CA2588150C - Thermodynamic fan with dual inverse flow - Google Patents

Abstract

Fan consisting of a rectangular insulated metal box with a thermodynamic double flow system with coils, two high-performance air inlet filters, two variable speed electric fans, one air intake from outside, two air inlets from the inside one of which serves to recover the energy before the expulsion outward and the other for the purification of air in recirculation mode, a filtered air outlet and calorified to the inside and another exit of treated air towards the outside for the evacuation of the stale air. The fan is also equipped with a control to regulate the humidity of the hot air, the flow of the air flow, the ventilation modes and the control of the ambient temperature as well as the level of dirt of the filters. . The fan blows pre-filtered air that passes directly through the thermodynamic system coils in a parallel fashion from each air inlet to largely recover energy from the air expelled from the inside. to the outside (enthalpy), to transmit this energy internally from the air introduced from the outside with a high degree of efficiency and to control the humidity of the ambient air when required. Through the reversibility of the thermodynamic cycle, the unit heats the air during cold periods and cools the air during hot periods in addition to acting as an air purifier and air dehumidifier. The appliance produces more energy than it consumes, hence saving energy and allowing a better comfort during the summer periods by dehumidifying and refreshing the ambient air.

Description

THERMODYNAMIC VENTILATOR WITH DOUBLE INVERTED FLOW
INTRODUCTION

The present invention relates to a fan which, together with its pump unit heat incorporated, ensures the ventilation and air conditioning of the ambient air during periods cold and summery in order to allow greater efFiciency 'in the air treatment through. its thermodynamic system that also plays the role of heat recovery and dehumidifier in warm periods and wet while the water of condensation is evacuated by a drain. With his system thermodynamics, there is heat exchange since the recovered energy is delivered by the refrigerant to the compressor and retransmitted by the system.
The device acts in the same way as a refrigerator that cools the air extract from the interior and restores entirely the fresh air breathed energy captured.
The economy of energy obtained from the fact that the system uses less electricity for transfer energy (thermodynamics) only to produce it (Joule).

It is called reverse-flow thermodynamic fan since the flux Extraction and insufflation are parallel. The heat pump module is reversible and composed of two coils, one in each stream, connected to a compressor ensuring the heat exchange between them by direct expansion.

According to Wikipedia, the relationship between what can be usefully recovered from the machine on what was spent to make it function.

2 As shown in Figure 1, the system consists of:

1) a box with thermo-acoustic interior insulation with components interior and exterior:

2) Air inlet coming from inside

3) Air intake coming from the outside before being treated

4) Exhaust air outlet to the outside

5) Treated air outlet going inside the building

6) Fan with variable speeds in the part of the air treatment coming from the interior for the insufflation and extraction of energy from the air and the expulsion of air processed outward

7) Fan with variable speeds in the part of the air treatment coming from outside for insufflation and extraction of energy from the air the expulsion of air treated inward

8) a heat pump module comprising:

a) compressor acting as a suction pump b) evaporator coils c) condenser coils d) pressure holder e) Reversing Valve f) safety device (low pressure / high pressure) g) anti-frost probe

9) Filter for the treatment of air coming from inside the building 2 Fan with heat recuperator

10) Pressure switches to check the condition of the air filter coming from inside

11) Box of filtration and purification of the air coming from the entrances 3 (outside) or 16 (Recirculation)

12) Pressure switches for the control of the filtration system and purification of the air coming entries 3 or 16

13) Control monitor for ventilation modes, air conditioning, operation components of the device and other security components

14) Monitor Control Control Connection Box 13

15) Hygrometer

16) Air intake from inside the building for recirculation mode

17) Motorized shutter to close the outside air inlet and open a second air inlet interior for recirculation mode

18) Closing valve for item 17

19) Drain for evacuation of water created by dehumidification of air entering or defrost coils

20) Humidifier

21) Air inlet on the outside wall

22) Air outlet on the outside wall

23) Motorized shutter (optional with # 25) to close the air intake on the exterior wall and open the heated air outlet of the solar collector

24) Closing valve for item 23

25) solar collector (optional) placed on the exterior wall of the building

26) (Reference only) Outside wall Description of the prior art It is now recognized that the need for ventilation in buildings residential is required and many studies have established links between the presence of indoor air contaminants and some health problems.

