ES2453740B1 - SANITARY HOT WATER PRODUCTION SYSTEM. - Google Patents

Abstract

Domestic hot water production system, comprising a compressor (1), responsible for raising the pressure and temperature of a refrigerant in a gaseous state, a first and a second heat exchanger (3-6), a closed water circuit ( 8) with recirculation valve (10), which passes through the first heat exchanger (3) and through a tank (9) domestic hot water container, and means (4-5) to select the passage of the vapors from the compressor (1) to the first or second heat exchangers (3 - 6).

Description

DESCRIPTION

Domestic hot water production system.

Field of the Invention

The present invention relates to a system for the production of domestic hot water for heat pumps and air conditioning and refrigeration systems, whose operating principle is based on a simple stage steam compression cycle 5 and in which the process of Compression is done by an electrically driven compressor.

Background of the invention

Other domestic hot water production systems are already known for this purpose. Known systems can be classified into 4 groups. The first group includes those systems in which the domestic hot water 10 is produced in a tank equipped with an internal coil through which hot water from the heat pump condenser, the air conditioning system or the water system is circulated refrigeration (system used by most heat pump manufacturers). The second group includes those systems called instantaneous domestic hot water production that consist of using an external heat exchanger in which the domestic water is heated in said exchanger by means of a stream of hot water that is circulated through said exchanger from a tank and, normally, forced by a pump (system normally used in installations with heat pump and other systems such as boilers, solar panels, etc.). The third group includes those systems in which domestic hot water is produced in a tank by means of a coil through which the coolant of the heat pump, the air conditioning system or the cooling system (used in pump) circulates of Panasonic heat and 20 thermodynamic heat pumps). Finally, the fourth group includes those systems in which a superheater exchanger arranged in series with the condenser of the installation is used and in which a portion of the water flow that has already been previously heated in the condenser is heated, which allows to obtain a reduced flow of high temperature water that is sent directly to a reservoir in which domestic hot water is produced, either instantaneously (iDM patent, manufacturer of heat pumps), or by circulation through a coil (Danfoss patent, manufacturer of heat pumps). The two existing systems of this group 4 are characterized in that the flow of water used for the production of domestic hot water circulates first through the condenser and then only a part of this flow circulates through the desheater.

Description of the invention

The present invention aims at a system for the production of domestic hot water, by means of heat pumps and air conditioning and cooling systems.

The installation of the invention is framed within the heat pump systems, whose operating principle is a steam compression system that operates according to a simple compression cycle, in which the compression process is performed by an electrically driven compressor. and that extracts energy in the form of heat from the ground (geothermal) or from the environment (aerothermal) and that yield energy, also in the form of heat, to water that is heated and used for the production of domestic hot water and heating.

The invention also relates to geothermal or aerothermal heat pumps, such as those indicated in the previous paragraph, and which are reversible, that is, by using the appropriate devices, they can reverse their operating cycle, in such a way that extract energy in the form of heat from one or several premises in which it is desired to maintain certain conditions of temperatures and / or humidity and that provide energy in the form of heat to water that is used for the production of domestic hot water.

The invention also relates to air conditioning and refrigeration systems whose operating principle is a steam compression system that operates according to a single or double stage compression cycle, in which the existing compression processes are carried out by means of a driven compressor. electrically and in which all or part of the energy released by the refrigerant, in the condensation process, is transferred in the form of heat to water that is heated and used for the production of domestic hot water.

The invention consists of a domestic hot water production system that is based on the use of two heat exchangers, to carry out the condensation process (de-heating, condensation and sub-cooling) of the refrigerant vapors at high pressure and temperature, leaving the compressor (compressor discharge) and in the use of a closed circuit in which forced water is circulated by means of a recirculating pump 50, such that the water circulating in the closed circuit is heated in the first of the heat exchangers, to which the refrigerant vapors enter directly from the compressor discharge, and which subsequently transfers said heat to the domestic hot water inside a tank, by circulating inside a coil located inside said tank .

