RU106938U1 - DEVICE FOR ENERGY REGENERATION IN THE INSTALLATION OF CONDITIONING AND VENTILATION TECHNIQUES - Google Patents

Abstract

 A device for energy recovery in the installation of air conditioning and ventilation technology with a volumetric flow of supply air and a volumetric flow of exhaust air, comprising a heat recovery system connecting the volumetric flow of supply and exhaust air for the purpose of heat transfer between the volumetric flow of supply air and the volumetric flow of exhaust air, which contains the unit recuperation and heat exchangers, one of which is located in the supply air volumetric flow, and the second - in the exhaust air volumetric flow ha, a heat pump, through heat exchangers connected to volumetric air flows, storage circuits associated with a heat pump and heat exchangers placed in volumetric air flows, as well as an automation unit, a heat supply system and a hot water supply system, characterized in that the heat exchangers are interconnected through the main pipeline, in addition, the device is equipped with temperature sensors associated with the automation unit, and one of the sensors installed in the volumetric flow th air after the heat exchanger, the second sensor is disposed in the supply air volume flow before recovery unit, and a third sensor - after the heat exchanger disposed in the supply air stream.

Description

The utility model relates to energy recovery devices in air conditioning and ventilation equipment. Heat recovery systems, installations with recuperative and regenerative heat transmitters, as well as installations with an intermediate medium or heat pumps are used in air conditioning and ventilation techniques to regenerate the energy of their exhaust or exhaust air.

Various heat recovery systems are known.

For example, RF patent No. 2168116, publ. 06/27/1999, RU, IPC F24F 3/147, 12/00 A device for an air conditioning system comprising heat recovery means and means for supplying additional heating and cooling, in which at least one heating or cooling device is installed in the flow of incoming air, the liquid side of which is connected to a heating or cooling device. A disadvantage of the known device is the high energy consumption for heating and cooling the air, as well as the inability to utilize excess heat.

The closest in technical essence and the achieved result is the technical solution adopted for the prototype of the utility model according to the patent of the Russian Federation No. 2362946, publ. 09/10/10, RU, IPC F24F 12/00. A well-known patent represents a method and device for energy recovery, which describes a device for energy recovery in the installation of air conditioning and ventilation equipment with a volumetric flow of supply air and a volumetric flow of exhaust air, comprising a recovery unit, heat exchangers, a heat pump, a storage circuit, a heat supply system and a system DHW. The device is also equipped with an automation unit connected by heat exchangers and a heat supply system. A disadvantage of the known technical solution is the lack of the ability to use heat exchangers installed in the volumetric flows of the supply and exhaust air for simultaneous operation to remove excess heat, which does not allow the most efficient storage and efficient use of the received energy, as well as the lack of the ability to quickly respond to the formation of excess automation unit heat.

The objective of the utility model is the possibility of the most complete removal of the excess heat of the volumetric air flows and energy conservation by increasing the automation of the device while creating the required temperature parameters of the air in the room and the possibility of utilizing excess heat.

The problem is solved as follows.

In the device containing the recovery unit (for direct transfer of energy from the supply air stream to the exhaust air and vice versa), heat exchangers, a storage circuit (for stabilizing the system and connecting the heat exchangers with the heat pump), a heat pump (for converting low-grade heat received from the exhaust air stream and its use for heating water in a hot water supply system), as well as an automation unit (for receiving and processing data on air parameters in the system), a heat supply system and a system in hot water. One heat exchanger is placed in the supply air stream after the recuperator, and a second heat exchanger is installed in front of the recovery unit to change the temperature of the exhaust air in the exhaust air stream. At the same time, heat exchangers are interconnected by a main pipeline, which makes it possible to most completely remove excess heat (simultaneously) from the exhaust air and from the supply air flow. In addition, the device is equipped with temperature sensors associated with the automation unit, one of which is installed in the exhaust air volume flow after the heat exchanger, the second sensor is located in the supply air volume flow, in front of the recovery unit, and the third sensor is located after the heat exchanger placed in the supply air flow , which allows the automation unit to immediately respond to changes in the temperature of the air flows and not waste extra energy on its heating (or cooling).

The device is illustrated in graphic materials.

In FIG. shows a schematic illustration of a device for energy recovery.

