SE1450530A1 - ventilation device - Google Patents

Abstract

ABSTRACT A ventilation device (10) for exchanging room air, comprising a casing (15)having an internal wall (22) dividing the casing (15) into a first compartment(23) and a second compartment (24), each of said compartments (23, 24)having a first opening (25a, 25b) and a second opening (26a, 26b), whereinthe ventilation device further comprises a first heat exchanger (11a) arrangedin the first compartment, a second heat exchanger (1 1 b) arranged in the sec-ond compartment, a first fan (12a) arranged in the first compartment and asecond fan (12b) arranged in the second compartment, said fans being ar-ranged for alternatingly providing, in a first direction, an exhaust airflow (13)from the room to an air supply through the heat exchangers, and alternatinglyproviding, in an opposite second direction, a supply airflow (14) from the airsupply to the room through the heat exchangers.

Description

2 the matrix in a first direction until the incoming air flow leaves the matrix in the opposite direction. Thus, the incoming air flow and the outgoing air flow are moved alternately through the matrix.

One problem with prior art ventilation devices is that they require a lot of space.

Another problem with such devices of known technology is that they can be complicated to install and require installation of cables between different ventilation devices.

SUMMARY OF THE INVENTION An object of the present invention is to avoid the problems of the prior art. The invention results in a compact and efficient ventilation device which is easy to install and which provides efficient ventilation.

The present invention relates to a ventilation device for exchanging air in at least one room, comprising a housing with an inner wall which divides the housing into a first chamber and a second chamber, each chamber having a first opening and a second opening, wherein ventilation device further comprising a first heat exchanger arranged in the first chamber, a second heat exchanger arranged in the second chamber, a first fan arranged in the first chamber and a second fan arranged in the second chamber, the fans being designed to alternately providing an outgoing air flow in a first direction from the room to an air source through the heat exchangers, and alternately providing an incoming air flow in an opposite second direction from the air source to the room through the heat exchangers. Similarly, two or more chambers with a fan and a heat exchanger, such as a regenerative heat exchanger, are combined in a single common housing and can work together in such a way that the total net air flow in ventilation applications can be set down to zero as required. (fluid that enters the space minus the fluid that exits the space is equal to zero). Thus, two or more air flows can be handled by the ventilation device simultaneously. Furthermore, the ventilation device results in a compact and efficient ventilation device that is easy to install and set up.

The first opening may be arranged in a rear side of the housing, and the second opening may be arranged perpendicular to the first opening, e.g. in lateral sides of the housing. Thus, efficient handling of the outgoing air flow and the incoming air flow is achieved, which enables a compact design of the ventilation device and efficient ventilation.

The inner wall may divide the first opening into a first opening portion leading to the first chamber and a second opening portion leading to the second chamber. The first opening can be arranged centrally in the back of the housing. An air flow tube may be connected to the first opening and may be configured to connect the first and second chambers to an air source. The air flow tube may comprise a first channel to the first chamber and a second channel to the second chamber. Thus, one or more ducts which enable the separation of two or more air ducts (normally incoming air and outgoing air) can be arranged in a single round hole in a wall of a building and still utilize the entire cross-sectional area of the round hole in the wall. The separation of the air flows can be accomplished either by using one or more inner walls within the air flow tube or by assembling two or more tubes to form a common air flow tube with substantially the same circular cross-section. Utilizing the entire cross-sectional area in the hole in the wall goes against previous solutions that use two circular pipes in a hole in the wall. Using two pipes in a hole in the wall corresponds to a use of a maximum of 50% of the hole in the wall. According to one aspect of the invention, 50% or more of the cross-sectional area of the hole in the wall, such as substantially the entire hole, may be used for the air flows. The invention leads to the possibility of utilizing the entire cross-sectional area of a single hole in the walls of the building for both outgoing and incoming air flow in order to reduce costs, reduce installation time and improve the handling of the flows. The external geometry of the pipe can be round, which allows the possibility of utilizing the entire cross-sectional area of drilled / cut holes in the building's walls. This solution can be realized either by a tube with a fixed or removable inner wall or by having two tubes, which are semicircularly shaped, which together form the external round geometry. The heat exchanger can be a regenerative heat exchanger with a fixed matrix, which, for example, has a length of less than 100 mm or 50-80 mm. According to one aspect of the invention, the flow length of the regenerative heat exchanger matrix is shorter compared to the prior art with minimal impact on dry energy recovery efficiency. This is made possible by the use of the solid matrix, such as a ceramic solid matrix with continuous channels for the air flow, which results in advantageous heat transfer properties.