For this, according to the invention, the installation comprises a compressor, which is responsible for raising the pressure and temperature of a refrigerant in a gaseous state; a first and a second heat exchangers, in

those that condense the vapors from the compressor; a closed water circuit, with a recirculation pump, which passes through the first heat exchanger and through a domestic hot water container tank; and means for selecting the passage of the vapors from the compressor to the first or second heat exchangers.

The control means mentioned above may consist of two solenoid valves that control the passage of the vapors 5 from the compressor to the first and second condenser.

The control means mentioned may also consist of a three-way valve.

The system object of the present invention is completely different from those indicated in groups 1 and 2, since they do not consider the use of a pre-heat exchanger prior to condensing the heat pump, air conditioning system or cooling system . 10

The system object of the present invention is also completely different from that indicated in group 3, since in these it is the refrigerant itself that exchanges heat directly with the domestic hot water inside the tank.

The system object of the present invention is also different from group 4 systems, since, although they have in common the use of an additional heat exchanger in series with the heat pump condenser, air conditioning system or cooling, since in this system the water that is used for the production of domestic hot water in the tank is circulated only by the heat exchanger exchanger and in a closed circuit, that is, it does not previously circulate through the heat pump condenser , air conditioning or cooling system. That is, the water that is used for the production of the domestic hot water inside a tank circulating inside a coil located inside said tank is heated by circulating only 20 through the desheater exchanger, without previously circulating through the condenser. In addition, the water used for the production of domestic hot water circulates in a closed circuit equipped with its own recirculation pump.

In addition, the domestic hot water production system object of the present invention also differs from all known in that, in the heat pump or reversible air conditioning systems, the cycle inversion valve is located after the exchanger desreheater, so that, regardless of whether the heat pump or air conditioning system is providing heat or cold through the emission system, hot gases from the compressor discharge always circulate through the desheater exchanger, which allows hot water can always be produced regardless of whether the heat pump or the air conditioning system is providing heat or cold through the emission system 30 located inside the building to be heated.

Brief description of the drawings

The attached drawing shows an installation for the production of domestic hot water, hereinafter “ACS”, given as a non-limiting example.

Detailed description of one embodiment 35

The characteristics, constitution and advantages of the installation of the invention can be better understood with the following description, made with reference to the scheme represented in the attached drawing.

The attached figure shows an installation comprising a compressor (1) that sucks the vapors of a low pressure refrigerant and performs a compression process of said vapors in which its pressure and temperature increases, so that in the discharge of the compressor (2) the refrigerant is in conditions of high pressure and high temperature and reheated, that is, at a temperature higher than the saturation temperature corresponding to its pressure.

The refrigerant vapors under the conditions of discharge of the compressor (2), that is, at high pressure and reheated, can be brought to the inlet of a first exchanger (3), called a de-heater, by means of the use of two bypass valves ( 4 and 5) electrically controlled, so that when the DHW production is carried out the valve (4) remains open and the valve (5) closed. The production of DHW will be completed by opening the valve (5) and closing the valve (4), so that the vapors from the compressor discharge are directed directly towards the second condenser exchanger (6), without passing through the first desheater exchanger (3).

The routing of the discharge vapors from the compressor (2) to the desheater (3) can also be performed 50 alternatively to the use of the passage valves (4 and 5) by using a single electrically controlled three-way valve with a single inlet , through which the compressor discharge vapors enter, and two outlets, one that directs the vapors towards the desheater (3) and another that directs them towards the condenser (6). In the case of using a single three-way valve, when the production of DHW is required, the valve will be electrically commanded, so that it only allows the flow of refrigerant from the inlet to the outlet that is

It is connected to the desheater (3), and when the completion of the DHW production is required, the valve will be controlled so that the flow of the refrigerant vapors occurs from the inlet to the outlet of the valve that is connected directly with the condenser (6), so that the refrigerant in this case will not circulate through the desheater (3).

In the ACS production process, the vapors under the conditions of the compressor discharge enter the first 5 superheater exchanger (3) from the top and circulate downwards leaving the bottom.

