NO318418B1 - Ventilation control method, as well as ventilation controls and computer program for carrying out the method. - Google Patents

Description

Technical area

The invention generally relates to ventilation technology, and more specifically regulation of air volume to or from a number of zones in a building.

In particular, the invention relates to a method for ventilation control in a building which comprises a number of ventilation zones, where air is led to at least one common branch and from there is distributed to a number of zone branches leading to the individual zones. The invention also relates to a ventilation controller and a computer program for executing a ventilation controller.

Background for the invention

Mechanical ventilation of buildings is traditionally based on the supply and/or extraction of a constant amount of air to rooms or zones in a building. The desired air volume is calculated from a maximum load in the various rooms. Since the real load is often not maximum, such systems involve unnecessarily high energy consumption.

In order to reduce energy consumption, so-called VAV systems (Variable Air Volume) have previously been developed, where the ventilation is demand-driven, as the amount of air to/from the individual rooms can be varied.

In this description, the expression air volume is to be understood as air flow, i.e. air volume.per unit of time (eng.: "air flow").

The position of the technique

Figure 1 shows a previously known, analogue VAV supply air ventilation system where variable amounts of air are supplied via outlets 110, 120, 130, 140, 150 to five zones or rooms in a building. The amount of air supplied to each zone can be set locally in the zone, so that it can be adapted to the current ventilation needs in the zone.

A branch 101 supplies a common branch 105 with air from a fan 108 via a main duct network 109. Downstream of the branch 101, a motorized damper 102 is arranged which is connected to the output of a pressure regulator 104. The pressure regulator 104 has as input a signal from a pressure transmitter 103, arranged to measure the pressure in the common branch 105, e.g. at the beginning of the common branch on the downstream side of the damper 102. The pressure regulator 104 is arranged to set the damper so that an approximately constant pressure is maintained in the common branch 105, regardless of the amount of air supplied to the zones. Constant pressure is necessary to prevent too high a pressure building up in the common branch 105, with associated strong, energy-wasting throttling of the zone dampers when there is little air demand in the associated zones.

The desired amount of air that is supplied from the common branch 105 to the outlet 110 in the first zone is regulated by means of a local, analogue air quantity regulator 113. The air quantity regulator 113 controls a motorized zone damper 112. The regulator has as input the signal from an air quantity meter 111 for measuring the real quantity of air which supplied to the zone. The regulator also has a set point for the desired amount of air for the zone in question. The value for the set point can either be manually set or automatically influenced by a signal from a presence detector, a thermostat, a CCV meter or similar (not shown) device in the respective zone.

Air supplied to the common branch 105 is similarly distributed to the four other zone outlets 120, 130, 140, 150. The branches leading to these outlets are equipped with dampers in the same way as described above (respectively 122, 132, 142, 152) air flow regulator (respectively 123, 133, 143, 153) and air flow meter (respectively 121, 131, 141, 151).

This previously known solution enables variable, locally needs-adapted air supply to each zone. However, the solution is associated with certain disadvantages.

In each zone, there is a need for a separate air volume regulator with an associated air volume meter, for regulation of the local zone damper. This leads to relatively high equipment, installation and maintenance costs.

Furthermore, it is a problem to determine the correct set point for the constant pressure provided by the pressure regulator 104. Too high a pressure leads to high energy consumption and a high noise level. On the other hand, a pressure that is too low means that the system cannot deliver sufficient amounts of air under heavy load, for example in the case that a maximum amount of air is to be supplied to all zones.

Summary of the Invention

It is a general purpose of the present invention to provide an improved method of the kind mentioned in the introduction.

A particular purpose of the invention is to provide such a method which overcomes the above-mentioned disadvantages of traditional VAV systems.

In accordance with the invention, there is provided a method for ventilation control as stated in independent patent claim 1 below, a ventilation controller as stated in independent patent claim 6 below and a computer program as stated in independent patent claim 7 below.

Further advantageous features appear from the non-independent claims.

Brief description of the drawings

In the following, the invention will be described in more detail in the form of preferred embodiments with reference to the drawings. Here: Fig. 1 shows a schematic block diagram for a VAV system in accordance with the prior art, and which has already been described in the above,

fig. 2 is a schematic block diagram of an improved VAV system in accordance with the invention;

fig. 3 is a schematic block diagram of a ventilation controller in accordance with the invention,

fig. 4 is a schematic block diagram of an improved VAV system in accordance with the invention, which includes a common exhaust branch, and

fig. 5 is a schematic block diagram of an improved VAV system in accordance with the invention, which includes separate exhaust branches.