Ventilation is considered the real lung of a home and protected normally the building of dust and external pollution when the filtration of the air is adequate.

It is also recognized that good ventilation allows the increase of duration life of the building structure when adequately ventilated ..

The indoor air of a residential building can theoretically contain various types of contaminants to which occupants are likely to be exposed. The reduction of indoor air contamination should ideally be subject to strategy that encompasses a number of measures, the control at the source being undoubtedly the option to consider first. However, this approach can not suffice for her only to decrease all the contaminants present, so that it becomes necessary to turn to complementary measures, such as air change inside.
With the rising costs of energy, it is becoming more and more expensive to do ventilation of residential buildings especially in winter.

Heat recovery is difficult for conventional fans when the temperature drops below the freezing point of water vapor in the air and that the created condensation then turns into frost that settles on the ducts of the heat exchanger; thermal transfer then becoming weak through the walls clogged with the exchanger.

To overcome this problem, it is necessary either to stop the air exchange between outside and inside and continue in recirculation mode or install a module heating or wheel to prevent core icing, further increasing costs of use and decreases energy efficiency.

Ventilation of air in a domestic building is normally treated mechanically by a device that operates according to the principle described in figure 4. This Commonly named fan VRC2 includes two fans Fig. 4.3 and 4.4 who operate in reverse and a heat recovery module (Fig.
4.1).

Stale air and fresh outside air pass through this module, and the heat evacuated air outside (Fig. 4.7) is used to preheat fresh air from outside (Fig 4.5). The fan (Fig. 4. 3) sucks stale air from inside (Fig. 4. 7) and the pushes outwards (Fig.4.6) through the core (Fig 4.1) while the fan (Fig.4.
4) sucks the air fresh from outside (Fig. 4.5) which passes through the nucleus (Fig. 4.
1) and is expelled inside (Fig. 4. 8).

When the outside temperature drops below 0 C, the heat exchanger bECOMES
inefficient because condensation created at the dew point turns into frosted which forms on the ducts of the heat exchanger and the transfer thermal becomes weak through the clogged walls of the exchanger. To overcome this problem, it must either stop the air exchange between the outside and inside and continue in recirculation mode or install a heating module or heat wheel for prevent icing of the core.

During the summer period when the outside temperature is higher than the temperature interior, the conventional fan warms the air and increases temperature interior of the building, which creates discomfort.

As a result, during the exchange of heat in the air exchange module in the core of the HRV, the air sucked from the outside cools the air from the inside during cold periods and warm it during warm periods.

There is a variant of a conventional fan with core as interchange combined with a heat pump outside the fan (Figure 5). This variant has been patented among others under the number 02225590. The effectiveness of this principle is much less efficient at the energy and operational levels for same reasons as a conventional core fan.

The air that is treated by the heat pump first goes into the core (Fig. 5 B), encounter the same deicing problems as a fan with a recuperator heat (HRV) and the air must be warmed to adjust the problem (Wheel thermal Fig. 5 C).

At temperatures below the point of water vapor in the air, the air that passes speak core is heated by a heat wheel to prevent clogging of the nucleus caused by the frost of condensation of water vapor in the air, which makes this system less efficient.

There is another variant (Figure 6) of a system registered in the Office of the patents United States under number 6167714 entitled `Portable Cooling and Heating Unit using Reversible Refrigerant Unit 'filed February 4, 2000 by Peter Baffes.

This system, as indicated in the title, is a cooler and a unit of heater ambient air and not a fan to change the stale air of inside by fresh air from the outside with heat recovery and does not have for objective of ventilate and replace stale air with fresh air from outside such as the subject of which this request is subject to, but has an air outlet only (A2) for push the air hot or cold depending on the season and bring down or raise the temperature of the room.

One of the problems that this device can cause is that it creates a vacuum in sucking the air of the apartment as well as the stale air and smells of the other apartments of the building;
a fan with change of fresh air always has an air inlet coming from outside while having the same amount of air coming from the inside in order to to create a Incoming and outgoing air volume balance.

There is no air intake coming from outside to change the stale air of interior as must a fan. Like the drawing of the patent 6167714 indicates in Figure 6, in heating mode the air from the inside (Fig 6.1) passes through the condenser (Fig 6.2) and back inside (Fig 6.A1).