In the first desheater exchanger (3) the refrigerant vapors give heat to the water flow of the closed circuit which, during the ACS production process, is circulated through the first exchanger and in countercurrent with the refrigerant vapors, that is, which enters through its lower part and exits through its upper part. The heat transfer process that takes place in the first exchanger (3) simultaneously causes the cooling of the vapor stream and the heating of the closed circuit water stream. The process of cooling the vapors can only cause their partial de-heating or their total de-heating and their partial or total condensation.

The refrigerant leaves the first exchanger (3) at its bottom and passes through a non-return valve (7), and since the valve (5) is closed, it goes to the second condenser (6) entering it on its part 15 superior. That is, during the ACS production process the refrigerant passes first through the first condenser (3), where heat is transferred to the water of the closed circuit, and then through the second condenser (6) where the total condensation of the vapors takes place and normally also a subcooling of the condensed refrigerant.

The closed water circuit consists of the first heat exchanger (3), the coil (8) and the recirculating pump (10), as well as a pressure switch, a closed expansion vessel, a 20-load system of water in the circuit and a non-return valve that prevents circulation by natural convection of water when the DHW production system does not work.

The coil (8) is located inside a tank (9), in which the heating of the DHW (DHW production tank) takes place.

The water recirculation pump in the closed heating circuit of the ACS can be of constant speed 25 or of variable speed.

When the ACS production system is in operation, the recirculating pump (10) circulates the water inside the closed circuit, so that it enters the first heat exchanger (3) on the other hand lower and circulates in countercurrent with the refrigerant receiving the heat given by it, which causes the water to warm up increasing its temperature, and therefore rises at a higher temperature, through the upper part of the first heat exchanger (3). The water that has been heated in the first heat exchanger (3) is directed through the corresponding pipe to the top of the coil (8) inside the ACS production tank (9).

The water from the closed circuit enters the coil (8) at its upper part at high temperature and circulates downwards giving heat to the ACS that is inside the tank (9) and, therefore, in contact with part 35 outside of the coil. The water from the closed circuit leaves the lower part of the coil at a lower temperature than the inlet due to the heat transfer to the ACS inside the tank (9).

The DHW in the tank (9) is heated due to the heat given by the water from the closed circuit that circulates inside the coil (8) at a higher temperature.

The heating of the DHW in the tank (9) can be carried out without entering or leaving the water in the tank 40 (normally referred to as static operation of the DHW production tank) and also simultaneously with the ACS water inlet and outlet in the tank. deposit (normally referred to as the dynamic regime operation of the ACS deposit). In dynamic operation of the tank, the ACS is introduced from the bottom (11) and removed from the top (12).

The control of the ACS closed circuit heating system will be based on the control of a certain temperature of the ACS inside the tank (setpoint temperature) acting on the recirculation pump (10) and on the valves (4 and 5), according to Fig. 1, or where appropriate on the three-way valve that replaces them.

The ACS setpoint temperature will be an external input of the control system. The actual ACS temperature in the tank will be measured with one (13) or two temperature sensors (13 and 14). If a single 50 temperature sensor (13) is used, the control system will also allow an external temperature differential to be established externally. If two temperature sensors (13 and 14) are used, they will be placed so that they measure the temperature of the DHW at a different height inside the tank.

If a single temperature sensor (13) is used, the control system will start and maintain the ACS production system when the actual ACS temperature measured by the sensor located 55

in the tank (13) it is lower than the setpoint temperature minus the differential set externally in the control system. The ACS production system can be started by performing the following actions: opening the solenoid valve (4), closing the solenoid valve (5) and starting the recirculating pump (10).

The control system will stop the DHW production system when the actual temperature of the DHW measured by the sensor inside the tank (13) is equal to the set setpoint temperature. The DHW production system will be stopped by performing the following actions: opening of the solenoid valve (5), closing of the solenoid valve (4) and stopping the water recirculation pump (10).