Detailed description of the invention

Fig. 2 is a schematic block diagram illustrating an improved VAV supply air system 200 in accordance with the invention.

A branch 201 supplies the system with air from an air supply, typically a fan

208 via a main duct network 209. It should be understood that further branches can be supplied by the same fan 208 via the same main duct network 209. Downstream of the branch 201, a damper 202 is arranged followed by an air flow meter 203. Alternatively, the air flow meter 203 can be arranged upstream of the damper 202 The airflow meter provides an airflow signal to a ventilation controller 204.

The ventilation controller 204 is arranged to control the damper 202 based on the air flow signal and data obtained from a local communication link such as a local digital bus 206. The ventilation controller is also arranged to communicate with a central control system via a central communication link, such as a central, digital bus 207. The ventilation controller is further described below with reference to Figure 3.

Downstream of the air flow meter, the air from the common branch 205 is distributed to 5 zone branches 211, 221, 231, 241, 251. The following describes the first zone branch 211 in detail. The other zone branches 221, 231, 241, 251 are identical to the first zone branch 211.

The first zone branch 211 leads to a motorized zone damper 212. The position of the zone damper 212 is set locally, and independently of the system according to the invention, by a local demand management device (not shown) in the zone. In a preferred embodiment, the zone valve 212 has only two predetermined positions; a minimum position and a maximum position.

In the simplest case, the operator control device can be a manual operation for switching between the damper's two positions. More typically includes

the demand management device a local presence detector, for example based on movement, infrared radiation and/or C02 concentration, and/or a device for time management in the relevant zone. Thereby, the damper can be set to the maximum position when a presence is detected in the zone and to the minimum position when no such presence is detected, or the damper can be controlled as a function of time so that it is in the maximum position during the periods when the ventilation need is high, and in the minimum position during the periods when the ventilation need is high is little.

The position of the zone damper 212 is read or detected by a zone damper position detector 213, which is connected to the local bus 206 via a bus connection 214. The zone damper position detector 213 is arranged to report the position of the zone damper 212 to the ventilation controller 204 via the local bus 206. Preferably, the zone damper position detector 213 arranged to be addressed and polled by the ventilation controller, whereupon

the zone damper position detector 213 sends data indicating the position of the zone damper.

Each of the other zone branches 221, 231, 241 and 251 is, in the same way as the first zone branch 211, provided with a zone damper (respectively 222, 232, 242, 252) and a zone damper position detector (respectively 223, 233, 243, 253) which are connected to the local bus 206 via a bus connection (respectively 224, 234, 244, 254).

Fig. 3 is a schematic block diagram of a ventilation controller in accordance with the invention.

The ventilation controller 204 is designed to obtain status information from the zone dampers 212, 222, 232, 242, 252. This acquisition preferably takes place by the ventilation controller 204 addressing and interrogating the zone damper position detectors 213, 223, 233, 243; 253 via the local bus 206, then via the local bus 206 to receive data indicating the position of the zone dampers. This acquisition preferably takes place cyclically at fixed intervals, for example every tenth of a second, every second, or a few times every minute.

Next, the ventilation controller 204 is arranged to calculate, on the basis of the obtained status information, a set point for a desired amount of air to be distributed from the common branch 205 to the zone branches. Furthermore, the ventilation controller is arranged to regulate the amount of air in the common branch 205 to this set point.

As can be seen from fig. 3, the ventilation controller 204 can functionally be seen to comprise an air volume regulator module 301 and a set point calculation module 31 \.

The air volume regulator module 301 comprises a deviation module 302 designed to calculate the regulation deviation between a set point, received from

the set point calculation module, and a measured air quantity received from the air quantity meter 203. The air quantity regulator module 301 further comprises a

regulation function module 303, which is arranged to generate a control signal which is supplied to the damper 202, on the basis of the regulation deviation.

The control function module 303 is based on a control algorithm that can be freely selected by professionals, such as PID control. With the help of the air quantity regulator module, it is achieved that the quantity of air which is fed to the common branch 205 at any time is approximately equal to the set point.

The set point calculation module 31 is designed to calculate the air volume set point which is supplied to the air volume regulator module 310. For this, status information read from the zone dampers via the local bus 206 is used.

On the basis of the status information from each zone damper, the set point calculation module 311 selects an air volume value from pre-stored data in a table. These air volume values are then summed, and the set point is set equal to the sum.