It has been found that a flow length of less than 100 mm and even down to 50 mm can still result in a dry energy recovery efficiency of 80% and up.

The fans can be axial fans arranged in a washer or a wall element. Said washer can be made in a construction of sound and / or vibration-damping material, which construction is arranged in abutment against the inside of the housing. Vibration damping solutions for axial fans according to the prior art are a compromise between size and leakage and are not sufficiently effective. Usually, the inside of the housing of ventilation devices are provided with sound-insulating or sound-absorbing materials. Closely related to sound-absorbing materials are materials that are made for vibration damping. According to one aspect of the invention, the fans can be attached directly or indirectly, such as through the fan washer, through the front of the fan (inlet or outlet side) to sound and vibration damping material. The inside of the ventilation device housing can be covered with sound and vibration damping material. A marriage plate with the fan mounted thereon can be slid into grooves in two side parts of the construction of sound / vibration damping material. The remaining two sides of the fan washer can abut against the upper and lower parts of the construction of sound / Vibration damping material, e.g. under load. This solution enables limited contact between the fan washer and the sound / vibration damping material and effectively separates the back and front of the fan (which means no / little leakage).

Further features and advantages of the present invention will become apparent from the description of exemplary embodiments below, the accompanying figures and the dependent claims.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will now be described in more detail with the aid of exemplary embodiments with reference to the accompanying drawings, in which Fig. 1a is a schematic perspective view showing the operation of a ventilation device comprising a regenerative heat exchanger, with an outgoing air flow in a first direction and heat energy in the outgoing air flow is recovered by means of the heat exchanger in a first part of a work cycle, Fig. 1b is a schematic view according to Fig. 1a, in which the incoming air flow is carried in a second direction and heated with the heat storage medium in a second and final part of the work cycle, Fig. 2 is a schematic perspective view of a ventilation device according to an embodiment of the invention, Fig. 3 is a schematic sectional view of the ventilation device according to an embodiment of the invention, Fig. 4a is a schematic perspective view from above of a ventilation device arranged in a room according to an embodiment showing an outgoing air flow and a incoming air flow in a first part of a work cycle, Fig. 4b is a schematic perspective view according to Fig. 4a, showing the outgoing air flow and the incoming air flow in a second and final part of the work cycle, Fig. 5a is a schematic perspective view from above of the ventilation device according to Fig. 2 arranged in a room and showing an outgoing air flow and an incoming air flow in a first part of a work cycle, Fig. 5b is a schematic perspective view according to Fig. 5a, showing the outgoing air flow and the incoming the air flow in a second and final part of the operating cycle, Fig. 6 is a schematic perspective view of an air flow pipe of the ventilation device according to an embodiment, Fig. 7 is a schematic front view of the air flow pipe according to Fig. 6, and Fig. 8 is a schematic perspective view of a fan of the ventilation device according to an embodiment.

THE INVENTION With reference to Fig. 1a and Fig. 1b, a general operation of a ventilation device 10 comprising a regenerative heat exchanger 11 is schematically shown. The ventilation device 10 is designed, for example, to ventilate at least one room, such as a dwelling. The ventilation device 10 comprises a heat exchanger 11 and a fan 12 for providing an air flow through the heat exchanger 11. The heat exchanger 11 comprises a heat storage medium in the form of a solid material matrix with continuous conduits for the air flow. For example, the heat storage medium comprises a ceramic material. The heat exchanger 11 is arranged to recover heat from hot air, whereby heat energy from the hot air is transferred to the heat storage medium of the heat exchanger 11. Then, when cold air is transported through the heat exchanger, heat is transferred to the cold air flow, which is heated. Correspondingly, the heat exchanger 11 can be used to cool an air flow.