If two temperature sensors are used in the tank (13 and 14), the control system will start and keep the ACS production system running when the actual ACS temperature measured by the sensor closest to the top of the tank (13) is lower than the setpoint temperature. The 10 ACS production system can be started up by performing the following actions: opening the solenoid valve (4), closing the solenoid valve (5) and starting the recirculating pump (10). The control system will stop the DHW production system when the actual DHW temperature measured by the sensor closest to the bottom of the tank (14) is equal to the set setpoint temperature. The ACS production system will be stopped by performing the following actions: opening of the solenoid valve (5), closing of the solenoid valve (4) and stopping 15 of the water recirculating pump (10).

If the recirculated pump (10) in the closed ACS production system is of variable speed, then the control system, in addition to controlling the start-up and shutdown of the ACS production system as indicated above, will perform the control of the operating speed of the recirculating pump (10) taking into account the setpoint temperature established in the control system and the actual temperature measured by the ACS sensors in the tank.

In the case of reversible heat pumps, the installation will include a cycle inversion valve (15) that will always be placed in such a way that, if the ACS production system is working, the refrigerant circulates through the solenoid valve (4), by the first heat exchanger (3), by the non-return valve (7) and then by the cycle inversion valve (15). If the ACS production system does not work, then the cycle reversing valve 25 (15) will be placed after the solenoid valve (5), so that the refrigerant from the discharge of the compressor (1) circulates at through the solenoid valve (5) and then through the cycle inversion valve.

The arrangement of the cycle reversing valve (15) indicated above and as shown in Fig. 1 guarantees that the DHW production system can always operate, both when the second heat exchanger 30 (6) is the condenser as explained above, such as when said second heat exchanger (6) becomes an evaporator in case of reversal of the heat pump operating cycle.

Claims (9)

1.- System for the production of domestic hot water in heat pumps and air conditioning and refrigeration systems whose operating principle is based on a simple stage steam compression cycle and in which the compression process is carried out by means of a electrically operated compressor and in which the condensation process of the refrigerant is carried out in two exchangers arranged in series, so that the refrigerant from the discharge of the compressor circulates through a first heat exchanger exchanger and then by a second condenser exchanger, characterized by the use of a closed water circuit, with a recirculation pump, in which the water circulates through the first desheater exchanger in which it is heated by heat exchange with the refrigerant and subsequently by a coil located inside a tank in which domestic hot water is produced through the transfer of lime or of the water circulating in the 10 closed circuit and the sanitary water of the tank.  2. System according to claim one, characterized in that it comprises actuation means consisting of two solenoid valves, which select the passage of the vapors from the compressor to the first desheater exchanger or to the second condenser exchanger. 3. System according to claim 1, characterized in that it comprises actuation means consisting of a three-way solenoid valve that selects the passage of the vapors from the compressor to the first desheater exchanger or to the second condenser exchanger. 4. Installation according to claim 1, characterized in that the first desheater exchanger is a plate exchanger through which the refrigerant vapors from the compressor and the water of the closed circuit for the production of domestic hot water circulate countercurrently. twenty 5. System according to claim 1, characterized in that the refrigerant vapors outlet of the first heat exchanger are connected to the inlet of the second exchanger, through a conduit equipped with a non-return valve. 6. System according to claim 1, characterized in that the closed water circuit includes a presostatic safety valve, a closed expansion vessel, a loading system with circuit water and a non-return valve 25. 7. System according to claim 1, characterized in that it comprises control means of the closed water circuit, which act as a function of the temperature in the domestic hot water container tank and act on the recirculation pump and on the actuation means for select the passage of the vapors from the compressor to the first or second exchanger. 30 8. System according to claim 1, applicable in reversible heat pumps, characterized by the provision of a cycle reversing valve just before the condenser exchanger, after the first desheater exchanger and the non-return valve located after it and then, of the drive means for selecting the passage of the vapors from the compressor to the second heat exchanger. 9. System according to claim 1 characterized by a control system, by using the measurement of the DHW temperatures in the tank, provided by one or two sensors, a setpoint temperature, or a setpoint temperature and a temperature differential, in the case of using a single sensor, and based on the comparison between the actual measurements and the setpoint, it will act on the circulating pump and on the solenoid valves or the three-way valve that allow the addressing of the vapors of refrigerant by the exchanged desheater or its delivery directly to the condenser. 40