It is currently known to cool hot water in a large-capacity cooling water tank, in which hot water flows through the inlet and at the same time cooled water flows out of its outlet. Cooling the water in the bulk tank is only the surface of the tank and from the water surface. Effective water cooling for industrial technologies with the required temperature and quantity of chilled water therefore requires the use of a large bulk tank with maximum internal surface, e.g. Lake. However, the formation of such a large-volume tank is costly and operationally expensive. Therefore, such a technical solution is used only minimally. A major disadvantage of this solution is that all the heat energy from the hot water is lost to the environment without any benefit, thereby reducing the efficiency of fossil and nuclear fuel recovery while significantly adversely affecting the external environment.

In industrial technologies used mainly for the production of electricity in thermal and nuclear power plants, superheated steam is exited from the last stage of a condensing steam turbine which is connected by a shaft to a power generator, i. j. Turbine generator on tubes cooled by cooling water in the condenser turns into water and after heating it returns to the steam generator, resp. into the cooking drum, event. a pressure vessel for separating saturated steam through the boiler feed water supply. The condensation heat from the condenser is thereby transferred by cooling water to the cooling tower, i. j. a heat exchanger in which the heat of the chilled water from the condenser is transferred to the ambient air. The most used are natural draft cooling towers, characterized by a draft chimney made of reinforced concrete hyperboloid mantle, on the surface of which the water supplied is sprayed by nozzles in the form of tiny droplets, which are cooled by the flow of rising heated air. The water slowly flows through these blocks, flows down and falls down into the sump. In more efficient systems, cooling air is driven against the movement of water by the fan, which quickly removes unnecessary heat from it. The cooled water then flows from the sump to the heat recovery technology again. Such a cooling device has an open cooling circuit allowing the steam and small particles of water to escape into the atmosphere. Closed cooling is also known, where the chilled water does not come into contact with the outside air, since it is guided in pipes whose surface is sprayed with cold water from the second circuit of the tower. Also known is the so-called. economical cooling, where the devices work on the principles of hybrid or adiabatic cooling with energy saving. It is a combination of open, closed and dry cooling.

The disadvantage of cooling towers is that they affect the climatic conditions of the vicinity by water in the form of steam and emitted solid particles, which as condensation cores increase the occurrence of precipitation. Especially in the cold season, the high relative humidity in the vicinity increases the probability of condensation of water vapor in the form of fog, drizzle, respectively. rain with subsequent event. ice and icing. Another major disadvantage of such a solution is that a substantial portion of the heat energy from the hot water in the cooling tower is lost to the environment for no benefit, thereby reducing the energy efficiency of the combustion of fossil and nuclear fuels for industrial purposes.

A heat pump is used for heating of industrial buildings and family houses. j. a device that converts the low potential thermal energy of the natural environment into a higher energy level, practically usable, which does not produce any waste products. Its principle is based on the latent transformation of the working medium with low boiling point - coolant in the internal circuit of the heat pump. The apparatus consists of a heat exchanger interconnected by an external and internal conduit with an evaporator, inside which an exhaust pipe with outlets interconnected via an electric compressor, a condenser condenser conduit and an injector reduction valve are mounted, having refrigerant filled in the conduits, i. j. the working medium with a low boiling point and the condenser is equipped with a cold water inlet pipe and a hot water outlet pipe. The temperature of the working medium entering the evaporator is lower than the temperature of the source passing through the evaporator, which causes evaporation of the working medium, whose steam is subsequently compressed to a higher pressure and temperature by the compressor. The saturated steam is fed to a condenser where it transfers useful heat, while the liquid working medium expands to the outlet temperature and pressure via the injector to the evaporator, repeating the entire cycle. The operation of the heat pump is controlled manually or electronically based on the temperature and pressure sensors in the internal circuit of the heat pump. In terms of starting and stopping the heat pump, it operates according to a preset equithermal control curve, which uses sensors to evaluate the actual temperature of the outside air and water in the building's heating system. Such a2

However, the control still does not form part of a water cooler for industrial technologies mainly used for the production of electricity in thermal and nuclear power plants.