In a preferred embodiment, each zone damper has two positions - a minimum position and a maximum position. In a table stored in a memory in the ventilation controller 204 there is pre-stored data which for each zone indicates the amount of air which corresponds to the minimum and maximum position of the zone damper in question.

To understand this, refer to an example: Suppose now

Qsetpoint = setpoint to be calculated

Q2i2= projected air volume for damper 212 in max. position,

<l2i2 = projected air volume for damper 212 in min. position 0.222= projected air volume for damper 222 in max. position,

q222 = projected air volume for damper 222 in min. position,

Q232 = projected air volume for damper 232 in max. position,

q232 = projected air volume for damper 232 in min. position,

Qi42 = projected air volume for damper 242 in max. position,

q242 = projected air volume for damper 242 in min. position, and

Q252 = projected air volume for damper 252 in max. position,

q252 = projected air volume for damper 252 in min. position.

Assume further as an example that the status information for the zone dampers indicates that the dampers 212 and 232 are in the maximum position, while the dampers 222, 242 and 252 are in the minimum position.

The ventilation controller will, after obtaining this status information, calculate the desired set point which

where k is a correction factor which means that leaks etc. are taken into account. The correction factor k will normally be close to 1.0.

In practice, the ventilation controller 204 is realized as a digital controller, comprising a microprocessor and a control program stored in a memory for operation of the microprocessor. The air volume regulator module and the set point calculation module are in practice implemented as computer program modules that are included in the control program. The controller 204 further comprises input circuits for reading the air quantity signal from the air quantity meter 203, and output circuits for controlling the position of the damper 202. The controller further comprises a first bus interface module to provide two-way communication with the central, external bus 207, and a second bus interface module to provide two-way communication with the local bus 206.

In order to have control over the air distribution between the zone dampers 212, 222, 232, 242 and 252, these must be regulated. That is you must set the correct max. and min. position

for each of the zone dampers. This is done by first setting the air volume for the maximum position for all the zone dampers according to the normal adjustment procedure known to professionals, e.g. the proportional method. Then, for one zone damper at a time and with all other zone dampers in the max. position*, the min. position is set to the desired minimum air volume, which should be approx. 1/3 of the maximum air volume.

With this regulation methodology, and in that the common branch is constantly supplied with the correct amount of air using damper 202, the amount of air in the zone dampers 212, 222, 232, 242 and 252 will lie within acceptable tolerance limits (+/- 15%) with random combinations of the zone dampers in max. and my position.

Fig. 4 is a schematic block diagram of an improved VAV system in accordance with the invention, which includes a common exhaust branch.

The supply system that appears in the upper part of fig. 4 is identical to the system described with reference to fig. 2. The outlet 210 is illustrated to open into a ventilation zone 410, and similarly the outlets 220, 230, 240, 250 are illustrated to open into respective ventilation zones 420, 430, 440, 450. All five zones are ventilation-wise in connection with an area where an air exhaust 460 is arranged. From here, an exhaust duct 405 leads to an exhaust damper 402 which is controlled by an exhaust air quantity regulator 404. The regulator 404 is supplied with a measurement signal for actual air quantity from an exhaust air quantity meter 403, and a set point for the desired exhaust air quantity is supplied via a communication connection 408 from the ventilation controller 204 Thereby, the set point calculated in the ventilation controller 204 will also be used as the set point for the exhaust air quantity regulator 404. The air quantity meter 403 can be arranged upstream or downstream of the exhaust damper 402.

Fig. 5 is a schematic block diagram of an improved VAV system in accordance with the invention, which includes separate exhaust branches.

The supply system that appears in the upper part of fig. 5 is identical to the system described with reference to fig. 2. Outlets 210, 220, 230, 240 and 250 are illustrated opening into separate ventilation zones each provided with zone exhaust with a zone exhaust damper, 512, 522, 532, 542 and 552 respectively.

Each zone exhaust damper 512, 522, 532, 542 and 552 is controlled as a slave by the respective zone damper 212, 222, 232, 242 and 252. This is illustrated by communication connections 513, 523, 533, 543 and 553, which in practice can be designed as electrical connections that duplicate the individual signal for controlling the motorized dampers 212, 222, 232, 242 and 252.

Furthermore, the five zone exhausts are connected together in an exhaust duct 505.1 similar to what is explained with reference to Figure 4, the exhaust duct 505 leads to an exhaust damper 402 which is controlled by an exhaust air quantity regulator 404. The regulator 404 is supplied with a measuring signal for actual air quantity from an exhaust air quantity meter 403, and a set point for the desired exhaust air quantity is supplied via a communication connection 408 from the ventilation controller 204. Thereby, the set point calculated in the ventilation controller 204 will also be used as a set point for the exhaust air quantity regulator 404. Here, too, the air quantity meter 403 can be arranged upstream or downstream of the exhaust damper 402.

