SE511915C2 - Measuring heat consumption in dwelling forming part of multi occupancy building, by measuring flow of air leaving dwelling and measuring its heat content - Google Patents

Abstract

The flow of air leaving the dwelling and the temperature of this air is measured, and then heat consumption is calculated for each dwelling, based on the flow of air leaving the dwelling and its heat content. The calculated heat consumption is corrected with respect to heat loss from the dwelling due to transmission. An Independent claim is also included for the measuring system used to carry out this method.

Description

10 15 20 25 30 511915 i i 2 Method 2 is easily applicable in existing buildings, but niken requires accessibility in the apartments for reading or if electronically transmitted values are measured, as is the case today with radio transmitters that require battery replacement. Same objections what Injustices can be argued against Method 2.

Method 3 is based on temperature measurement in each room and some form of data collection from these. This does not measure the energy flow nom radiators. Instead, the indoor climate is valued in the form of the indoor temperature obtained regardless of whether the heat comes through radiator system, via interior walls from the neighbors' apartment or household electricity. The disadvantage of method 3 is that it requires cabling between the rooms and the data collection unit, and that this method only measures an energy-related parameter linked to the transmission losses, not the heat losses out through the lation air. The latter is of minor importance if all have the same air exchange per unit area, but this is often not the case the case due to poor adjustments and comes even less become the case if demand-adapted ventilation becomes common this method does not take into account possible manipulations of internal the temperature in the form of, for example, cooling of the temperature sensors.

An object of the invention is therefore to provide a system with which the mentioned inconveniences can be limited in whole or in part. The object is achieved by the method and the device according to the independent claims.

Embodiments of the invention are set forth in the appended dependent the patent claims.

The invention basically involves evaluating the interior of the apartment. climate by measuring the air temperature of the apartment 10 15 20 25 30 511915 with a measurement of the energy flow out via the exhaust air. Energy- the flow in the exhaust air is calculated on the basis of measurements of its temperature. luck and flow. Thus, method 3, which gives a measured energy carried away, developed into a more accurate method and can be used either as a single method, or as a complementary method to methods 1 and 2 which provide only a measure of the unit's supplied energy via the management system and as such is very dependent on neighbors' indoor temperature and the apartment's location in the building.

The system can then be further developed in accordance with the invention. by also measuring directly to the apartment carried heat effect over time. Thus, the debiting of apartments The heat consumption of the unit is based on a combination of these toder to reduce the apartment owner's motivation to through window ventilation ventilate and lower the indoor temperature in order to reduce their heating costs. Further one can measure the apartment's consumption of household electricity, which emits waste heat, eg from refrigerators, freezers, stoves, lighting, etc., whereby you can correct the apartment's estimated heating energy consumption with the result of this.

In that an important feature of the invention is that one should sense the flow of exhaust air from the respective apartments in the house, is it is of great importance to be able to monitor ventilation the function of the installation by means of systems that can rationally control changes in a system with varying air flows and pressure drop. In doing so, it is important that the monitoring system should be able to distinguish which changes are solely due to it chosen regulatory strategy and changes due to errors in temet. 10 15 20 25 30 511 915 These changes must be measurable as differences in pressure cases in relation to flow and of course also be bust. According to a special feature of the invention, one can therefore read static pressure drop (Apant) in a ventilation duct in direct connection to the suction side of an air flow fan. Where the dynamic pressure of the air flow is also measured at some point in the duct the system where the total air flow passes, for example before ten. You can then form a ratio between static pressure drop and dynamic pressure drop. This ratio can be considered as a system factor. The system factor constitutes a constant absolute value in a plant without changes in the duct system despite variations in flow. If the system factor assumes a value that is too high, one is triggered alarms that are considered to be an indication of a malfunction.

The technique of monitoring a valve with such a system factor can also be used at a single room or a individual space for monitoring its ventilation system.

The invention will be described in the following in exemplary form with reference to the accompanying drawing.

