CA2911450A1 - Method and system for recovering energy from air exchange in buildings - Google Patents

Abstract

The present invention relates to energy recovery. More specifically, the present invention relates to energy recovery by thermal conduction between fresh air flow and stale air buildings. It is known that air exchanger units exist in many forms to produce an energy transfer between stale air and fresh air buildings. These air exchangers require a relatively bulky volume, generally have a limited heat transfer efficiency and require a defrost cycle according to the outside temperature. In the present invention a conductive heat exchange block provides a heat exchange surface between air currents in the opposite direction. This heat exchange block is composed of an assembly of stamped and striated metal sheets, constituting a separation of the fresh air currents and stale air, in a form allowing a downward channeling of a current of fresh air and a riser up a stale air stream. This system and method allows for high efficiency heat exchange of sensible and latent energies while occupying a smaller volume than existing air exchangers and not requiring a defrost cycle.

Description

2 TITLE OF THE INVENTION
Method and system for recovering energy from air exchange buildings FIELD OF THE INVENTION

The present invention relates to the recovery energy. More specifically, the present invention relates to the energy recovery by thermal conduction between fresh air flows and stale air of buildings.
BACKGROUND OF THE INVENTION

[0004] The rationalization of the use of energy for the air treatment of buildings is the subject of significant efforts account given the constant increase in energy costs and requirements regulatory requirements for ventilation and fresh air supply buildings.

The energy required for the heating or air conditioning of fresh air in buildings is an important part of total needs energy buildings. In fact, air conditioning units new with heat exchanger exist in many forms to produce an energy transfer between stale and fresh air buildings. Although functional these existing applications present gaps of several types that can even make them inoperative or much less effective in extreme weather conditions.

For example, for new air treatment units to Heat exchange by thermal conduction with stale air, such as thermal wheels, heat exchangers per cell cross-flow honeycomb, cyclic energy storage devices in the mass or plate heat exchangers, the housing of air exchanger requires for its installation a relatively bulky in buildings. Considering the decrease in the size of dwellings and buildings for which their use is intended, Positioning constraints of the air exchanger apparatus in function their own occupied volume and their accessibility for maintenance purposes often force users to use a large volume of their mechanical part reserved solely for this apparatus and constituting several cases a loss of space.

[0007] Air exchange apparatus for small buildings or for housings use a heat exchanger per flow cell crossed. These air exchange units often use an exchange block heat of plastic whose heat transfer property are generally limited to efficiencies of between 55% and 65% for heat transfers sensible energy and have in general an efficiency very limited for latent energy heat transfers. Blocks of heat exchange in plastic are often preferred over other more conductive materials such as metals because of their Low cost of production and the relative complexity of a technology comparable made of more conductive materials.

[0008] The configuration of the heat exchange blocks in terms of cross-linked honeycomb cells provide surfaces of heat exchange of incoming and outgoing flows as well as a distribution controlled air flows on the heat exchange surfaces by the forced flow of air into the cells of the exchange blocks energy. The heat exchange blocks consist of many flat honeycomb layers arranged perpendicularly one by report to the other thus tracing the air conduction paths of the flows crossed in perpendicular directions. This provision of cells, favoring a good distribution of the flows in the exchange block, does not exist in the cross-flow trading blocks manufactured by succession of metal sheets or in plate heat exchangers the heat exchange efficiency by conduction can be decreased by a variability of the dispersion of the air flows along the exchange planes thermal.

[0009] Existing air exchangers must have a cycle of defrost usually varying in duration depending on the temperature exterior. The proportions of time of use of the air exchanger in defrost cycle can vary from 10% to 50% of the time of use of these devices. Deicing cycles are important sources of reduced energy efficiency of the air exchanger in addition to cause a return of stale air towards the interior of the building.

Existing air exchangers by flow cell honeycomb crosses have a relatively low efficiency rate for the recovery of the latent heat in the condition of evacuation of hot and humid air in winter or in condition of introduction of hot new air and humid in summer because Frost accumulation on the exchange surfaces or efficiency of relatively low conduction heat exchange.

On existing air exchanger apparatus using a block of heat exchange consisting of multiple layers of leaves Metals whose incoming and outgoing flows are in the same axis linear, counter-flow or unidirectional flow, the relative installation is greatly reduced compared to flow heat exchangers crossed. However, the potential conductivity gain of the metal compared to plastic does not achieve the expected gains due to a distribution preferential flow of air decreasing the transmission efficiency of the heat by conduction.

