NL2017079B1 - Ventilation system with heat pump, and method for operating ventilation system - Google Patents

Abstract

The invention relates to a ventilation system with a fan (16), at least one extraction channel (4, 4 ', ...) connected to the fan for extracting air from a room, and an outlet (6) connected to the fan for the outside extract the building from the extracted air. Furthermore, a heat pump (18) is present whose evaporator (20) can be heat exchanged with the extracted air and whose condenser (28) can be heat exchanged with an object to be heated, such as a hot water supply or central heating installation (19, 23). , 24). With the aid of an auxiliary system (5) designed for controlling the flow of the air to be exchanged with the evaporator (20), the efficiency of the ventilation system can also be ensured in the air with only a low flow being extracted .

Description

Ventilation system with heat pump, and method for operating ventilation system

The invention relates to a ventilation system for a building with at least one room, comprising a fan, at least one extraction channel connected to the fan for extracting air from the at least one room, an outlet connected to the fan for discharging outside the building the air extracted from the at least one room, and a heat pump whose evaporator can be brought into heat exchange with an air flow comprising at least the air extracted from the at least one room, and whose condenser can be heat exchanged with an object to be heated, such as a hot water supply.

Such a ventilation system is known from FR-A-2396930. For buildings such as offices and homes, it is customary to regularly ventilate the rooms. Depending on the use of the room and / or the number of people in it, the air in the room in question can be refreshed to a greater or lesser extent. The air is extracted by the fan, and can enter naturally through ventilation slots and the like. Usually the air is heated in the rooms, both under the influence of the presence of people and through a heating system.

When the heated air is discharged to the outside, however, a not insignificant amount of energy is lost. According to FR-A-2396930, a heat pump is provided for the purpose of utilizing at least a portion of the energy from the heated air. By means of this heat pump the energy from the air can be used to, for example, heat tap water. The energy thus recovered can also be supplied to a central heating.

Such a ventilation system functions reasonably within certain preconditions. One of those preconditions concerns the flow rate of the heated air that flows along the evaporator of the heat pump. This flow has a critical lower limit, under which the performance of the heat pump falls sharply. With traditional ventilation systems that operate more or less continuously, this problem hardly occurs because a certain flow is already maintained as standard. However, in the case of ventilation systems that do not operate continuously but demand-driven, this is different. When demand is controlled by the ventilation system, sensors determine the actual ventilation requirement per room. Depending on this, the flow for the relevant rooms is regulated. An important advantage of this is that it increases the comfort for the people present in the rooms.

If little demand for air exchange is detected, it can happen that the total flow rate falls sharply. This is in itself beneficial to reduce the total energy consumption and also the noise production of the ventilation system. On the other hand, however, the operation of the heat pump can be adversely affected if the total flow rate falls too strongly.

In itself, the operation of the heat pump could be maintained if more air were drawn out of the rooms than is necessary for the required refresh. However, this extra air, which first enters from outside the rooms, must be warmed up, which reduces the yield of the ventilation system. A major drawback is furthermore that the increased flow rate thus obtained is no longer well adapted to the needs of the people in the various rooms, whereby the comfort decreases.

The object of the invention is therefore to provide a ventilation system in which the air exchange in the rooms can be regulated purely on demand per room, but in which the operation of the heat pump can be ensured at all times. That object is achieved by a ventilation system for a building with at least one room, comprising a fan, a plenum room, at least one extraction channel connected to the plenum room for extracting air from the at least one room, a supply channel connected to the plenum room that is outside each room around which a suction channel is connected and via which supply channel air outside of each room to which a suction channel is connected can be supplied to the plenum chamber, a discharge connected to the plenum chamber for discharging the air from the at least outside of the building one room with extracted air, a heat pump whose evaporator can be brought into heat exchange with an air flow that comprises at least the air extracted from the at least one room, and whose condenser can be heat exchanged with an object to be heated, such as a hot water supply or central heating installation and a help system m designed to control the flow rate of the air flow to be exchanged with the evaporator.

If the flow rate of ventilation air available for the operation of the heat pump becomes insufficient, an adjustment can always be made by means of the control device, so that the desired flow rate can nevertheless be achieved. To this end, the evaporator can be heat exchanged with an additional air flow that can be supplied outside the room to which a suction channel is connected to the evaporator through the supply channel. An example is mentioned as a supply channel that extends directly from the outside of the building to the plenum chamber, such as from under an external solar panel, and / or via a ground pipe. It is important that the supply channel is isolated from the rooms and the associated extraction channels, so that the additional air in front of or near the heat pump can be mixed with the extracted air.

