NL2018676B1 - Air-conditioning system and method for controlling a air-conditioning system - Google Patents

Abstract

The present invention relates to a method for controlling a climate control system of a building. The air-conditioning system comprises a plenum, an air outlet with an outlet valve, and an air inlet with a inlet valve for controlling the flow of supplied outside air. The air-conditioning system further comprises an air heat pump with an evaporator, a single fan, and a control device for controlling the at least one discharge valve, the position of the discharge valve being adjusted by means of the control device as a function of a desired discharge rate. Furthermore, the pressure in the plenum is adjusted by means of the control device as a function of the desired discharge flow rate.

Description

Air-conditioning system and method for controlling a air-conditioning system

The present invention relates to a method for controlling a climate control system of a building. The air-conditioning system comprises a plenum, an air outlet for discharging indoor air from at least one room of a building to the plenum, and an outlet valve for controlling the flow of air discharged from the at least one room of the building, and an air supply for the supplying outside air to the plenum, and a supply valve for controlling the flow of supplied outside air.

The air-conditioning system further comprises an air heat pump with an evaporator for exchanging heat between air passed over the evaporator and the evaporator, a single fan for sucking indoor and outdoor air through the at least one air outlet and the at least one air supply, and for driving the sucked-in indoor and outdoor air over the evaporator, and a control device for controlling the at least one discharge valve, wherein the position of the discharge valve is adjusted by means of the control device as a function of a desired discharge flow rate. The present invention further relates to a climate system.

State of the art

Such a climate system is known from FR29411521. A disadvantage of this system is that, in heat exchange operation, continuous control of the fan is required. Because the fan is continuously controlled by a control device, the fan will require more maintenance, be replaced faster and produce more noise by adjusting the fan speed. Furthermore, the climate system will also consume more energy.

Object of the invention

An object of the invention is to provide an improved method for controlling a climate system. A further object of the invention is to provide a method and air-conditioning system that are more energy efficient.

Description of the invention

This object is achieved with the method according to the invention as described in claim 1. By controlling the pressure dP in the plenum by means of the control device, the desired discharge flows Qa, Qb, Qc can be achieved. If the control of the discharge valves proves insufficient to reach the flow through the discharge, the control device will control the pressure dP in the plenum in order to be able to reach the desired discharge flow Qa, Qb, Qc. In a preferred embodiment of the invention, the control device will control the position of the supply valve to control the pressure dP in the plenum.

It is advantageous that the flow rate of air Q that is driven over the evaporator can be set to a maximum for a certain desired discharge rate Qa, Qb, Qc. In use, one control valve can always be set to an open position. The supply valve will preferably be set in a maximum open position.

This will allow more energy to be extracted from the air that is driven over the evaporator, compared to methods in which a fixed flow rate is driven over the evaporator.

In a preferred embodiment of the invention, the speed of the fan will be kept constant.

This object is further achieved with the method according to the invention as described in claims 2-10.

The invention further relates to a climate system as described in claims 11-20.

Brief description of the figures

The invention will be explained in more detail below with reference to an exemplary embodiment shown in the drawing.

Figure 1 shows a schematic cross-section through a building with a climate system according to the invention;

Figure 2 shows a schematic cross-section through a first embodiment of a climate control device;

Figure 3 shows a cut-away view of a second embodiment of a climate control device.

Extensive description of the figures

Figure 1 shows a schematic cross-section through a multi-room building 1 and a climate control system 10 comprising a climate control device 100 and an air heat pump 110 with an evaporator 111 in the climate control device 100.

The air-conditioning system 10 further comprises a discharge with a plurality of air discharge channels 20 for discharging indoor air from a plurality of rooms of the building 1, a supply with an air supply channel 30 for supplying outside air to the air-conditioning device 100, and an air outlet channel 40 for discharging air from the air conditioning device 100.

Each air exhaust duct 20 is connected upstream to a space of the building and is connected downstream to the air conditioning device 100. The air supply duct 30 is connected upstream to the supply opening in the building and is connected downstream to the air conditioning device 100. The air outlet duct 40 is upstream connected to the air-conditioning device 100 and connected downstream to a drain opening in the building.