SUMMARY OF THE INVENTION

The inventor used the laws of thermodynamics to design a fan with heat pump module that allows recovery of energy from the air forced out outward effectively by using hot air around 20 VS
from the inside of the building to be ventilated during cold periods of year.
At the same time, cold air from outside passes through the serpentine warm, picks up energy and warms that air. The fan routes then the air nine inwards.

This fan is a ventilation and air conditioning system that allows renew the air in a very efficient way by ensuring a thermal comfort in period cold as in hot weather thanks to the reversal of its cycle thermodynamic.

The thermodynamic module of the fan, of which our request is the object, allows a superior energy recovery from stale air that is expelled to outside, from where heating savings. Moreover, in summer, it cools the air coming from the outside and dehumidifies it for a better comfort of the occupants of the building.

The fan blows previously filtered air that goes directly to through the thermodynamic system coils in parallel fashion from each Entrance of air to recover much of the energy of the expelled air from interior outward, to transmit with a high degree of efficiency this energy towards the inside from the air introduced from the outside and to control the humidity of the ambient air when required.

It is an objective of this application to provide a ventilation system to evacuate stale air from inside a building to the outside of the building and from renew the said stale air with the externally treated air, said system comprising a housing sparing a first and a second chamber, the first chamber having a first air inlet contacting inside the building and a first air outlet through which stale air is rejected outside the building, said second chamber having a second air inlet communicating with outside the building and a second air outlet through which the outside air is directed to inside the building, a first fan to create a first airflow between said first input of air and said first air outlet of said first chamber, a second fan to create a second stream of air between said second air inlet and said second air outlet of said second chamber, said first air flow and said second air stream being isolated from each other by said first and second rooms, a first heat exchanger disposed in said first chamber between said first air inlet and said first air outlet for extracting energy from said first air flow before the said stale air is rejected at outside the building, a second heat exchanger disposed in said second room between said second air inlet and said second air outlet for treating outside air before it is directed inside the building, and a thermodynamic bridge between said first heat exchanger and said second heat exchanger allowing a heat energy exchange between said first heat exchanger and said second heat exchanger.

It is an objective of this application to provide a ventilation system for building, comprising a housing providing a first passage for guiding a first air flow between a first entry and a first air outlet opening on the outside of the building, and a second isolated passage of said first passageway for guiding a second airflow between a second air inlet overlooking the outside of the building and a second air outlet opening on the inside of the building to allow an air intake outside inside the building, a first fan to generate said first airflow through said first passage, a second fan for generating said second air flow at through said second passage, a first heat exchanger inside said first passage, a second heat exchanger heat within said second passage, said first heat exchanger and said second exchanger 7a of heat being connected by a thermodynamic circuit to allow a energy transfer between said first and second heat exchanger.

DRAWINGS
Figure 1 Diagram of the system in heating mode from the outside Figure 2 Diagram of the system in air cooling mode from the outside Figure 3 Diagram of the system in recirculation mode and filtering of the air coming from interior Figure 4 Diagram of a fan variant with heat recuperator using a core Figure 5 Diagram of a fan variant with heat recuperator composed of a core and a wheel thermal defrosting as well as an option with an external link to a heat pump. This variant has been patented under the number 02225590.

Figure 6 Diagram of a variant of a system registered in the United States Patent Office United under the number 6,167,714 entitled Portable Cooling and Heating Unit Using Reversible Refrigerant Unit that is not a fan 7b BRIEF DESCRIPTION OF THE DRAWINGS
Figures 1, 2, 3 The diagram of the appliance includes a box with thermally insulated interior acoustic (1), this box containing a thermodynamic system including an engine with compressor (8A) acting as a suction pump, a serpentine of the evaporator (8B), a coil of the condenser (8C), a holder (8D), a valve inversion (8E), a safety device for detecting pressures from system (8F) and an anti-frost probe (8G). A drain (19) for the evacuation of the water created by the dehumidification of the incoming air or the defrosting of the coils This box also contains the following components:
= an air inlet (2) coming from inside the building = a fan (6) for blowing air from inside by the entrance (2) and expel him to the exit (5) = a filter (9) to remove dust, hairs and particles animal pollen or others to ensure the cleanliness of the system treating the air coming of inside the building = a pressure switch (10) mounted with 2 tubes of air before and after the filter in order to check the pressure difference and the state of cleanliness of the filter (9) = a hygrometer (15) to check the humidity level of the air at inside the house = an outlet (4) through which stale air from inside after being treaty is expelled to the outside = an air intake coming from the outside (3) of the box which passes by the box of filtration and purification of air (11) = an air inlet (16) coming from the inside when the system is in recirculation = a box of filtration and purification of the air (11) in order to eliminate contaminants, allergens, germs, bacteria, viruses, smells and fumes = a pressure switch (12) mounted with 2 tubes of air before and after the box of filtration and of purification in order to check the pressure difference and check the state of cleanliness.