The auxiliary system is preferably designed for controlling the flow of the additional air flow through the supply channel. In a practical embodiment the auxiliary system comprises: - a plenum chamber, to which plenum chamber each suction channel is connected via a supply opening, the supply channel is connected via a supply channel opening and the discharge is connected via a discharge opening, such that an air flow path extends between on the one hand each suction channel and supply channel, and the discharge, on the other hand, - the heat pump evaporator, which evaporator is in heat exchange with the air flow path between, on the one hand, each exhaust channel and the supply channel, and the discharge, on the other hand, - adjustable valves for controlling the flow in each exhaust channel and supply channel, - one or more sensors for measuring the air flow to which the evaporator is exposed, - a control device for operating the valve in the supply channel opening on the basis of the measured air flow.

In addition, the auxiliary system may comprise: - sensors for detecting at least a property of the air in each supply opening, optionally a property of the air in the supply channel opening and optionally a property of the air in the discharge opening, - wherein the control device is designed for control of the position of the valves on the basis of the air property (s) detected by the sensors.

The help system can take into account the demand for ventilation in each room separately. On the other hand, this demand can be compared with the demand for air at the heat pump's evaporator. If necessary, the auxiliary system ensures that the valve of the supply channel is opened to additionally guide air together with the extracted air over the evaporator, so that the heat pump can continue to function as desired.

In that connection, the sensor / sensors are / are provided for measuring the air flow over the evaporator; the control device is thus designed to operate the valve in the supply channel opening on the basis of the measured air flow over the evaporator.

The invention also relates to the auxiliary system for a ventilation system as described above, comprising: - a plenum chamber provided with at least one supply opening to which a suction channel can be connected, a supply channel opening to which a supply channel can be connected and a discharge opening to which a discharge can be connected, such that an air flow path extends between each supply opening and the supply channel opening on the one hand, and the discharge opening on the other hand, - a heat pump evaporator, which evaporator is located in the air flow path between each supply opening and the supply channel opening on the one hand, and the discharge opening on the other hand, - controllable valves for controlling the flow rate in each supply opening and the supply channel opening, - one or more sensors for measuring the air flow along the air flow path and to which the evaporator is exposed, and - a control device for operating the valve in the supply channel opening on the basis of the measured air flow.

The auxiliary system may further comprise: - sensors for detecting at least one property of the air in each supply opening, optionally a property of the air in the supply channel opening and optionally a property of the air in the discharge opening, - wherein the control device is designed for control the position of the valves on the basis of the properties detected by the sensors of the air.

In addition, the invention relates to a method for operating the ventilation system, comprising the steps of: - supplying the heat pump's evaporator with air that has been extracted from at least one room, - determining the total instantaneous flow rate of the air extracted by extracting air air flow obtained from each room, - determining the minimum required air flow rate required for the operation of the heat pump, - comparing said total instantaneous flow rate and the minimum required flow rate, - supplying the evaporator with additional air outside each room that is connected to an exhaust duct if the total instantaneous flow of the airflow obtained by extracting air from each room is lower than the minimum required flow of airflow that is necessary for the operation of the heat pump.

Further, the method may include supplying the heat pump evaporator only with air that has been extracted from each room if the total instantaneous flow rate of the airflow obtained by extracting air from each room is equal to or higher than the minimum required flow rate of the air flow that is necessary for the operation of the heat pump.

The invention will be further elucidated on the basis of an exemplary embodiment of a ventilation system shown in the figures.

Figure 1 shows a building with the ventilation system according to the invention. Figure 2 shows a cut-away view of the auxiliary system according to the invention.

The building shown in Figure 1 has a number of rooms 1, 1 "..., which have a supply 2, 2" ... for outside air. Air can be drawn out of the rooms through extraction openings 3,3 ", ... which are connected to an extraction channel 4, 4". Each extraction channel is connected to the auxiliary system 5 with a fan, which in turn discharges the extracted air to the outside via the exhaust channel 6. To the auxiliary system is also connected a further-described supply channel 7, which is directly connected to the outside air and that the flow is not connected to one of the rooms 1, Γ, ....

The auxiliary system 5 is further shown in figure 2. A cover (not shown) can seal the housing 11 airtight with respect to the peripheral edge 12 thereof. A number of supply openings 8, 8 ", ... are present in the wall of the housing 11, the passage of which can be controlled with the aid of the valves 13, 13", .... Just as many suction channels can be connected to these supply openings. Furthermore, the wall of the housing 11 has a discharge opening 9 to which the discharge channel 6 can be connected.