In use, indoor air from the building 1 is supplied via the air exhaust ducts 20 to the air-conditioning device 100. In the air-conditioning device 100, the indoor air is driven over the evaporator 111 and discharged from the air-conditioning device 100. The indoor air is further removed from the building 1 via the air outlet channel 40.

Furthermore, in heat pump operation of the air-conditioning device 100, outside air is supplied to the air-conditioning device 100 via the air supply duct 30. In the air-conditioning device 100, the outside air is mixed with the inside air and driven together over the evaporator 111 and discharged from the air-conditioning device 100. The mixed air is further discharged from the building 1 via the air outlet channel 40.

Figures 2 shows a schematic cross-section of a climate control device 100 according to the invention. The air-conditioning device 100 comprises a plurality of air discharge connections 120a, 120b, 120c for receiving discharged indoor air, an air supply connection 130 for receiving outside air, and an air outlet connection 140 for discharging air.

In each air outlet connection 120a; 120b; 120c is a discharge valve 121a; 121b; 121c provided with a resistance value K * a; K * t>; K * c. A supply valve 131 with a resistance value K * o is provided in the air supply connection 130.

Each air exhaust connection 120a, 120b, 120c can be connected to an air exhaust channel 20a; 20b; 20c of a climatization system 10, wherein each air exhaust duct 20a; 20b; 20c a resistance value Ka; K B; Kc has. The air supply connection 130 can be connected to an air supply channel 30 of the air-conditioning system 10, wherein the air supply channel 30 has a resistance value Ko. The air outlet connection 140 is connectable to an air outlet channel 40 of the air-conditioning system 10.

The evaporator 111 of the air heat pump 110 is adapted to exchange heat between air passed over the evaporator and a fluid in the evaporator 111. The evaporator 111 shares an internal volume of the air-conditioning device 100 in a plenum 101 and a discharge volume 102. In the plenum 101, where the inside air and the outside air are mixed, a pressure dP is measured. The dew is measured using pressure sensor 160.

The air-conditioning device 100 further comprises only a single fan 150 for sucking through the air discharge connections 120a, 120b, 120c and the air supply connection 130, respectively, indoor and outdoor air, and for driving the air from the plenum 101 to the evaporator 111 to the discharge volume 102.

In one embodiment of the air-conditioning device 100, furthermore, a heating unit may be provided for heating the outside air prior to mixing the inside air and the outside air in the plenum 101.

In use of the air-conditioning device 100, on the one hand a ventilation company and on the other hand a heat pump company can be distinguished, in which the air heat pump 110 is put out of use in ventilation company.

In ventilation operation of the air-conditioning device 100, indoor air from the building 1 is supplied via air-discharge connections 120a, 120b, 120c to the air-conditioning device 100 with desired discharge rates Qa, Qb, Qc. In the air-conditioning device 100, the indoor air is driven over the evaporator 111 and discharged from the air-conditioning device 100 via the fan 150 and the air outlet connection 140 with an outlet flow rate Q.

Furthermore, in heat pump operation of the air-conditioning device 100, outside air is supplied via the air supply connection 130 to the air-conditioning device 100 with a supply flow rate Qoda. driven and discharged from the air-conditioning device 100 via the fan 150 and the air outlet connection 140 with an outlet flow rate Q.

If the air heat pump 110 is an air-to-water heat pump, water can be heated in heat pump operation for use in central heating (central heating) or as domestic hot water (DHW).

The air-conditioning device 100 further comprises a control device 200 for controlling the air-conditioning device 100. The control device 200 is adapted to control the discharge valves 121a-c for controlling the flow of discharged air. The control device 200 is also adapted to control the supply valve 131 for controlling the pressure dP in the plenum 101. The control device 200 is furthermore adapted to control the fan 150 for controlling the pressure dP in the plenum 101 by using the speed of the fan 150.

The control of the air-conditioning device 100 comprises the control of the flow of exhaust air by means of the control device 200 by controlling the discharge valves 121a-c and the pressure dP in the plenum 101. During the control of the air-conditioning device 100 will always be fully open at least one discharge valve 121 and / or the supply valve 131. This is preferably the supply valve 131. The discharge valve 121 and the supply valve are so-called control valves. A control valve according to the invention is a valve which has at least one position between an open position (maximum position) and a closed position (minimum position).