= a motorized shutter (17) serving to close the air inlet coming from outside (3) the building and open the entrance (16) coming from the inside = a closing flap (18) attached to the motorized flap (17) = a fan (7) for blowing air from outside by the entrance (3) or from the inside 16 when in recirculation mode and expel it at the exit (5) = a treated air outlet (5) and expelled towards the interior of the building = a connection box (14) for the control of the components of the device = a drain for the evacuation of the water created by the dehumidification of the air incoming or the defrosting of the coils since the apparatus produces water of condensation in cooling mode or air heating.

= The operation of the device is controlled by a monitor (13) for the fashion air conditioning, ventilation, control of other internal components or external and connected to the system.

In heating mode, a solar collector (25) can be added outside of the building to preheat the fresh air before it is processed in the appliance. The other components are then added:

= a motorized shutter (23) for closing the air inlet (21) on the outer wall with a closing valve 24 allowing the opening of the air outlet of the sensor solar.

On the outer wall of the building (26), there is a fresh air inlet (21) and an air outlet from the inside (22) after recovering the energy from the system.
DETAILED DESCRIPTION

Field of the invention The reverse flow thermodynamic fan is a system of ventilation which allows to renew the air in a very efficient way by ensuring a comfort thermal in cold period as in hot period thanks to the reversibility of its cycle thermodynamic. To illustrate the treatment of air in Figure 1, the airflow in extraction of the interior (2) by a fan (6) and insufflation of outside (3) by a fan (7) are treated in parallel. The air coming from the inside by the entrance (2) passes through a filter (9), flows through the coils of the evaporator (8B) for be cooled and expelled to the outside through the outlet (4).

In a parallel manner, the air coming from the outside through the inlet (3) passes through a box of filtration and purification of the air (11) flows through the coils of the condenser (8C) to be warmed up and expelled inside by the exit (5) to be humidified by the humidifier (20) when required. The thermodynamic circuit composed of two coils (8B and 8C) connected to a compressor (8A) ensure the exchange thermal by direct relaxation.

The fan of which this request is the object possesses a recuperator of heat thermodynamics where the air is directly infused from within and from outside and the energy captured in the air from inside and outside is transferred by the refrigerant to thermodynamic modules (Condenser and Evaporator) to the air intake coming from outside and inside the building.

Thanks to a reversing valve (Reversing valve) of the heat pump module, the unit heats the air during cold periods and cools the air during the periods hot in addition to playing the role of air purifier and dehumidifier air.
The device produces more energy than it consumes, hence energy savings and allows a better comfort during the summer periods by dehumidifying and refreshing the ambient air.

Unlike an air-to-air heat pump that recovers its energy from the air outside and that becomes ineffective around -12 C, this fan with module of heat pump takes its energy from the air coming from the inside, ie to the around 20 C. It's as if an air-to-air heat pump was in heater during the summer period, so very effective.

The control monitor (13) provides the kind of air handling mode heater, cooling or in recirculation and air filtering mode. He controls also the modulation of the fan speed, the air intake from the outside into heating mode by operating a motorized shutter outside to suck the heated air in the module of solar collector, the shutdown of the heat pump module and fans when of defrosting the evaporator as well as the humidity rate. It also serves as monitor information when problems of operation of the components as well as the state of dirt in the filtration modules and purification.

Ventilation and heating mode of air from outside (Fig. 1) The intake of the outside air and the evacuation of the indoor air are simultaneously.
The two air circuits are always kept apart within the system. The flux air extraction from inside (2) and insufflation from outside (3) are treated so parallel.