[0012] There is therefore a need in the art of a method and a building air exchange energy recovery system decreasing the footprint required for its use, increasing transfer efficiency energy by conduction of sensible energy and latent energy and eliminating the need for defrost cycles.

OBJECT OF THE INVENTION
BRIEF DESCRIPTION OF THE FIGURES

Figure 1 is an isometric general view diagram of a building air exchange energy recovery system according to one embodiment of an aspect of the present invention including a cup exposing the inner parts.

Figure 2 is a diagram of a recovery system of air exchange energy of buildings in order to plan a cut according to an embodiment of an aspect of the present invention disclosing the fresh air supply circuit (03);

Figure 3 is a diagram of a recovery system of air exchange energy of buildings in order to plan a cut according to an embodiment of an aspect of the present invention disclosing the exhaust air system (01);

Figure 4 is a diagram of a metal plate (09) constituting part of the heat exchange block (07) according to a mode embodiment of an aspect of the present invention;

Figure 5 is a diagram of an exploded assembly of a heat exchange block system (07) according to one embodiment an aspect of the present invention;

Figure 6 is a diagram of an assembly of a system of heat exchange block (07) according to an embodiment of an aspect of the present invention;

Figure 7 is a diagram of an isometric view top of a gaseous flow and condensate deflector (06) according to a embodiment of one aspect of the present invention; and

Figure 8 is a diagram of a lower isometric view a deflector of gaseous flow and condensate (06) according to a mode accomplishing an aspect of the present invention.

DESCRIPTION OF EMBODIMENTS OF THE INVENTION

It is proposed a method and a recovery system energy exchange of buildings by heat exchanger metal with vertical counterflows.

As illustrated in FIGS. 2 and 3, a system of recovery of air exchange energy of buildings according to a mode of embodiment of one aspect of the present invention generally comprises a stale exhaust air circuit (01) including a fan exhaust air (02), a fresh air supply circuit (03) and a air supply fan (04).

The exhaust air flow is driven by the exhaust fan of air (04) and encounter in exhaust air circuit (03) a filtered (05), a deflector of gas flow and condensate (06) before being driven into the heat exchange block (07), into the fan exhaust air (04) and to the outside of the building.

The fresh air flow is driven by the fan supply air (02) and encounter in the air supply circuit nine (01) a filter (08) is introduced into the heat exchange block (07) and passes into a deflector of gas flow and condensate (06) before to be transferred inside the building.

Stale air and fresh air flows are driven vertically in a heat exchange block (07). The fresh air flow is driven from top down of the heat exchange block (07) and the stale airflow is driven from the bottom to the top of the heat exchange block (07).

The heat exchange block (07) comprises at least five metal plates (09) stamped, stackable and preferably symmetrical in a plane of symmetry (10) shown in Figure 4.

The metal plates (09) are superposed in position alternating in rotation of 180 degrees with respect to the axis of rotation (11), such as shown in exploded view in Figure 5, to form the exchange block of heat (07). The assembly of the metal plates (09) superimposed defines the paths of the stale air flow (03) and the fresh air flow (01) in the volumes of the interstices (12) between the metal plates (09 such so that the stale air flow (03) and the fresh air flow (01) are in traffic counter-clockwise on both sides of a metal plate wall (09).

Part of the stamping of metal plates (09) on each side along a longitudinal axis (13), comprises a fold longitudinal axis (14) delimiting when assembling the exchange block of heat (07), the outer wall of the heat exchanger along an axis longitudinal (13). Once assembled, the longitudinal folds (14) form the sides.

Part of the stamping of the metal plates (09) on each side of a transverse axis (16), includes a transverse fold (17) delimiting the closure of the airflow on half of the lateral face upper part (18) and the lower side face (19) of the exchange block of heat (07 and includes a non-folding portion (20) defining the area introducing or evacuating air flows from the heat exchange block (07).

The upper side face (18) and the lower side face (19) of the heat exchange block (07) formed by both alternations of metal plates (09 show a quarter opening of their surface for the passage of the flow of fresh air (01) and a quarter of their surface for the passage of the exhaust air flow (03). Outside the block heat exchanger (07), each of the air flows is separated by a wall (22). The path of the fresh air flow (01) goes vertically downwards on the upper side face (18) of the heat exchange block (07) and spring on the same side of a longitudinal plane (21) on the lateral face lower (19) of the heat exchange block (07). The course of the airflow stale (03) vertically upwards on the lower side (19) the heat exchange block (07) on the opposite side to a longitudinal plane (21) relative to the fresh air flow (01) and spring on the side face upper (18) of the heat exchange block (07) on the same side of a longitudinal plane (21) that it was introduced.