In ventilation operation of the air conditioning device 100, when the air heat pump is out of use, the supply valve in the air supply connection 130 is in the closed position. The controller 200 controls the drain valves to achieve the desired drain rate Qa, Qb, Qc. The control device 200 controls the discharge valves 121a-c as a function of the measured pressure dP and the resistance value of the channels IC; K B; Kc to set the required discharge flows Q ', Qb, Qc.

If the desired discharge rate Qa, Qb, Qc can be achieved by controlling the discharge valves 121a-c without at least one discharge valve 121a-c in a fully open position, the control device 200 controls the fan to control the speed of the fan 150. decrease such that the pressure in the plenum 101 is reduced. The control device 200 reduces the speed of the fan 150 and controls the discharge valves 121a-c until at least one discharge valve 121a-c must be in a fully open position to set the desired discharge rate Qa, Qb, Qc.

If the desired discharge rate Qa, Qb, Qc cannot be achieved by controlling the discharge valves 121a-c with at least one discharge valve 121a; 121b; 121c in a fully open position, the control device 200 controls the fan to increase the speed of the fan 150 such that the pressure in the plenum 101 is increased. The control device 200 increases the speed of the fan 150 until the desired discharge rate Qa, Qb, Qc can be achieved in all discharge valves 121a-c with at least one fully open discharge control valve and then controls the discharge valves 121a-c to the desired discharge rate Qa, Qb , Qc is set in all discharge valves 121a-c.

In heat pump operation of the air conditioning device 100, when the air heat pump 111 is in use, the supply valve in the air supply connection 130 (initially) is opened to a maximum in order to drive an as high as possible air flow over the evaporator. This will allow a maximum of energy to be extracted from the mixing air. During heat pump operation, the control device 200 will not control the fan 150, and the speed of the fan 150 is maintained at a certain value. The control device 200 controls the discharge valves as a function of the measured pressure dP and the resistance value of the channels K K B; Kc to set the required discharge rates Qa, Qb, Qc.

If the desired discharge flow rate Qa, Qb, Qc cannot be achieved by controlling the discharge valves 121a-c, the control device 200 controls the supply valve to increase the pressure in the plenum 101. The controller 200 partially closes the supply valve such that the pressure in the plenum 101 increases until the desired discharge rate Qa, Qb, Qc can be achieved by controlling the discharge valves 121a-c and controls the discharge valves 121a-c to the desired discharge flow rate Qa, Qb, Qc is set in all discharge valves 121 ac.

If the desired discharge flow Qa, Qb, Qc can be achieved by controlling the discharge valves 121 ac without at least one control valve 121 ac, 131 (discharge valve 121a-c or supply valve 131) in a fully open position, the control device 200 controls the supply valve 131 to reduce the pressure in the plenum 101. The control device 200 opens the supply valve 131 so that the dew in the plenum 101 lowers, until at least one control valve 120a-c, 130 must be in a fully open position in order to achieve the desired discharge rates Qa, Qb, Qc. Thereafter, the controller 200 controls the drain valves 121a-c until the desired drain rate Qa, Qb, Qc is set in all drain valves 121a-c.

The air-conditioning device 100 according to a second embodiment is further shown in Figure 3. A cover (not shown) can seal a housing airtightly relative to a peripheral edge thereof. A number of air discharge connections 120a, 120b, ... are present in the wall of the housing, the passage of which is adjustable with the aid of the discharge valves 121a, 121b, .... .. to connect. Furthermore, the wall of the housing has an air outlet connection 140 to which an air outlet channel 40 can be connected.

The space in the housing is divided by a baffle 103. On one side of the baffle 103 the air discharge connections 120a, 120b, ... open out in a plenum 101 and on the other side of the baffle the air outlet connection 140 opens into an outlet volume 102 from. The partition 103 has a permeable grid 104. The fan 150 is connected to the air outlet connection 140; in operation, the fan sucks air through the air outlets 120a, 120b, ... into the housing, through the grille 104 into the baffle 103 and discharges the air to the air outlet connection 140. Depending on the position of the various valves 121a, 121b, .... a larger or smaller flow rate is thereby obtained in the channels connected to said air discharge connections. 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 122a, 122b, ..., humidity sensors and the like can be present in the relevant rooms, channels or in the air discharge connections 120a, 120b, .... The values detected by these sensors are transmitted to a control device 200. On the basis of the software of this control device 200, the tilt positions and possibly the performance of the fan 150 can then be adjusted.