The essence of the technical solution

These drawbacks are substantially eliminated by a water cooler, especially industrial technology according to the invention, consisting of a hot water inlet, a large cooling water tank, a chilled water outlet and a heat pump formed by a heat exchanger interconnected by external and internal piping with the evaporator inside. Equipped with outlet piping with outlets interconnected by compressor with electric motor, condenser condenser piping and injection reducing valve. The piping is filled with working medium and the condenser is equipped with pressure cold water supply line and heated water discharge line. The essence of this technical solution is that the heat exchanger of the heat pump is mounted in the cooling water of a large-volume tank.

It is advantageous here that at least a part of the condenser is mounted next to the exchanger in the cooling water of the large-volume tank and that the large-volume tank is at least partially covered.

It is also advantageous if the chilled water outlet from the bulk tank is connected by a cold water pressure supply line to a condenser from which the heated water discharge line is connected to the feed water supply of the heat source boiler, wherein at least one water pump can be mounted in the pressure line.

The device according to the invention only minimally influences the climatic conditions of the near surroundings in the form of steam and emitted solid particles and does not affect the occurrence of near-precipitation in the form of fog, drizzle, resp. rain with subsequent event. ice and icing. The great advantage of the technical solution is that it prevents the leakage of a significant part of the thermal energy from hot water while cooling it into the air and that it subsequently and economically uses it together with renewable solar energy accumulated in the surrounding environment, thereby significantly increasing the efficiency of energy recovery from fossil and nuclear fuels from geothermal springs for industrial purposes. Another benefit of this technical solution is that its heat pump generates a substantially higher temperature in the hot water outlet pipe, such as in the hot water inlet, which allows it to be fed to the steam generator preheater or pressure vessel to separate saturated steam in the heat source. saving fossil or nuclear fuel and reducing the annual operating costs of heating and hot water production without incurring the cost of the necessary fuel heating. In addition, the use of the heat pump in operation does not require extra operation and maintenance and allows the generation of heat without the formation of ash or other gas flue gases. At the same time, the necessary investment input costs are substantially outweighed by the long-term financially lower operating costs for the production of heat from fossil or nuclear fuel and for cheaper building heating and hot water production. The use of technical solutions will positively affect not only the economy, but also from an environmental point of view, it also reduces pollution and increases the protection and recovery of the environment.

BRIEF DESCRIPTION OF THE DRAWINGS

A specific embodiment of the invention is schematically shown in the accompanying drawings, in which FIG. 1 shows an embodiment of a water cooler, in particular of industrial technologies, with a capacitor mounted above the ground in the air, and FIG. 2 shows an embodiment of a water cooler, in particular of industrial technologies, with a capacitor partially mounted in the cooling water next to the exchanger in a large-volume tank.

Examples of technical solution

Basic embodiments of a water cooler, in particular of industrial technologies according to the invention, are shown in FIG. 1 and 2. These devices consist of a hot water inlet 3, a large cooling water tank 1, a chilled water outlet 2 and a heat pump formed by a heat exchanger 4 mounted in the cooling water of the large tank 1, which is interconnected by external piping 5 and internal piping. 6 with an evaporator 7. Inside the evaporator 7 is provided a discharge pipe 8 with outlets interconnected via a compressor 9 with an electric motor M, a condenser conduit 11 of a condenser 14 and an injection reduction valve 10, the working medium being filled in the conduits, e.g. CFC-free refrigerant (R

134 a), difluoro (ledon) ... and the condenser 14 is provided with a cold water supply line 13 and a heated water outlet line 12. The capacitor 14 shown in FIG. 1 is mounted above the terrain in the air and FIG. 2 is partially mounted in the cooling water next to the exchanger 4 in the large-volume tank

SK 5397 Υ1

1. The large-volume tank 1 in FIG. 1 and 2 is formed as an opening in the ground, which may have different shapes, e.g., prisms, cubes, cylinders, natural depressions, lakes and the like. The heat exchanger 4 has a vertical arrangement of tube-shaped tubes in the figures shown.