Fig. 1 schematically illustrates a horizontal section through a two-room apartment in an apartment building.

Fig. 2 shows a monitoring unit indicated in Fig. 2.

In Fig. 1 it can be seen that each room of the apartment has a heat source. 1a 3, for example in the form of a radiator 3 belonging to a meandering with waterborne heat. When all the apartments diators 3 belong to a single heating circuit 4 you can easily with one conventional heat meter 40 measures the heat flux emanating from the circuit then 4 ie departs from the radiators. If the radiators 3 heat is provided in other ways, for example via different heating circuits (several 10 15 20 25 30 511 915 trunk lines), one can in a conventional way by means of sensors 41 measure the heat dissipation from the respective radiator 3.

Furthermore, it is shown that the apartment has a single exhaust duct 2 which contains a measuring sensor 7 which senses the temperature of the exhaust air.

In addition, there is a measuring sensor 8 which senses the exhaust air flow through exhaust air duct 2. Sensors 7 and 8 provide information as in a calculation device 9 can be evaluated as the amount of heat from the apartment (excluding transmission losses and ventilation losses) after correction for the waste heat generated by the household devices emit, which is done with information from unit 50 (housing of the electricity meter) or from the electricity supplier's meter data.

Information from the unit 40 (or the units 41) can thus be used to together with the information from the device 9 calculate a weighted measure that, in a more equitable way, presents the apartment's heat consumption and can be used as billing documents.

Measurement sensor 8 can be a sensor that measures the air flow via measurement of the air speed or a sensor that measures the speed of the fan as a measure of the fan's air flow in case where each apartment has a fan of its own.

On the basis of temperature and flow of exhaust air from the apartment one can thus calculate an amount of heat that can be used as a basis for the landlord's debiting of the heating cost for the apartment.

Furthermore, the temperature in the apartment's exhaust air can be used as an indicator of the apartment's indoor temperature, at least as one reference value in relation to the correspondingly produced internal temperature values for the second apartment in the house. 10 15 20 25 30 35 511 915 In Fig. 1 it can further be seen that the exhaust air ducts 2, 2 ', 2 "from the other apartments in the house merge into a common channel 21 which receives the total air flow of the house.

To register if the static pressure drop is too high smiles too low in a system with varying airflows it must static pressure drop is related to a specific flow. If an- the system cure of the installation does not change due to, for example contamination or clogged ventilation devices, the pressure drop always to vary proportionally to the flow, provided that the air flow is turbulent.

The relationship between air flow and static pressure drop can then be is printed as a system factor SF and is calculated according to: SF = Calculate equation 1 2 q where p is pressure drop in pasqal and qz flow in m3 / s.

Since the air flow is a function of the dynamic pressure in the duct system, the relationship between static pressure drop and air flow, system factor, also described according to: SF = Apüat equation 2 Apdyn where Apüm is the dynamic pressure in the system.

The dynamic pressure is measured at some point in the duct system there the total air flow passes, for example before the fan. Dä SF consists of a relationship between static and dynamic pressure the pressures do not have to correspond to measured absolute values at technical and dynamic pressure. 10 15 20 25 30 7 511915 The system factor shall normally be a constant absolute value in the plant without changes in the duct system. If it exists forcing functions, for example in a VAV system or a cation of the air flow at the kitchen cabinet, the system factor comes to forcing operation to be lower than during normal operation. In this case the system factor will never exceed a certain value the plant is operating normally. Too high a value is registered as an alarm.

As shown in Fig. 2, in the duct 21 there is a fan device 22. On the low pressure side of the fan there is a probe 27 which is connected to one sensor 28 which detects static pressure difference, and to another sensor 29 which detects dynamic pressure difference. These sensors are connected to an evaluation unit 30 which forms the ratio between lan the signals of the sensors 28, 29, whereby this ratio can be considered constitute a system factor SF can as defined as Apmßt / Apmm.

The evaluation unit 30 can then be assigned an upper limit value for SF to trigger an alarm from a connected alarm unit 31 when SF exceeds this limit value.