The air drawn in by the fan is heated in the rooms and has a certain energy content. A heat pump 110 is provided for the purpose of useful use of this energy content. The heat pump 110 has an evaporator 111 along which the air drawn in by the fan 150 flows. The heat present in the air is absorbed by the evaporator 11, and according to a cycle known per se, the fluid present in the heat pump 110 is supplied to the condenser 112 by means of pump 113 and circuit 114.

The operation of the heat pump 110 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 of nevertheless ensuring a sufficiently high flow rate, and thereby optimizing the operation of the heat pump, an air supply channel is provided which is connected to the air supply connection 130 which opens into the plenum 101. This air supply connection 130 has a supply valve 131, of which the position can be controlled by the control device 200. The sensor 160 connected to the control device 200 measures the pressure dP in the plenum 101. If this turns out to be too low for an optimum discharge of air from the rooms, the control device 200 closes the supply valve 131 in such a way that the pressure in the plenum 101 rises and that sufficient air can be discharged from the rooms.

Even with a low flow through the air discharge connections 120a, 120b, ..., a desired, sufficiently high flow along the evaporator 111 can be obtained. It is not necessary to increase the flow rate supplied by the rooms. Thus, both the comfort in the rooms can be maintained, while at the same time efficient energy recovery for the central heating and the like remains possible.

List of reference signs 1. Building 10. Air-conditioning system 20,20a-c. Air outlet channel 30. Air supply channel 40. Air outlet channel 100. Air conditioning device 101. Plenum 102. Exhaust volume 103 Bulk 104 Air permeable grid 110. Air heat pump 111. Evaporator 112. Condenser 113. Pump 114. Circuit 120a-c. Air outlet connection 121a-c, Drain valve 122a-c Air parameter sensor 130. Air supply connection 131, Supply valve 140. Air outlet connection 150. Fan 160. Pressure sensor 200. Control device

Qoda Supply rate

Qa, Qb, Qc Desired Drainage flow Q Outlet flow rate dP Press in the Plenum

Claims (20)