The large-volume tank 1 is filled with cold cooling water and the hot water produced in the boiler condenser continuously condenses through the inlet 3 after leaving the last stage of the condensing steam turbine, which is connected to the generator by a shaft, t. j. turbine generator and at the same time continuously from outlet 2, e.g. by gravity or by the pressure of a water pump (not shown), the chilled water flows into the known, not shown supply water supply of the boiler of a heat source of industrial technology, e.g. heat or nuclear power plant and the like, while the heat pump used is running. The compressor 9, driven by the electric motor M, sucks the working medium from the evaporator pipe 8, creating a negative pressure and evaporating the working medium while consuming exhaust heat from the exchanger 4, i. j. cooling the cooling water in the bulk tank i. Subsequently, the working medium is compressed by the compressor 9, thereby being heated and forced into the condenser 14 where it is liquefied. Upon liquefaction, it absorbs the absorbed exhaust heat in a known manner from the cold water supply line 13 to the heated water outlet line 12, i. j. e.g. to the system of hot-water heating, etc. The liquefied working medium further flows through the injector 10 and loses pressure as it expands, thereby cooling substantially. Since the working medium is cooler than the heat source in the exchanger 4, it continuously extracts heat from it while cooling the cooling water in the large-volume tank 1 and the working cycle is repeated in the direction of evaporator 7, compressor 9, condenser 14 and pressure reducing valve 10. is controlled in a known manner manually or electronically based on temperature and pressure sensors in the internal circuit of the heat pump. In terms of starting and stopping the heat pump, this device operates according to a preset equithermal control curve, which uses sensors to evaluate the actual temperature of the outside air and water in the building's heating system.

The described and illustrated embodiments are not the only possible solutions according to the utility model, since the heat exchanger may have horizontal or horizontal-vertical, or spiral, respectively. combined arrangement of pipes with different external shapes. The heat exchanger may also form a filler between at least a portion of the double wall of the bulk tank. The large-volume tank can be either partially or completely covered, e.g. lid, foil and the like. Alternatively, the bulk tank may be mounted on or above the ground and may have a different shape, e.g. prisms, cubes, cylinders, balls and the like, with an upper opening which can be either partially or completely covered, e.g. lid, foil and the like. Also, the chilled water outlet from the bulk tank may be connected by a cold water pressure feed line to a condenser from which the hot water drain line is connected to the feed water supply of the heat source boiler, wherein at least one water pump may be mounted in the pressure line. The hot water inlet and the chilled water outlet can be in any position in the large-volume tank.

Industrial usability

The water cooler, especially of industrial technologies according to the technical solution, can be used for heating, air-conditioning and domestic hot water heating in residential buildings, schools, assembly or working areas, swimming pools, office and industrial buildings, even in combination with cooling equipment, eg. in the dairy industry for milk cooling or for drying wood, bricks, linen, foodstuffs and the like.

Claims (5)

PROTECTION REQUIREMENTS 1. A water cooler, in particular industrial technology, comprising a hot water inlet, a large cooling water tank, a chilled water outlet and a heat pump consisting of a heat exchanger interconnected by an external and internal conduit with an evaporator, inside which a discharge conduit is connected to the conduits connected via a compressor with an electric motor, a condenser condenser line and an injector reduction valve, the working medium being filled in the conduits and the condenser being equipped with a cold water supply line and a heated water outlet line, characterized in that the heat pump heat exchanger (4) is mounted in cooling water a large-volume tank (1). Water cooler according to claim 1, characterized in that at least a part of the condenser (14) is mounted next to the exchanger (4) in the cooling water of the bulk tank (1). Water cooler according to claim 1 or 2, characterized in that the large-volume tank (1) is at least partially covered. SK 5397 Υ1 Water cooler according to claim 1 or 2 to 3, characterized in that the cooled water outlet (2) from the bulk tank (1) is connected to the condenser (14) via a cold water pressure line (13). . from which the heated water outlet pipe (12) is connected to the feed water supply of the heat source boiler. Water cooler according to claim 4, characterized in that at least one water pump is mounted in the pressure line (13).