RU2386900C2 - Room heating and cooling device - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: room heating and cooling device includes liquid heater and cooler, supply and return pipelines, as well as radiator connected to pipelines through inlet and outlet connection pipes. At that, heater is made in the form of individual assembly. Connection pipes are connected to the system from supply and return pipelines through shutoff valves. Liquid cooler is made in the form of separate device which is connected to radiator through additional complex of supply and discharge pipelines. At that, supply pipeline is connected via shutoff valve to outlet connection pipe, and discharge pipeline is connected via shutoff valve to inlet connection pipe.

EFFECT: energy saving.

10 cl, 2 dwg

Description

Technical field

The technical solution relates to systems for liquid heating of premises with natural or forced, for example using a pump, circulation of the coolant [1]. It is suitable for use in cottages, high-rise buildings, as well as in storage facilities, agricultural and industrial facilities, which are located in regions with changing seasons, mainly for areas characterized by pronounced winter.

State of the art

In the method of using ice for cooling [2], cold is transferred from the ice maker to water, which circulates between cooling devices and ice in the ice maker. Ice in the ice machine is prepared in the winter.

This technical solution is not suitable for heating buildings.

The heating and cooling system of the building [3] can operate in winter and summer. It consists of pipelines (supply and return), as well as heat exchangers connected to them, which use heating and cooling convectors. Pipelines are attached to a node that acts as a source of heat or cold, depending on the time of year.

This technical solution is taken as a prototype.

The disadvantage of this technical solution is the large cost of energy for cooling.

SUMMARY OF THE INVENTION

The problem solved by the proposed device is energy saving.

The device for heating and cooling the premises has a liquid cooler and a source of thermal energy. Liquid radiators are connected to a heat source through a piping system.

According to the invention, radiators are connected to the piping system through valves. The liquid cooler is designed as a storage of frozen liquid. The stock of frozen liquid stored in the storehouse is prepared in the winter. The internal cavity of the storage is connected to radiators through shut-off valves, supply and return pipelines.

The source of thermal energy can be made in the form of a liquid boiler using combustion of fuel or electric energy.

The heat source can be implemented as a connection to a district heating system.

A pump can be switched on between a heat source and a radiator.

The pump can be switched on between the fluid cooler and the radiator.

One of the valves connecting the radiator to the piping system is a thermostat.

One of the valves connecting the radiator to the supply or return piping is a thermostat.

To connect radiators to a liquid cooling system, they are equipped with additional input and output fittings.

Brief Description of the Drawings

The invention will be further described in detail with reference to the accompanying drawings, in which:

- figure 1 depicts a diagram of a device for heating and cooling a room in which convection circulation of liquid is used;

- figure 2 depicts a diagram of a device for heating and cooling a room that uses forced, using pumps, the circulation of liquid.

The method of carrying out the invention

Figure 1, 2 presents the best embodiments of the invention.

In the device for heating and cooling the premises (Fig. 1), natural fluid circulation is used. The movement of the liquid is the result of convection due to the difference in its temperature. This device contains liquid radiators 1, which are designed to heat or cool the air in the room (the room in figure 1, 2 is not shown). Radiators 1 are connected to the heating subsystem used in winter. This subsystem consists of shut-off valves 2, 3, supply 4 and return 5 pipelines connected to the electric boiler 6. The tank 7 compensates for the thermal expansion of the liquid.

The cooling subsystem used in summer consists of a storage 11 in which a monolith 12 of frozen liquid is located. Monolith 12 is a collection of blocks 13, which are prepared in the winter. The storehouse is a container 15 with heat insulation 16. The tank 15 has a thermally insulated roof 17. The monolith 12 floats in the liquid 18 located in the internal cavity 19 of the storage 11. The cavity 19 communicates with radiators 1 through the supply 21 and return 22 pipelines, as well as shut-off valves 23 24. Shut-off valves 26, 27 connect pipelines 22, 21 to the environment.

In the device for heating and cooling the room (figure 2), the circulation of fluid is provided by pumps. Radiators 31 are designed to heat indoor air in the winter or to cool it in the summer. Radiators 31 are equipped with fittings 32, 33. They are designed to be connected to a heating subsystem. Nipples 34, 35 are used to connect to the cooling subsystem.

The heating subsystem consists of a heat exchanger 37, a pump 38, a pressure (supply) pipe 39 and a drain (return) pipe 41, as well as a tank 42. Shut-off valves 44 and temperature controllers 45 are used to connect radiators 31 to pipelines 41 and 39, respectively. The heat exchanger 37 through pipelines 47 is connected to a district heating system, which is not shown in Fig.1, 2.

The cooling subsystem consists of a storage 51. A monolith of frozen liquid 52 is located in the cavity 53. The liquid 54 located in this cavity is connected through the pump 55 to the supply pipe 56. The radiators 31 are connected to the pipe 56 using thermostats 58, and to the return pipe 59 through shut-off valves 61. The pipe 59 is connected to the internal cavity 53 of the storage 51. Shut-off valves 66, 67 connect the piping 59, 56 to the environment.