In the above, detailed implementation examples are described. However, it should be pointed out that many variations are possible within the scope of the invention.

For example, it will be understood that the zone damper detectors themselves can take the initiative to report their respective data indicating the position of the zone damper, without being queried by the ventilation controller via the bus. Furthermore, it will be understood that the transmission of data indicating the position of the zone valves does not necessarily have to take place periodically, as indicated in the above. Especially in the event that the zone damper position detectors themselves report this data to the ventilation controller via the bus, this can happen in response to an actual change in the position of the individual zone damper.

It is further stated as an example that the zone dampers can only occupy two defined positions; a minimum and a maximum position. Those skilled in the art will realize that there is nothing in the way of operating with three or more positions, and the invention will also be able to operate with continuously variable (and by the zone damper detector detectable) zone damper positions.

Although the example mentions five zone branches linked to each common branch, it will be obvious to those skilled in the art that the invention can be used with any number of zone branches per joint branch, including only one or two zone branches.

With reference to fig. 2, a further possibility of variation shall be described in the following. In the event that several common branches are connected to the main duct network 209 in addition to the illustrated common branch 201, it would be advantageous to let the fan 208 be included in a further air volume regulation loop, where a ventilation controller (not shown) is arranged for controlling the fan, which gets its measuring input from a quantity meter arranged in the main duct network 209 and its setpoint generated by a setpoint calculation module which adds the setpoints from the ventilation controllers arranged in the common branches (transmitted via a data bus such as the central bus 207), multiplied by a correction factor close to 1.0, and which uses this result as the set point for air volume in the main duct network 209. This involves a solution that is analogous to that used in the common branches.

In the detailed description, the use of a central, digital bus 206 and a local, digital bus 207 is mentioned. Alternatively, the communication can take place over just one bus.

Those skilled in the art will realize that many other modifications and variations are conceivable within the scope of the invention. The invention should therefore not be considered limited to those

described examples, but includes all embodiments that fall within the definition given by the subsequent patent claims.

Claims (7)

1. Procedure for ventilation control in a building that includes a number of ventilation zones, where air is led to at least one common branch (205) and from there is distributed to a number of zone branches (211, 221, 231, 241, 251) which lead to the individual zones, where the method comprises the following steps: (a) obtaining status information from a zone damper (212, 222, 232, 242, 252) located in each zone branch, and (b, c) controlling the air flow rate supplied to the common branch (205) based on the obtained status information, characterized by that the control step (b, c) comprises the steps (b) of calculating, on the basis of said acquired status information, a set point for a desired air flow rate to be distributed from the common branch (205) to the zone branches, including (bl) on the basis of the status information from each zone damper, to select an air flow rate value from pre-stored data in a table, and (b2) setting said set point proportionally to the sum of said air flow rate values, and (c) regulating the air flow rate in the common branch (205) of said set point. 2. Procedure for ventilation control in accordance with requirement 1, where the acquisition step (a) comprises (al) addressing and interrogating a zone damper position detector (213, 223, 233, 243, 253) via an electronic communication link (206, 214, 224, 234, 244, 254), and (a2) receiving data representing the position of the zone damper (212, 222, 232, 242, 252) via the electronic communication link. 3. Procedure in accordance with claim 1 or 2, where step (b2) includes setting said set point equal to the sum of said air flow rate values, multiplied by a predetermined factor to compensate for leaks or other conditions. 4. Method for ventilation control in accordance with one of the claims 1-3, where an air exhaust (460) is arranged from an exhaust point that is in ventilation connection with the zones, via an exhaust duct (405), where the air flow rate through the exhaust duct (405) is regulated to a desired exhaust air flow rate, the method further comprising the step (d) of setting the desired exhaust air flow rate to said set point. 5. Method in accordance with claim 4, where the setting step (d) comprises transferring said set point to an air flow rate regulator (404) for the exhaust duct (405) via an electronic communication connection. 6. Ventilation controller (204), comprising input circuits, output circuits, a microprocessor and a control program contained in a memory, characterized in that the controller, when executing the control program, is arranged to carry out a method in accordance with one of claims 1-5. 7. Computer program contained in a memory or on a storage medium, arranged for the execution of a microprocessor in a ventilation controller, characterized in that the computer program contains instructions which, when executed by the microprocessor, carry out a method in accordance with one of claims 1-5.