In this mode, the motorized shutter (17) closes the opening of a second input air from inside (16) by means of the valve (18) and allows the opening of entry from the outside (3).

To make the system even more efficient in cold periods, we add in option to the system a solar collector installed on an outside wall and across which air fresh is warmed by the sensor, sucked, purified and warmed up more effective since preheated by the solar collector, which allows for savings even bigger energy.

Fresh air from outside is then blown in from the solar collector (25) heats previously cold air before passing into the inlet duct (3).
When this option is installed, the motorized shutter (23) by its valve (24) closes the opening of the outside entrance (21).

Without the solar collector option, fresh air enters the system directly by the conduit (21) of the outer wall (26).

Fresh air from outside (3) is drawn through a box of filtration and air purification (11), warmed by the condenser hot coil (8C) and the air filtered is expelled by the fan (7) inwards. The pump module heat operates from a compressor (8A) and a pressure holder (8D).

The device also allows you to control the humidity level of the air in cold period since dry air from outside is warmed up before going through humidifier (20) to increase the moisture content when identified by hygrometer (15).
) as being too low, which allows a better comfort.

A separate duct (2) sucks the stale air by a fan (6), where it is beforehand filtered (9) and blown into the thermodynamic module (8B) where the stale air then releases heat, which is transferred by the heat pump to the fresh air sucked into the House.
In the cold season, the fans (6) and (7) operate at low speed to to increase the energy efficiency of the heat pump module.

When frost is formed on the evaporator (8B), the thermal probe (8G) gives a signal to the control module (13) which stops the operation of the system of heat pump the time required for the transfer of energy to take place between the condenser (hot) and the evaporator (cold) and restart the pump system to heat when the temperature of the evaporator is restored so that there is no have more than frosted. The water produced by thawing frost is expelled through the drain (19).

Ventilation and cooling mode from the outside (Fig.2) In hot season, the system is reversed using the control monitor which activates the overturn valve (8E) while the coil at the air inlet outside (8B) becomes evaporator (cold) of the thermodynamic system and cools the air hot from the outside (3) and captures the energy of this hot air. The coil (8C) which captures the energy coming from the air inside (2) condenser, either warm, and provides a heat exchange to the system all the air treatment is done contrary to the cold period. In this last mode, the shutter motorized (17) closes the opening of a second air inlet from the inside (16) to way of a valve 18 and allows the opening of the air inlet coming from the outside (3).

Recirculation and ambient air filtration mode (Fig. 3) The recirculation mode is used to filter the indoor air without using the module thermodynamic. This mode is activated by the control monitor (15) and then the thermodynamic system is stopped as well as the fan (6). The blind motorized (17) then closes the outside air inlet (3) by means of a valve (18) and open the entrance of air from inside (16).

The air is sucked by the fan (7) passes through the filter box and purification of the air before being blown inside at the exit (5). The fan (6) as well as the heat pump module do not work in recirculation mode Summary of the invention SUMMARY OF THE INVENTION

The invention this fan is subjected to is based on the laws of the thermodynamic.
That's why the more the gap between the outside and inside temperature is high, more the system is energy efficient because of the energy transfer.

A first object of the invention is therefore to suggest a fan capable of recover with much of the energy captured from the inside towards outside.

Another object of the invention is therefore to suggest a fan with a heat pump.
heat and heat recuperator able to produce more energy than it loses when exhausting stale air even at temperatures under the point of freezing at a lower cost than conventional heating (i, e.
oil, electricity, gas).

Another object of this fan is that it recovers energy from hot air coming from inside through the evaporator coils as well as a transfer of energy to the condenser.

Another object is that this fan is designed to control, by means of a temperature sensor ("Sensor"), the evaporator defrost mode heater of air during periods under the freezing point outside in stopping heat pump module and ventilation the time required for defrosting, the heat transfer from the hot condenser to the frosted evaporator.

Another object is that the indoor / outdoor air exchange rate is controlled in the external inputs and outputs of the air by modulating the speed of fans to allow an ideal flow for the exchange of air in cold periods or summer.

Another object is that this fan is that the air inlet collars for the recirculation and that coming from the outside each have a flap admission motorized synchronized between each to control the origin of the air according to air treatment mode and ensure the pressure balance indoor / outdoor Ambiant air.

