Heat recovery unit and heat recovery system of building utilizing it
The objective of the present invention is to provide a system which allows efficient air-conditioning heat recovery during ventilation and is applicable to ordinary housing. In order to achieve the above objective, a central ventilation fan 110 is connected to a heat exchanger 120 via a ventilation pipe. Air collected in the central ventilation fan 110 is emitted via the heat exchanger 120 from a device after recovering heat from heated exhaust air from each room by the heat exchanger 120. On the other hand, the heat exchanger 120 is connected to a tank 130 via a water suction/drainage pipe. Water drawn up from the tank 130 by a pump 140 is heated by the heat exchanger 120 and then returned to the tank 130 again. The heat exchanger 120 uses the Peltier device to cool the exhaust air from the central ventilation fan 110, and heat water in the tank 130 at the same time, thereby efficiently transferring air heat from each room to water. Efficient transfer of heat using the Peltier device allows a higher temperature of the water from the heat exchanger than the exhaust air temperature.
The present invention relates to a heat recovery device and a building heat recovery system using the same to efficiently recover air conditioning heat during ventilation of buildings.
BACKGROUND OF THE INVENTIONUrgent solutions for environmental issues have been desired. In particular, a problem of reduction in CO2 emission has come under close scrutiny after ratification of the Kyoto Protocol. Energy saving must be promoted in every field throughout the nation in order to reduce CO2 emission. Therefore, energy saving is required even for heating and cooling in small buildings, more specifically, in ordinary housing.
On the other hand, with ordinary housing, a concern for ventilation in housing has grown due to health problems. However, good ventilation leads to inefficient thermal energy emission during ventilation of air-conditioned housing.
Consequently, a system which allows efficient air-conditioning heat recovery during ventilation is currently required.
DISCLOSURE OF INVENTIONThe objective of the present invention is to provide a system which allows efficient air-conditioning heat recovery during ventilation and is applicable to ordinary housing.
In order to achieve the above-described objective, a ventilation heat recovery device of the present invention includes a heat sink; a Peltier device connected to the heat sink; a medium connected to the Peltier device; and a power supply for the Peltier device, wherein heat including cold heat is transferred from ventilation to a medium via the Peltier device.
In addition, a building heat recovery system of the present invention includes a central ventilation fan for collecting exhaust air from each room in the building for ventilation; a ventilation heat recovery device, which conducts exhaust air heat from the central ventilation fan to a medium; and a highly efficient thermal conduction sheet for radiating heat conducted via the medium to each room.
A highly efficient thermal conduction material is used as the medium, and heat is conducted without transferring via the medium. Such configuration allows reduction in difference in temperature between the top and the bottom of a room or between rooms.
BRIEF DESCRIPTION OF THE DRAWINGS
An embodiment of the present invention is described while referencing the drawings.
In
The heat exchanger 120 uses the Peltier device to cool the exhaust air from the central ventilation fan 110, and heat water in the tank 130 at the same time, thereby efficiently transferring air heat from each room to water. Efficient transfer of heat using the Peltier device allows a higher temperature of the water from the heat exchanger than the exhaust air temperature.
By reversing the direction of current flowing into the Peltier device for cooling, exhaust air from the central ventilation fan 110 is heated and water is cooled by the heat exchanger 120, resulting in generation of cold water. In this case, usage of the Peltier device allows decrease in this cold water temperature to be lower than an exhaust air temperature from a room.
Note that a thermometer 154 measures water temperature flowing into the heat exchanger 120; a thermometer 152 measures water temperature flowing out from the heat exchanger 120; and a thermometer 156 measures water temperature in the tank 130. A power supply 160 supplies power, which is then measured by a wattmeter 162, to the Peltier device in the heat exchanger 120 and a pump.
The heat exchanger 120 is made up of heat sinks 210, Peltier devices 220, water suction/drainage pipes 250, and a container 230. Exhaust air from the central ventilation fan 110 is emitted from the heat exchanger via the heat sinks 210, while conducting exhaust air heat to the heat sinks 210. Water flowing through the heat exchanger 120 from the tank 130 enters the container 230 via one of the water suction/drainage pipes 250, flows out from the other water suction/drainage pipe 250, and returns to the tank 130.
One surface each Peltier device 220 is bonded to a flat surface of corresponding heat sink 210, and the other is bonded to one surface of the container 230. When applying a certain amount of current to the Peltier devices 220, one surface thereof becomes a cooled surface, and the other becomes a heated surface. When reversing the direction of the current, the cooled surface and the heated surface are reversed.
Consequently, in the case of recovering air-conditioning heat using the heat exchanger and then heating water in the container 230, a certain amount of current should be applied so that the Peltier device 220 sides bonded to the heat sink 210 become cooled surfaces and the other sides surfaces bonded to the container 230 become heated surfaces This makes the Peltier device 220 sides bonded to the heat sink 210 cool exhaust air, and the Peltier devices 220 sides bonded to the container 230 heat water. On the other hand, when cooling water by recovering air-conditioning cold air, a certain amount of current is applied to the Peltier devices 220 in a direction opposite to the case of heating. This makes the Peltier devices 220 bonded to the heat sink 210 heat exhaust air, and the Peltier devices 220 sides bonded to the container 230 cool water.