Referring to Fig. 1a and Fig. 1b, the air flow through the ventilation device 10 is shown by means of an arrow, the striped part representing hot air and the single-colored part representing cold air. In the example shown in Fig. 1a, the fan 12 provides an outgoing air flow 13 from the room to an air source. Heat from the outgoing air flow 13 is transferred from the building which comprises one or more rooms and on to the air source in a first direction by means of the fan 12. The air source is for example air outside the building, 7 as surrounding outdoor air, or from another space containing fresh air. Heat from the outgoing air flow 13 is recovered by the heat exchanger 11. Then, after a period of time or based on another parameter, the fan 12 changes direction to provide an incoming air flow 14 of fresh air from the air source to one or more of the rooms in the building, which is shown in Fig. 1b, the incoming air flow 14 being heated as it passes the heat exchanger 11. Thus, the fan fan 12 moves air intermittently, i.e. periodically and repeatedly, in the first direction and the second direction to provide the outgoing air flow 13 and the incoming air flow 14, the air flow going back and forth through the ventilation device 10. The outgoing air flow 13 and the incoming air? the fate 14 is brought into abutment against the heat exchanger 11 by alternately passing them through the heat exchanger 11 in a recurring cycle. Thus, a single air flow is passed through the heat exchanger 11 in a cyclically reversible flow. A period or cycle is the time from which the outgoing air flow 13 enters the ventilation device 10 in the first direction and until the incoming air flow 14 leaves the ventilation device in the opposite direction. Thus, the incoming air flow 14 and the outgoing air flow 13 are passed alternately through the heat exchanger 11. For example, the outgoing air flow 13 is directed exclusively through the heat exchanger 11 in the first direction during a first part of the cycle, the incoming air flow 14 being directed exclusively through the heat exchanger. 11 in the other direction during a second part of the cycle. The heat exchanger 11 is, for example, a regenerative heat exchanger with a fixed matrix with continuous ducts for the air flow. For example, the air is moved back and forth through the same channels in the heat exchanger 11, so that the hot outgoing air flow is transported through the channels in the first direction during the first part of the cycle and the cold incoming air flow is transported through the same channels in the opposite second direction during the second part of the cycle.

Referring to Figs. 2 and 3, the ventilation device 10 according to an embodiment of the invention is shown. The ventilation device 10 comprises a housing with a front side 16 and an opposite rear side 17. In the embodiment shown, the housing is box-shaped with an upper side 18, an opposite lower side 19, a left-hand side 20 and a right-hand side 21, the upper, lower, the left and right sides 8-21 extend between and are perpendicular to the front and rear sides 16, 17. Alternatively, the housing 15 is cylindrical in shape or made of another suitable shape with areas corresponding to the upper, lower, left and right sides. dorna 18-21.

The ventilation device 10 comprises an inner wall 22 which divides the housing into a first chamber 23 and a second chamber 24. In the embodiment shown, the first and second chambers 23, 24 are designed in a similar manner and are mirror-inverted relative to each other. The first and second chambers 23, 24, respectively, comprise a first opening 24a, 25b and a second opening 26a, 26b.

The first opening 25a, 25b is connected to an air flow pipe 27 which connects the ventilation device 10 to the air source, such as ambient air, to direct the incoming air flow and the outgoing air flow between the air source and the chambers 23, 24 of the ventilation device 10. 27 arranged to extend through a wall of a building. The air flow pipe 27 is connected to the back 17 of the ventilation device 10. The outgoing air flow and the incoming air flow from the air source and into the chambers 23, 24 of the ventilation device 10 through the air flow pipe 27 are shown by means of arrows A and B in Fig. 2.

The second openings 26a, 26b are arranged to direct the outgoing air flow and the incoming air flow between the room or rooms and the chambers 23, 24 of the ventilation device 10, which is shown by means of the arrows C and D in Fig. 2. For example, the second the second opening 26a of the chamber 24 is arranged in the left side 20 of the housing 15, the second opening 26b of the first chamber 23 being arranged in the right side 21 of the housing 15. Alternatively, the second openings 26a, 26b are arranged in the upper and lower sides 18, 19. Thus the other openings 26a, 26b are arranged in a side of the housing 15 which is perpendicular to the back side 17.

The ventilation device 10 or the housing 15 is, for example, designed with a thickness or a depth x of 100-200 mm or 100-150 mm, a width y of 200-500 mm, 250-400 mm, 300-400 mm or 350-380 mm, and a height z of 200- 500 mm, 250-400 mm or 300 mm. The respective chambers 23, 24 comprise the heat exchanger 11 and the fan 12 for alternately providing the outgoing air flow and the incoming air flow through the first and second chambers 23, 24. Thus, the first chamber 23 comprises a first heat exchanger 11a and a first fan 12a. , the second chamber 24 comprising a second heat exchanger 11b and a second fan 12b. As the outgoing air flow is passed through the first chamber 23, the incoming air flow is passed through the second chamber and vice versa. In the embodiment shown, the heat exchanger 11a, 11b is arranged at the second opening 26a, 26b, the fan 12a, 12b being arranged between the heat exchanger 11a, 11b and the first opening 25a, 25b. Alternatively, the fan 12a, 12b is arranged at the second opening 26a, 26b.