The space in the housing 11 is determined by a plenum chamber 29 which is divided by a partition 14. On one side of the partition in the plenum chamber 29, the supply openings 8, 8 ', ... out and on the other side open in the plenum chamber. the discharge opening 9 opens into the plenum chamber 29 of the bulkhead. The partition 14 has a permeable grid 15. The fan 16 is connected to the outlet opening 9; in operation, the fan sucks air through the supply openings 8, 8 ', ... in the housing 11, through the grille 15 in the partition 14 and discharges the air to the outlet 9. Depending on the position of the various valves 13, 13 ', .... a larger or smaller flow rate is thereby obtained in the channels connected to those supply openings. This means that more or less air can be extracted from the relevant room accordingly.

The position of the valves can be adjusted on demand. In that connection, for example, CO2 sensors 17, 17 ", ..., humidity sensors and the like may be present in the relevant rooms, channels or in the supply openings 8, 8", ... The values detected by these sensors are transmitted to the control device 27. On the basis of the software of this control device, the tilting positions and possibly the performance of the fan can then be adjusted.

The air drawn in by the fan is heated in the rooms and has a certain energy content. The heat pump 18 is provided for the purpose of useful use of this energy content. The heat pump 18 has an evaporator 20 along which the air drawn in by the fan 16 strokes. The heat present in the air is absorbed by the evaporator 20, and according to the cycle known per se, the fluid present in the heat pump is fed by means of pump 21 and circuit 22 to the condenser 28. There, heat is absorbed by the heating circuit 23 with heat dissipation panel 19; in this circuit liquid is pumped around by the pump 24.

The operation of the heat pump 18 is strongly influenced by the flow rate of the air flow generated by the fan. If the demand in the rooms is low, the flow rate of the air flow along the evaporator can become so low that the operation of the heat pump is greatly reduced. With the aim nevertheless of guaranteeing a sufficiently high flow rate, and thereby optimizing the operation of the heat pump, the supply channel 7 is provided which is connected to the supply channel opening 10 which opens into the plenum chamber 29 of the housing 11, namely to that side of the baffle 14 where also the supply openings 8, 8 ', .... open into the plenum chamber 29. This supply channel opening 10 has a valve 25, the position of which can be controlled by the control device 18. The sensor connected to the control device 18 26 near the grid 15 measures the flow there over the evaporator 20. If, as mentioned above, this proves too low for optimum operation of the heat pump 18, the control device 18 opens the valve 25 in such a way that additional air can flow in from outside the building into the plenum chamber 29 in which also the supply openings 8,8 ', ... open.

Even with a low flow through the supply openings 8, 8 ", ..., a desired, sufficiently high flow along the evaporator 18 can thus nevertheless be obtained. It is not necessary to increase the flow rate supplied by the rooms. In this way, both the comfort in the rooms can be maintained, while at the same time efficient energy recovery for central heating and the like remains possible.

List of reference characters I, Γ, ... Departure 2.2 ', ... Supply 3.3', ... Exhaust opening 4., 4 '... Exhaust channel 5. Auxiliary system 6. Exhaust channel 7. Supply channel 8., 8 ', ... Supply opening 9. Supply opening 10. Supply channel opening II. Housing 12. Wall housing 13., 13. ', ... Valve 14. Baffle 15. Grille 16. Fan 17., 17', ... Sensor 18. Heat pump 19. Heat transfer panel 20. Evaporator 21. Pump 22 Heat pump circuit 23. Central heating circuit 24. Central heating pump 25. Valve 26. Evaporator airflow sensor 27. Control device 28. Condenser 29. Plenum chamber

Claims (15)