Another object of this fan is that it has a filtration box and purification at the outside entrance to eliminate dust, smoke, odors and other contaminants and to ensure the hygiene of the incoming air as well as a filter at the air outlet stale outward for the protection of the components of the device.

Another object of this thermodynamic dual flow fan is that the unit of heating / cooling can be reversed to ensure heating of the air entering during the winter and cooling of the air during the summer.

Another object is that this fan is that it has a second input air coming from the inside for recirculation and air filtering mode only.

Another object of this fan is that its coefficient of performance (EER) for the air cooling allows the cooling and dehumidification of the air during summer periods to ensure better comfort.

Another object of this fan is that it allows to recover in the ambient air of the builds some of the heat produced by other sources, such as cooker, the refrigerator, other heating system and heat sources, and serve as this energy to increase its coefficient of performance (COP).

Another object of this fan is that it saves energy given its coefficient of performance, its high rate of heat recovery in period cold, so heating costs and better comfort at all outside temperatures.

With an improved energy efficiency coefficient due to this model of design he There is energy saving both in terms of recovery and production of energy with the heat pump system.

Claims (14)

1. A ventilation system to evacuate stale air from inside a building outward of said building and to renew said stale air with air from outside treated, said system comprising a housing providing a first and a second room, the first a chamber having a first air inlet communicating with the interior of the building and a first air outlet through which stale air is released outside the building, said second chamber having a second air inlet communicating with the exterior of the building and a second air outlet by which the outside air is directed towards the interior of the building, a first fan to create a first air flow between said first air inlet and said first air outlet of said first chamber, a second fan to create a second airflow between said second air inlet and said second air outlet of said second chamber, said first air flow and said second stream of air being isolated one of the other by said first and second chambers, a first heat exchanger heat disposed in said first chamber between said first air inlet and said first outlet of air to extract the energy of said first air flow before said stale air is rejected at outside the building, a second heat exchanger disposed in said second chamber between said second air inlet and said second air outlet to treat the outside air before it is directed inside the building, and a thermodynamic bridge between said first heat exchanger and said second heat exchanger allowing an exchange of heat energy between said first heat exchanger heat and said second heat exchanger. The system of claim 1, wherein said first fan and said second fan are calibrated to balance said first expelled air flow of the inside to the outside and said second flow of air directed from the outside to the inside of the building. 3. The system of claim 1, wherein said second chamber has a additional air inlet communicating with the interior of the building, said additional air intake being provided with a valve for selectively opening said air inlet additional when the system function in recirculation mode. 4. The system of claim 1, wherein a solar collector is installed on a wall outside the building to preheat the outside air before entering said second chamber. The system of claim 1, wherein a humidifier is installed in downstream of said second air outlet of said second chamber. The system of claim 1, wherein the first heat exchanger heat comprises a first coil installed in said first chamber, said second heat exchanger comprising a second coil installed in said second chamber, said first coil and said second coil being connected by the thermodynamic bridge by means of a compressor and a holder. The system of claim 6, wherein said thermodynamic bridge includes a reversing valve to allow said first and second coils to be used in turn as evaporator and condenser of said thermodynamic bridge. The system of claim 7, wherein the energy transfer between the coil of Evaporator and condenser coil is circulated a refrigerant. The system of claim 1, wherein a filter is disposed in said first bedroom and said second bedroom. The system of claim 8, wherein the refrigerant is circulated by said compressor. The system of claim 1, wherein said first fan and said second fan are at variable speed. The system of claim 6, wherein a thermal probe is installed in said first chamber for detecting a frost condition on said first coil. 13. A building ventilation system, including a plenum box a first passage to guide a first flow of air between a first entry and a first air outlet opening onto the outside of the building, and a second insulated passage first pass to guide a second airflow between a second air inlet to the outside of the building and a second air outlet opening on the inside of the building to allow a contribution outside air inside the building, a first fan for generating said first air flow at through said first passage, a second fan for generating said second airflow through said second passage, a first heat exchanger inside said first passage, a second exchanger heat inside said second passage, said first heat exchanger and said second heat exchanger being connected by a thermodynamic circuit to allow a transfer of energy between said first and said second heat exchanger. The system of claim 13, wherein said first input of air communicates with the interior of the building.