The temperature regulator 45 or 58 is a valve with a thermostatic element that changes the flow area of the valve depending on the temperature of the room in which the radiators 31 are located. It is also possible to use valves with thermoelectric actuators controlled by room thermostats with wired connection. The temperature controller 45 or 58 has the possibility of preliminary adjustment, which allows you to correctly distribute the fluid flow between the radiators 31, and can also be closed.

Device operation

A device for heating and cooling a room (Fig. 1) operates as follows. In winter, valves 2, 3 are open, and valves 23, 24 are closed. The liquid heated in the boiler 6 rises through the supply pipe 4 to the radiators 1, where it gives off part of the heat to the surrounding air. The cooled liquid through the valve 3 through the return pipe 5 is lowered into the boiler 6.

The liquid 18 is previously drained from the storage 11. For this, valves 23, 24, 26, 27, 28 are used. The roof 17 is removed and the storage is filled with blocks of frozen liquid 13. They are combined into a monolith 12 with the help of the liquid applied to the side surfaces of the blocks 13.

In the summer, valves 2, 3, 26, 27 are closed, and valves 23, 24, 28 are open. The cooling subsystem is filled with liquid 18. As a result of the natural external heating of the storage 11, the monolith 12 begins to melt. Cold liquid 18 from the lower zone of the storehouse is lowered through the supply pipe 21 to the radiators 1, where it is heated, taking the heat of the surrounding air. The heated fluid through the valve 24 through the return pipe 22 rises to the storage 11, where due to the melting of the monolith 12 is cooled and lowered down.

A device for heating and cooling the premises (figure 2) with forced circulation of the liquid works as follows. In winter, the liquid is pumped through the pump 38 through the heat exchanger 37 and through the supply pipe 39 enters the radiators 31. The temperature controller 45 changes the fluid flow through the radiator 31 depending on the temperature of the room where the radiator is located. The valve (not shown in FIGS. 1, 2) of the temperature controller 45 opens if the room temperature is below a predetermined level. The valve cross section increases with increasing difference between the set and actual temperatures. Having cooled in the radiators 31, the liquid through the return pipe 41 enters the heat exchanger 37. Thermostats 58 and valves 61 are closed. The fluid 54 is drained from the storage 51 through the valves 67, 68. The roof 71 of the storage 51 is open, and it is loaded with blocks 72, which are combined into a monolith 52.

In the summer, the valves 44 and thermostats 45 are closed, and the thermostats 58 and the valves 61 are open. The liquid 54 formed in the storage 51, through the valve 68 and the pump 55 enters the supply pipe 56. Then, through the thermostats 58, the liquid 54 enters the radiators 31. The valve (not shown in FIGS. 1, 2) of the thermostat 58 opens if the room temperature exceeds the set level. The valve cross section increases with increasing difference between the set and actual temperatures. The liquid heated in the radiators 31 through the valves 61 enters the storage, where it is cooled by the melting of the monolith 52.

Literature

1. Turkin V.P. Automatic water heating systems for residential and public buildings. M .: Stroyizdat, 1976.

2. USSR author's certificate No. 98583, cl. F25D 3/00.

3. USSR author's certificate No. 342023, cl. F24D 3/02.

Claims (10)

1. A device for heating and cooling the premises, containing a heater and a liquid cooler, supply and return pipelines, as well as a radiator connected to the pipelines through the inlet and outlet nozzles, respectively, characterized in that the heater is made in the form of an individual unit, the nozzle is connected to the system from the supply and return pipelines through shut-off valves, and the liquid cooler is made in the form of a separate unit, which is connected to the radiator through an additional set of discharge and drain pipelines, and the discharge pipe through the shut-off valve is connected to the outlet fitting, and the drain pipe through the shut-off valve is connected to the inlet fitting. 2. The device for heating and cooling the premises according to claim 1, characterized in that the unit is made in the form of a frozen liquid located in the storage. 3. A device for heating and cooling a room according to any one of claims 1 and 2, characterized in that the frozen liquid is prepared in the winter. 4. The device for heating and cooling the premises according to claim 1, characterized in that the fluid heater is made in the form of a boiler using fuel combustion or electric energy. 5. The device for heating and cooling the premises according to claim 1, characterized in that the liquid heater is implemented as a connection to a district heating system. 6. The device for heating and cooling the premises according to claim 1, characterized in that between the liquid heater and the system from the supply and return pipelines, a liquid pump is switched on. 7. The device for heating and cooling the premises according to claim 1, characterized in that between the unit and the aggregate of the discharge and drain pipelines, a liquid pump is turned on. 8. The device for heating and cooling the premises according to claim 1, characterized in that one of the valves connecting the radiator to the system from the supply and return pipelines is a thermostat. 9. The device for heating and cooling the premises according to claim 1, characterized in that one of the valves connecting the radiator to a combination of discharge and drain pipelines is a thermostat. 10. The device for heating and cooling the premises according to claim 1, characterized in that the radiator is equipped with additional inlet and outlet fittings connected to the discharge and drain pipelines, respectively, which communicate with the output and input fittings connected to the return and feed pipelines, respectively.

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