A ventilation system for a building with at least one room (1, Γ, ...), comprising a fan (16), a plenum chamber (29), at least one extraction channel (4, 4 ', connected to the plenum chamber (29). ..) for extracting air from the at least one room, a supply channel (7) connected to the plenum chamber (29) which is diverted outside each room (1, Γ, ...) on which a suction channel (4, 4 ') , ...) is connected and through which supply channel air outside each room to which an extraction channel is connected can be supplied to the plenum chamber, a discharge (6) connected to the plenum chamber (29) for the outside through the fan (16) discharging the building from the air extracted from the at least one room, a heat pump (18) whose evaporator (20) can be brought into heat exchange with an air flow comprising at least the air extracted from the at least one room, and whose condenser (28) ) is heat transferable with an object to be heated, such as a hot water supply or central heating installation (19, 23, 24), as well as an auxiliary system (5) designed to control the flow of the air flow to be exchanged with the evaporator (20). Ventilation system according to claim 1, wherein at least one supply (2, 2 ', ...) is provided for supplying air from the outside of the building into the at least one room (1, Γ, ...) under the influence of of suctioning air from the at least one room through the fan (16). Ventilation system according to claim 1 or 2, wherein the auxiliary system (5) is designed for controlling the flow of the air flow obtained by extracting air from the at least one room (1, Γ, ...). Ventilation system according to any one of the preceding claims, wherein the auxiliary system is designed for also bringing the evaporator (20) into heat exchange with an additional air flow via the supply channel (7). Ventilation system according to claim 4, wherein the supply channel (7) extends directly from the outside of the building to the plenum chamber (29), such as from under an external solar panel, and / or via a ground pipe. Ventilation system according to claim 4 or 5, wherein the auxiliary system (5) is designed for controlling the flow of the additional air flow through the supply channel (7). A ventilation system according to claim 6, wherein the auxiliary system comprises: - the plenum chamber (29), to which plenum chamber each suction channel (4, 4 ', ...) is connected via a respective supply opening (8, 8', ...) , the supply channel (7) is connected via a supply channel opening (10) and the discharge (6) is connected via a discharge opening (9), such that an air flow path extends between each suction channel and the supply channel on the one hand, and the discharge on the other hand, evaporator (20) of the heat pump (18), which evaporator is located in the air flow path between, on the one hand, each exhaust channel and the supply channel, and the outlet, on the other hand, - adjustable valves (13, 13 ', 25) for controlling the flow in each exhaust channel and in the supply channel, - one or more sensors (26) for measuring the air flow to which the evaporator (20) is exposed, - a control device (27) for operating the valve (25) in the supply channel opening (10) based on the measured n airflow. Ventilation system according to claim 7, wherein the auxiliary system comprises: - sensors (17, 17 ', ...) for detecting at least one property of the air, such as the CO2 content and / or the air humidity, in each exhaust duct ( 4, 4 ', ...), optionally a characteristic of the air in the supply channel (7) and optionally a characteristic of the air in the discharge (6), - wherein the control device (27) is designed for the air property (s) detected by the sensors controlling the position of the valves (13, 13 ', ..., 25). Ventilation system according to claim 8, wherein the control device (27) is designed for operating the valve (25) in the supply channel opening (10) based on the air flow measured by sensor (26) to which the evaporator (20) is exposed. A ventilation system according to any one of claims 7-9, wherein the fan (16) is provided in the plenum chamber (29), and is preferably connected to the discharge opening (9). Auxiliary system for a ventilation system according to any one of the preceding claims, comprising: - a plenum chamber (29) provided with at least one supply opening (8, 8 ', ...) to which a suction channel (4, 4', ...) can be connected , a supply channel opening (10) to which a supply channel (6) can be connected and a discharge opening (9) to which a discharge can be connected, such that an air flow path extends between on the one hand each supply opening and the supply channel opening, and the discharge opening on the other hand, - a in the plenum chamber evaporator (20) provided with a heat pump (18), which evaporator is located in the air flow path between, on the one hand, each inlet opening and the inlet channel opening, and the outlet opening, on the other hand, - controllable valves (13, 13 ', ...; 25) for controlling of the flow rate in each supply opening and the supply channel opening, - one or more sensors (26) for measuring the air flow to which the evaporator (20) is exposed, and - a control device (27) ) for operating the valve (25) in the supply channel opening (10) based on the measured air flow. Auxiliary system according to claim 11, comprising: - sensors (17, 17 ', ...) for detecting at least one property of the air, such as the CO2 content and / or the air humidity, in each supply opening (8, 8) ', ...), optionally a property of the air in the supply channel opening and optionally a property of the air in the discharge opening, - wherein the control device (27) is designed for the property (s) detected by the sensors of the air regulating the position of the valves (13, 13 ', ..., 25). Auxiliary system according to claim 11 or 12, wherein a fan (16) is provided in the plenum chamber (29), which fan is preferably connected to the discharge opening (9). Method for operating the ventilation system according to one of claims 1-13, comprising the steps of: - supplying to the evaporator (20) the heat pump (18) air that has been extracted from at least one room (1, Γ) ...), - determine the total instantaneous flow rate of the airflow obtained by extracting air from each room, - determine the minimum flow rate required for the operation of the heat pump (18), - compare of said total instantaneous flow rate and the minimum required flow rate, - supplying the evaporator (20) with additional air outside each room connected to an exhaust duct (4,4 ', ...) if the total instantaneous flow rate of the the extraction of air from each room obtained air flow is lower than the minimum required air flow rate necessary for the operation of the heat pump (18). Method according to claim 14, comprising exclusively supplying to the evaporator (20) the heat pump (18) air that has been extracted from each room (1, Γ, ...) if the total instantaneous flow rate of the suction airflow obtained from air from each room is equal to or higher than the minimum required airflow flow required for the operation of the heat pump (18).