In the embodiment shown, the first opening 25a, 25b of the first chamber 23 and the second chamber 24 are formed by a single opening, such as a single circular hole, in the housing 15, where the opening is divided by the inner wall 22. In the embodiment shown, thus, the first opening 25a, 25b of the first and second chambers 23, 24 is semicircular, the flat side of the first openings 25a, 25b being formed by the inner wall 22.

The heat exchanger 11a, 11b is, for example, a regenerative heat exchanger with a fixed matrix and through-air ducts. According to one embodiment, the heat exchanger 11a, 11b comprises a ceramic material. The thickness t of the heat exchanger 11a, 11b, i.e. the distance from the inlet side of the airflow to the inlet side of the airflow is, for example, less than 90 mm, less than 75 mm or less than 60 mm. For example, the thickness t of the heat exchanger 11 is about 50 mm.

In the embodiment shown, the respective fan 12a, 12b is arranged in a wall element 28 connected to the inside of the housing 15 in order to increase the efficiency of the fans 12a, 12b. According to one embodiment, the ventilation device 10 has the capacity to provide an air flow of at least 0.3 l / s per m2 or at least 0.35 l / s per m2. For example, the ventilation device 10 is designed with an interval of 6-16 l / s with a dry energy recovery efficiency of more than 80%.

Referring to Figs. 4a and 4b, the operation of the ventilation device 10 is shown schematically and simplified. The ventilation device 10 is arranged in a room 29 or a space for exchanging the air inside. Thus, the ventilation device 10 is arranged to provide the outgoing air flow 13 and the incoming air flow 14 simultaneously, the outgoing air flow 13 being passed through the first chamber 23 and the incoming air flow 14 being passed through the second chamber 24. Heat energy is recovered by means of of the heat exchangers 11a, 11b. The fan 12a in the first chamber 23 is arranged to provide the outgoing air flow 13 from the space 29 to the air source in a first direction through the heat exchanger 11a in the first chamber 23, while the fan 12b in the second chamber 24 is arranged to provide the incoming the air flow 14 from the air source to the space 29 in an opposite second direction through the heat exchanger 11b in the second chamber 24, as shown in Fig. 4a. Then, after a predetermined period of time or based on another parameter, the air flow direction is changed through the chambers 23, 24, so that the incoming air flow 14 is passed through the first chamber 23 and the outgoing air flow 13 is passed through the second chamber 24. , as shown in Fig. 4b. For example, the direction of rotation of the fans 12a, 12b is reversed to reverse the air flows.

According to one embodiment, the operation of the spools 12a, 12b is synchronized or coordinated so that the direction of air flow through the first and second chambers 23, 24 is changed simultaneously or with a smaller time delay to reduce noise.

Referring to Figs. 5a and 5b, the operation of the ventilation device 10 is shown schematically according to an embodiment. A first part of the outgoing air flow 13, such as a hot part, is sucked into the first chamber 23 through the second opening 26a by means of the fan 12a inside the first chamber 23.

Thus, the first part of the outgoing air gap 13 is sucked into the first chamber 23 laterally and thus perpendicular to the back of the housing 15. Any heat energy is recovered by the heat exchanger 11a and stored therein. A second part of the outgoing air flow 13, such as a cold part, is blown out of the first chamber 23 through the first opening 26a in a direction perpendicular to the first part of the outgoing air flow 13. At the same time, the incoming air flow 14 is passed through the second chamber 24 in the opposite direction. Then, as shown in Fig. 5b, the air flows through the first and second chambers 23, 24 are reversed and the heat energy is recovered.

Referring to Figs. 6 and 7, the air flow tube 27 is shown in accordance with one embodiment. The air flow tube 27 is arranged to simultaneously carry two air flows in opposite directions, i.e. the outgoing air - fate from the first or second chamber and the incoming air - fate to the first or second chamber.