The device contains, located in the aperture for the passage of air flows, a recovery unit 1, for direct energy transfer between the volumetric flows of the supply and exhaust air, a heat exchanger 2 located in the volumetric flow of the supply air for the selection and transfer of heat to the supply air, connected to the accumulation circuit 3 for regulation of heat transfer or heat extraction from the supply air. The storage circuit 3 is connected to the heat pump 4. The heat exchanger 5 is located in the volumetric flow of exhaust air, for the selection and transfer of heat to the exhaust air. The heat exchanger 5 is connected to the accumulation circuit 6 (to regulate the transfer or selection of heat from the exhaust air and communication with the heat pump 4). The heat exchangers 2 and 5 are interconnected via a pipeline 7, which makes it possible for the heat exchangers to work simultaneously to remove heat from both the exhaust and supply air. The heat pump 4 serves to convert low-grade heat received from exhaust and supply air and direct it for use when heating water in a hot water supply system 8. The device also includes an automation unit 9, which, in turn, is connected to storage circuits 3 and 6, the system heat supply 10, recovery unit 1, heat pump 4. Storage circuits are connected to heat pump 4 and hot water supply system (DHW) 8. In the exhaust stream of (exhaust) air (in the direction of flow) heat exchanger 5 is mounted temperature sensor 11. Similar temperature sensors 11 installed in the supply air volume flow after the heat exchanger 2 and to the recovery unit 1. The temperature sensors 11 associated with the automation unit 9.

The device operates as follows.

Outside air, which after ventilation and technical processing becomes supply air, enters the area in front of the recuperator unit 1, where the temperature sensor 11 is located. The sensor captures the temperature of the outdoor air and sends data to the automation unit 9. If the outdoor temperature is lower than the required supply air temperature , then the automation unit sends a signal to the recovery unit 1 and activates it for direct heat transfer between the volume flows of the supply and exhaust air, thereby increasing The supply air to the desired temperature. Simultaneously with the supply air heating in the recovery unit 1, a heat exchanger 5 is operating in the installation, which removes the remaining heat potential from the exhaust air and transfers it to the accumulation circuit 6. The accumulation circuit 6 is connected to the heat pump 4, which, in turn, is associated with the accumulation circuit 3. Accumulative circuit 3, transfers heat to the hot water supply system (DHW) 8 of the building. If the thermal potential of the exhaust air is not enough to heat the supply air directly in the recovery unit, the temperature sensor 11 located after the heat exchanger 2 fixes this and the automation unit 9 connects the heat exchanger 2 to the storage circuit 3. The circulation fluid of the storage circuit 3 is heated using heat pump 4 , which is associated with a storage circuit 6 connected to a heat exchanger 5, which removes the remaining heat potential from the exhaust air passed through the recovery unit 1. Water heating hot water Istemi stops.

If the sensor 11 reports that the temperature of the circulating liquid of the accumulation circuit 3 is not enough to heat the supply air, the automation unit connects the existing heat supply system 10 of the building. The heat carrier of the heat supply system transfers the thermal potential of the circulating fluid of the accumulation circuit 3, thereby increasing its temperature to the required value to heat the supply air.

If the sensor 11 detects the outdoor temperature above the desired supply air temperature, then the automation unit turns off the recovery unit 1 and connects the heat exchanger 2, through the connecting pipe 7, by opening a three-way valve (not shown in Fig.) To the storage circuit 6 for cooling the supply air. Exhaust air enters the heat exchanger 5, where it gives off heat and is also cooled. The heat is transferred to the circulating fluid located in the storage circuit 6. The temperature of the circulating fluid is set as low as possible and is regulated by the automation unit 9 based on the data received from the temperature sensor 11. Thus, the air is cooled to the lowest possible temperature and the maximum possible removal of thermal potential from the exhaust air. After processing, exhaust air is emitted into the atmosphere.

This installation allows you to heat the supply air during the transition period without additional heating by the heat supply system, while heating the water in the hot water supply system. In the cold period of time, the supply air is heated by heat exchange with exhaust air and partly by means of the building heat supply system. In the warm period, the supply and exhaust air are cooled, and the thermal potential is transferred to the building's hot water supply system as much as possible.

Thus, the proposed implementation of heat exchangers placed in the supply and exhaust air streams in communication and supplying the device with temperature sensors associated with the automation unit allows for maximum removal of excess heat from the air flows, efficient use of energy, and its direction for heating water (i.e. e. disposal).

Thus, the problem of the utility model is solved.

Claims (1)

A device for energy recovery in the installation of air conditioning and ventilation technology with a volumetric flow of supply air and a volumetric flow of exhaust air, comprising a heat recovery system connecting the volumetric flow of supply and exhaust air for the purpose of heat transfer between the volumetric flow of supply air and the volumetric flow of exhaust air, which contains the unit recuperation and heat exchangers, one of which is located in the supply air volumetric flow, and the second - in the exhaust air volumetric flow ha, a heat pump, through heat exchangers connected to volumetric air flows, storage circuits associated with a heat pump and heat exchangers placed in volumetric air flows, as well as an automation unit, a heat supply system and a hot water supply system, characterized in that the heat exchangers are interconnected through the main pipeline, in addition, the device is equipped with temperature sensors associated with the automation unit, and one of the sensors installed in the volumetric flow th air after the heat exchanger, the second sensor is disposed in the supply air volume flow before recovery unit, and a third sensor - after the heat exchanger disposed in the supply air stream.