The system factor shall normally be a constant absolute value in the facility, so you can easily monitor the system factor with a constant set limit value.

Static pressure drop in duct, Apmmt, is measured in direct connection to the suction side of the fan. Dynamic pressure, Apqm, is measured with on 29. A tube from the probe 28 for measuring static sub- duct pressure is connected to a low pressure port on the sensor 28 and sensor 29. A port for high pressure on sensor 28 is connected to probe 29 with openings directed towards the air flow. A gate for high pressure on sensor 29 is open to atmosphere.

In a microprocessor, system factor calculation is performed according to (SF = Apaßt / Apqm) and sent as a measurement variable in one bus system or as an analog signal. By integrating measurement 10 15 20 25 30 511915 i i “ static and dynamic pressure drop in ducts and temperature indoor and outdoor temperatures, information on air flow, pressure drop, thermal indoor climate and technical performance for heating and ventilation is obtained continuously. Calculation of system factor can take place for an entire ventilation system in apartment buildings or in one local, but can also be calculated for a ventilation system separately rate for each apartment in the cases separate fan systems for each apartment is the case.

The energy content of the exhaust air flow is calculated and complements it calculated energy consumption for heating. The simplified measurement the method of measuring the temperature of the exhaust air provides a lunda representative value of the apartment's temperature level, but slightly increases the uncertainty regarding the losses through the walls compared to measuring in each room. However, this is compensated more than well of the increased accuracy with which the measurement of energy flow the exhaust air represents. Furthermore, the read indoor temperature is calibrated. lucky with the apartment's consumption of household electricity. Household appliances emits heat. This heat also causes temperature rises. One apartment that uses a lot of household electricity can have higher indoor temperatures without the need to supply the same amount of heat via the ator system. To avoid this apartment being charged for heat supplied via household electricity is recorded as household consumption with, for example, a recording device and an internal cargo is calculated individually for each apartment as a basis for heat charge correction. A signal from the device 50 can thus be used to correct the calculation. Alternatively, reverses historical consumption data.

Measurement data from temperature sensors on the apartment's radiators (method 2), alternatively pulse values from the heat flow meter (method 1) collected together with temperature sensors in the exhaust air duct, air flow meters and any pulse values from hot water meters 10 15 20 25 30 511915 re in a common IT-based climate box (electronics unit). Via the climate box, alarm devices can also be connected such as fire alarms or moisture damage alarm because the communication with the climate box is event-driven.

The measurement collection box stores hourly average values and sends these to a central computer unit via a bus system and possibly or a modem for each building within an area. And dis- play shows current airflow.

If the property manager considers a simplified measure only measurement of the temperature in the exhaust air is used which measured the indoor temperature of the apartment and this together with exhaust air flow as the basis for the heat billing.

All data is sent and collected centrally for calculation with one program. This program performs the following: Energy consumption for hot water and from any heating quantity meters are registered hour by hour as well as to the entire added total amount of energy. Based on the building's added amount of energy (eg the total value of the district heating meter) is tad or measured amount of energy for hot water of. It remains energy needed to heat the building. From this calculation the energy part that applies to the heating of the apartments after the heat to common areas is drawn off and called for "total apartment heat". Each apartment "total apartment heat" calculated and the apartment's energy use (LA-1) for current hours are saved.

If measurement via surface temperature of the radiator takes place instead of with heat meter, the surface temperature is recorded every hour for each radiator. The energy output is calculated as the temperature difference. 10 15 20 25 30 511915 10 between the surface temperature of the radiator and the room temperature times the radiator surface. The room temperature is calculated based on the exhaust air measured temperature minus a correction temperature TNK, which represents the difference between room temperature and air temperature. This correction temperature is set equal to all apartments and can be based on experience values or measured value for the current building.