A method for controlling a climate control system (10) of a building (1), the climate control system (10) comprising: a plenum (101); an air outlet (20a, 120a; 20b, 120b; 20c, 120c) for discharging indoor air from at least one space of a building (1) to the plenum (101), and a discharge valve (121a; 121b; 121c) for controlling of the flow rate of air discharged from the at least one space of the building (1); an air supply (30, 130) for supplying outside air to the plenum (101), and a supply outlet (131) for controlling the flow of supplied outside air; an air heat pump (110) with an evaporator for exchanging heat between air passed over the evaporator and the evaporator (111); a single fan (150) for sucking through the at least one air outlet (20a, 120a; 20b, 120b; 20c, 120c) and the at least one air supply (130) in the plenum (101), respectively, indoor and outdoor air, and for driving the aspirated indoor and outdoor air over the evaporator (111); and a control device (200) for controlling the at least one discharge valve, wherein the position of the discharge valve is adjusted by means of the control device (200) as a function of a desired discharge rate Qa, Qb, Qc, wherein by means of the control device ( 200) the pressure dP in the plenum (101) is set as a function of the desired discharge rate Qa, Qb, Qc. Method according to claim 1, wherein the control device (200) is adapted to control the at least one supply valve and wherein in heat pump operation of the air-conditioning device (100), when the air heat pump (110) is in use, by means of the control device (200) adjusts the position of the supply valve as a function of the pressure dP in the plenum (101). A method according to claim 1 or 2, wherein in heat pump operation of the air conditioning device (100), when the air heat pump (110) is in use, the speed of the fan (150) is kept constant. A method according to claim 2 or claim 3, wherein the flow rate of air Q driven over the evaporator (14) corresponds to a maximum value as a function of the desired discharge rate Qa, Qb, Qc. A method according to any one of the preceding claims, wherein the control device (200) is adapted to control the fan (150), and in ventilation operation of the air-conditioning device (100), when the air heat pump (110) is out of use, the speed of the fan (150) is adjusted by means of the control device (200) in function of the pressure dP in the plenum (101). The method of claim 5, wherein in ventilation operation of the air-conditioning device (100), the position of the at least one supply valve is kept constant. A method according to claim 5 or claim 6, wherein the feed rate Qoda corresponds to a minimum value. A method according to any one of the preceding claims 2-4, wherein the air-conditioning device (100) in the plenum (101) comprises at least one dew sensor (200) for measuring an air pressure in the plenum (101); and wherein, in heat pump operation, each supply valve is controlled as a function of measured values of measurements with the pressure sensor located in the plenum. A method according to any one of the preceding claims 5-7, wherein the air-conditioning device (100) in the plenum (101) comprises at least one pressure sensor (200) for measuring an air pressure in the plenum (101); and wherein, in ventilation operation, the fan (150) is controlled in function of measured values of measurements with the dew sensor located in the plenum. The method of any preceding claim, wherein each air outlet (20a, 120a; 20b, 120b; 20c, 120c) comprises at least one sensor for measuring an air parameter in the exhaust air in the air outlet connection (120a; 120b; 120c) ; and wherein a discharge valve is controlled as a function of measurement values of measurements with the sensor located in the air outlet (20a, 120a; 20b, 120b; 20c, 120c). An air-conditioning system (10) comprising: a plenum (101), an air outlet for discharging indoor air from at least one space of a building (1) to the plenum (101), and an outlet valve for controlling the flow from from the at least one room of the building (1) exhaust air; at least one air supply (130) for supplying outside air to the plenum (101), and a supply valve for controlling the flow of supplied outside air; an air heat pump (110) with an evaporator for exchanging heat between air passed over the evaporator and the evaporator (111); a single fan (150) for sucking through the at least one air outlet (120a; 120b; 120c) and the at least one air supply (130) in the plenum (101), respectively, indoor and outdoor air, and for over the evaporator (111 ) drifting the sucked in indoor and outdoor air; and a control device (200) for controlling the at least one discharge valve, the control device (200) being adapted to adjust the position of the discharge valve with the aid of the control device (200) as a function of a desired discharge rate Qa, Qb, Qc, characterized in that the control device is adapted to control the pressure dP in the plenum 101 as a function of the discharge flow rate Qa, Qb, Qc. The air-conditioning system (10) of claim 11, wherein the control device (200) is adapted to adjust the position of the supply valve as a function of the pressure dP in the plenum (101). The air-conditioning system (10) according to claim 12, wherein the control device (200) is adapted to keep the speed of the fan (150) constant in heat pump operation of the air-conditioning device (100). The air-conditioning system (10) according to claim 12 or claim 13, wherein the control device (200) is adapted to correspond to the flow of air Q driven over the evaporator (14) to a maximum value as a function of the desired discharge flow Qa , Qb, Qc. The air-conditioning system (10) according to any of the preceding claims 11-14, wherein the control device (200) is adapted to adjust the speed of the fan (150) as a function of the dew dP in the plenum (101). The air-conditioning system (10) according to claim 15, wherein the control device (200) is adapted for, in ventilation operation, keeping the position of the at least one supply valve constant. The air-conditioning system (10) according to claim 15 or claim 16, wherein the control device (200) is adapted to match the supply flow rate Qoda with a minimum value. The air-conditioning system (10) according to any of the preceding claims 12-14, wherein the air-conditioning device (100) in the plenum (101) comprises at least one pressure sensor (200) for measuring an air pressure in the plenum (101); and wherein the control device (200) is adapted for controlling, in heat pump operation, each supply valve as a function of measured values of measurements with the pressure sensor located in the plenum. The air-conditioning system (10) according to any of the preceding claims 15-17, wherein the air-conditioning device (100) in the plenum (101) comprises at least one pressure sensor (200) for measuring an air pressure in the plenum (101); and wherein the control device (200) is adapted to control the fan (150) in ventilation mode as a function of measured values of measurements with the pressure sensor located in the plenum. The air-conditioning system (10) according to any of the preceding claims 11-19, wherein each air outlet (20a, 120a; 20b, 120b; 20c, 120c) comprises at least one sensor for measuring an air parameter in the discharged air in the air outlet connection ( 120a; 120b; 120c); and wherein the control device (200) is adapted to control a discharge valve as a function of measured values of measurements with the sensor located in the air discharge (20a, 120a; 20b, 120b; 20c, 120c).