As shown in
In
In the heat exchanger 430, a certain amount of current flows through the Peltier devices so that water can be heated for warming, or that water can be cooled for cooling. Heated or cooled water circulates along the water suction/drainage pipe 440, and returns to the pump/spare tank 450.
This heat recovery device allows heating (cooling) of each room using heat (cold heat) stored in water. In this case, as shown in
On the other hand, when collectively taking air in from the outside for ventilation of a building, the Peltier devices may be used for heating (cooling) the air intake. In this case, usage of the heat exchanger with the Peltier devices as shown in
In this system, the location of each device is not limited to the above, and, for example, the heat exchanger 430 may be provided outdoors. In addition, the location of the water suction/drainage pipe 440 is not limited to the above, and, it may be deployed, for example, under a floor, in walls, or in a ceiling of each room.
Exhaust air from each room in the housing is collected by a central exhaust air/heat recovery device via ventilation pipes 512 provided in each room. The central exhaust air/heat recovery device made up of a central ventilation fan 510, which collects exhaust air from the ventilation pipes 512, and a heat exchanger 530, which recovers and stores exhaust air heat in a medium, recovers and stores exhaust air heat in a medium, and then emits the exhaust air from a pipe 514 to the outside of the housing. The central exhaust air/heat recovery device recovers not only heat during heating but also cold heat for cooling. The heat exchanger 530 is controlled by a control unit 540, which is operated using an operation panel. The control unit 540 also monitors temperatures using an intake air temperature sensor 543, an exhaust air temperature sensor 545, an inlet water temperature sensor 544, and an outlet water temperature sensor 547. The heat exchanger 530 will be described below in detail.
Heat (including cold heat) recovered by the central exhaust air/heat recovery device is sent back to the housing again from a radiator panel (highly efficient thermal conduction sheet bonded board) 560 provided in each room via a medium such as water and the heat exchanger 530. As shown in
The heat exchanger 530 used in the central exhaust air/heat recovery device is the above-described heat exchanger 530 with the Peltier devices. In the heat exchanger 530, heat sinks provided in exhaust air are connected to the Peltier devices, thereby transferring heat (cold heat) from those Peltier devices to a medium.
The radiator panel (highly efficient thermal conduction sheet bonded board) 560 has a configuration where a highly efficient thermal conduction sheet (e.g., a graphite sheet) 566 is bonded to a board 562. Thermal conduction between the highly efficient thermal conduction sheet 566 and a heat exchanger 556 including a medium such as water is provided by a similar highly efficient thermal conduction sheet 564. Since a medium within the heat exchanger 556 moves slowly, sufficient thermal conduction to the highly efficient thermal conduction sheet 564 can be provided.
Configuration of the radiator panel with a highly efficient thermal conduction sheet allows generation of a lightweight and highly efficient radiator panel.
In addition, since a highly efficient thermal conduction sheet deployed on part of a surface of that radiator panel 560 provides thermal conduction, this panel can be deployed anywhere by nailing, for example.
According to this system, as shown in
As described above, since this heat recovery system provides thermal conduction using a highly efficient thermal conduction material, there is no need for motive energy for transferring a medium.
In addition, in the case where a radiator panel is provided in a ceiling or under a floor in a room, if there is not only heat recovered from exhaust air but also difference in temperature between the top and the bottom of a room or between rooms, the heat for the difference in temperature is absorbed from the highly efficient thermal conduction sheet on the radiator panel, and then conducted via the highly efficient thermal conduction material in the pipe, which allows elimination of difference in temperature within a house. This is effective even when heat from exhaust air is not recovered.
This is because the highly efficient thermal conduction sheet on the radiator panel or the highly efficient thermal conduction material in the pipe conducts heat bidirectionally, and this allows arbitrary thermal conduction.
Industrial AvailabilityThe heat recovery device according to the present invention allows efficient operation at low costs and facilitates maintenance. In addition, less power consumption leads to energy saving. Furthermore, noise can be suppressed.
Claims
1. (canceled)
2. A building heat recovery system, comprising:
- a central ventilation fan for collecting exhaust air from each room in the building for ventilation;
- a ventilation heat recovery device; which has a heat sink, a Peltier device connected to the heat sink, a medium connected to the Peltier device and a power supply for the Peltier device, and conducts exhaust air heat from the central ventilation fan to a medium; and
- a highly efficient thermal conduction sheet for radiating heat conducted via the medium to each room.
3. The building heat recovery system according to claim 2, wherein a highly efficient thermal conduction material is used as said medium, and heat is conducted without transferring via the medium.
Type: Application
Filed: Feb 3, 2003
Publication Date: Jun 30, 2005
Applicant: FAMM CO., LTD (Yokohama-shi)
Inventor: Hideyo Yamamoto (Kanagawa)
Application Number: 10/505,432