Thus, the air flow tube 27 is arranged to carry both the incoming air flow and the outgoing air flow to and from the ventilation device 10. According to the embodiment shown, the air flow tube 27 comprises a first channel 30 and a second channel 31. For example, the first and second channels 30, 31 are formed of a wall 32 dividing the air flow tube 27 in the first and second ducts 30, 31.

Alternatively, the first and second channels 30, 31 are assembled to form the air flow tube 27. The first channel 30 is connected to the first chamber 23 and the second channel 31 is connected to the second chamber 24. The cross section of the air flow tube 27 is, for example, circular, wherein the cross section of the first channel 30 is semicircular and the cross section of the second channel 31 is semicircular.

Referring to Fig. 8, the fan 12 according to one embodiment is shown. For example, the fan 12 is an axial fan and provides the air flows in a direction along the axis of rotation of the fan 12. The fan 12 is arranged in a wall element 28 which is connected to the inside of the housing 15 by a bottom 33, an upper part 34 and side parts 35. In Fig. 8 one of the side parts 35 has been removed. The bottom 33, the upper part 34 and the side parts 35 are arranged in a sound-absorbing and / or vibration-damping material and are arranged in direct abutment against the inside of the housing 15 to support the wall element 28 which supports the fan 12 in a sound and / or vibration-damping manner. Thus, the bottom 33, the upper part 34 and the side parts 35 form a construction of damping material which supports the wall element 28 with the fan 12. For example, the wall element 28 supporting the fan 12 is inserted in grooves in the bottom 33, the upper part 34 and the side parts 35 of damping material . The grooves extend into the bottom 33, the upper part 34 and the side parts 35 but not through them, the wall element 28 not being abutting against the housing 15. Thus the entire periphery of the wall element 28 12 is enclosed by the upper part through the bottom 33, the upper part 34 and the side members 35 formed the structure.

Claims (11)

1. A ventilation device (10) for exchanging room air in at least one room (29),comprising a casing (15) having an internal wall (22) dividing the casing (15)into a first compartment (23) and a second compartment (24), each of saidcompartments (23, 24) having a first opening (25a, 25b) and a second open-ing (26a, 26b), wherein the ventilation device (10) further comprises a firstheat exchanger (11a) arranged in the first compartment (23), a second heatexchanger (11b) arranged in the second compartment (24), a first fan (12a)arranged in the first compartment (23) and a second fan (12b) arranged inthe second compartment (24), said fans (12a, 12b) being arranged for alter-natingly providing, in a first direction, an exhaust airflow (13) from the at leastone room (29) to an air supply through the heat exchangers (11a, 11b), andalternatingly providing, in an opposite second direction, a supply airflow (14)from the air supply to the at least one room (29) through the heat exchangers(11a, 11b).

2. A ventilation device according to claim 1, wherein the first opening (25a,25b) is arranged in a rear side (17) of the casing (15), and wherein the sec-ond opening (26a, 26b) is arranged perpendicular to the first opening (25a,25b).

3. A ventilation device according to claim 2, wherein the second opening(26a) of the first compartment (23) is arranged on a first lateral side (21) ofthe device, wherein the second opening (26b) of the second compartment (24) is arranged in an opposite second side (20) of the casing (15).

4. A device according to any of the preceding claims, wherein the internalwall (22) divides a hole in the casing (15) to the first opening (25a) leading tothe first compartment (23) and the first opening (25b) leading to the second compartment (24). 14

5. A device according to any of the preceding claims, comprising an airflowpipe (27) connected to the first opening (25a, 25b) and being arranged forconnecting the first and second compartments (23, 24) to supply air.

6. A device according to claim 5, wherein the airflow pipe (27) comprises afirst duct (30) to the first compartment (23) and a second duct (31) to thesecond compartment (24).

7. A device according to claim 6, wherein the first duct (30) and the second duct (31) together form a pipe having circular cross section.

8. A device according to any of the preceding claims, wherein the heat ex-changer (11a, 11b) is a fixed matrix regenerative heat exchanger.

9. A device according to any of the preceding claims, wherein the heat ex-changer flow length is less than 100 mm or 50-80 mm.

10. A device according to any of the preceding claims, wherein the fans(12a, 12b) are axial fans.

11. A device according to any of the preceding claims, wherein the fans(12a, 12b) are connected to the inside of the casing (15) through a sound and/or vibration dampening material.