A shutter (23) is disposed on the side face upper part (18) and on the lower side face (19) to prevent the circulation of an air flow on the top of the upper metal plate (24).

The metal plates (09) comprise streaks of deflection of the airflows (25) stamped. Flow deflection streaks of air (25) have a stamping thickness equal to the interstitial space between the plates of the heat exchange block (07). They form walls delimiting the deflection of the air flows, imposing on the air flows a course distributed over the entire surface of the metal plates (09) and increasing the heat exchange surface against the flow of air separated by a metal plate wall (09).

Deflection streaks of the air flows (25), channeling the flows of air in the interstitial volumes of the heat exchange block (07), in expanding and reconcentrating the airflow. The enlargement action air flow will double the surface normal to the flow inside the interstitial expaces with respect to the input and output surface of the block of heat exchange (07), allowing a halving of the average speed of the flow of air flows in the interstices of the block heat exchange (07).

The metal plates (09) comprise mounds stamped (26) whose stamping thickness equals the interstitial space between the plates of the heat exchange block (07). The mounds stampings (26) contribute to increase the local turbulence of the air flows and to maintain the uniformity of the interstitial spacing between the plates metal (09).

The course of the stale air flow (03) upward and flow fresh air (01) counter-clockwise in the vertical axis causes a progressive heat exchange gradient to prevent, in case where the flow of fresh air is freezing, the formation of frost on a wall of the heat exchange block (07). The water vapor content of the airflow stale (03) in this case is condensed in the lower part of the block heat exchanger (07) and the condensate is drawn downwards by gravity, against the flow of stale air (03), allowing in this condition a recovery of the latent heat contained in the stale air.
This heat exchange block configuration (07) allows a continuous operation of heat exchange between the fresh air flow (01) and the stale airflow (03) without defrosting cycle of the exchange block of heat (07).

In the case where the fresh air is hot and humid, the evacuation air-conditioned stale air allows dehumidification of the fresh air by condensation, the condensate of the fresh air being driven by gravity towards the down in the same direction as the fresh air flow (01).

The condensate of the fresh air flow (01) or the exhaust air flow (03) is evacuated from the bottom of the openings of the lower lateral face (19) of the heat exchange block (07). Condensate drain descends through gravity along the walls of the heat exchanger housing or on the deflectors gas flow and condensate (06). The deflectors of gas flow and condensate (06) act as a separator allowing the passage of airflow up or down and a gravity evacuation of the condensate to one of the drains (27) in the heat exchanger housing (28).

The deflectors of gas flow and condensate (06) include at least 1 cone deflectors (29) and deflectors tapered (29) can be superimposed depending on the flow amplitude air flows.

The superimposed conical shape of the flow deflectors Gaseous and Condensate (06) Concentrates Liquid Condensate Flow down through the drainage tubes (30) and away from the gas stream.

The bottom of the housing of the air exchanger is equipped with two drains (27) each connected to a siphon to allow the evacuation of the condensate of the fresh air flow (01 or the stale air flow (03).

Although the present invention has been described above at means of achievement, it can be modified, while remaining in the context of the nature and teachings of the invention.

Claims (3)

14 1. An energy exchange energy recovery system of buildings, including:
A heat exchange block;
An exhaust fan;
An air supply fan and Insulating housing with compartments;
such as:
the heat exchange block by conduction, constituting a vertical pipe downward for a fresh air flow and a vertical pipe upwards for a stale air stream, consisting of an assembly of stamped metal sheets, establishing a separation of drafts and stale air, provides a heat exchange surface between the drafts at misinterpretation; and the surface of the stamped metal sheets has streaks and mounds, whose height is equal to the height of the interstitial space between the metal sheets, allowing a deflection of drafts over their entire surface. 2. The system of claim 1 comprising a water deflector gas allowing a gravitational separation of the heat condensate latent flow of stale air against the flow of stale air; and a gravitational separation of latent heat condensate from the flow of fresh air circulating in the same direction as the gravity flow of condensate. 3. A method of recovering energy from air exchange of buildings, including conductive heat exchange between a flow of fresh air and a flow of stale air circulating in the opposite direction and vertical on both sides of a metal wall;
such as:
the sensible heat of the air flows is transferred by conduction to through the metal wall separating air flows; and the latent heat contained in the air flows is condensed to the surface of the metal walls and that the condensate is drained by gravity without encountering frost conditions;