Thus a product is obtained: degree hourly surface which is summed for each apartment and saved as hourly value. The apartment's heating use is calculated as its share of the degree hour area of all apartments times the building's flat rate. "Total apartment heating" is based of the total value of the district heating meter minus the sum of hot water use in cases where hot water is measured in the apartments. Otherwise it is recommended that a central heat meter be installed. Where- with the apartment's share (LA-2) of this apartment quota and the apartment's energy use for the current hour is saved.

LA-1 or LA-2 is a calculation measure of the the heating energy supplied to the unit from the heating system diators.

The measurement values from any of these calculation methods are supplemented day with the apartment's energy use (LA-3) calculated from the outside the apartment's energy losses, Wlgh via transmission and ventilation tion as a measure of the apartment's energy use. This is done through measurement of the exhaust air temperature and air flow according to the the: - exhaust air temperature, Tel - exhaust air flow, Qf - heated apartment area, Algh household electricity from the previous reading and a genome average waste heat output, P spill (kWh / h) for heating the period is calculated with a standard number. 10 15 20 25 30 35 ll 511 915 The apartment's energy losses Wlgh = Qf x (Tf-Tute) x K + Ua x Algh / Boa x (Tf-Tute - Tmmr) -Pspill, there Ua = building heat transfer number x enclosing area and K = constant I Boa = heated area of all apartments Thu, = correction temperature to obtain the breaking point at which heating from the heating system is required.

The apartment's energy losses give in relation to the sum of the energy losses of all apartments a distribution basis of it above calculated "total apartment heat" as a measure of the apartment energy use LA-3 for every hour. This hourly value is saved.

Through this calculation procedure, it is less important if eg selected value for Thu, there is something wrong, because the heat output tering only takes place for the hours of heat delivered to the building in the heating circuit.

Finally, the calculated heating energy is weighted based on them three methods to each other so that with due regard to the conditions of the building in other respects a weighted measure of unit heat consumption LA is obtained. This means that construction with large heat flows between the interior walls attaches greater importance in sub-method 3 (LA-3) than methods 1 and 2. Normally only method 1 or 2 to be used in combination with method 3, but In general, the weighting is done with the following equation: LA = X x LA-1 + Y x LA-2 + X x LA-3, where X. Y and Z are set as that the sum will be 100%.

In the case of heat billing, the apartment's share of the heating for common building parts, which takes place in the usual way as well as charging for hot water, which can also be race on individual apartment measurement.

This procedure means that there will be no charge for heat to take place during the hours of the day when no heat is supplied to the in the heating circuit.

Claims (10)

10 15 20 25 30 12 511915 P a t e n t k r a v A method of evaluating the heat consumption of an apartment in a house comprising several apartments, sensing the temperature of the apartment's air, characterized by sensing the magnitude of the apartment's exhaust air flow, sensing the air temperature in the exhaust air flow from the apartment and each apartment estimates its heat consumption on the basis of the exhaust air flow and the heat content of the exhaust air, and that the estimated heat consumption is corrected with regard to the apartment's heat transfer loss. Method according to Claim 1, characterized in that the heat input directly supplied to the apartment is also measured over time and that the estimated heat consumption of the apartment is corrected with this in mind. Method according to claim 1 or 2, characterized in that the apartment's consumption of external energy such as electrical energy for the fridge, freezer, stove, lighting, etc. is measured and that the apartment's estimated heat consumption is corrected based on this. Method according to one of Claims 1 to 3, characterized in that the heat content of the exhaust air is evaluated relative to the heat content of the outdoor air. Method according to one of Claims 1 to 4, characterized in that the ventilation system of the house and / or the apartment is monitored for malfunction by comparing a system factor (SF) with a constant limit value, an alarm being triggered if the system factor exceeds the limit factor and that the system factor (SF) is calculated as the ratio between static pressure difference and dynamic pressure difference for the total ventilation air flow, whereby sensors are provided to detect static pressure difference and dynamic pressure difference, respectively. Device for evaluating the heat consumption of an apartment in an apartment building, comprising a sensor for sensing the temperature of the apartment's air, characterized in that the air temperature sensor is located in an exhaust air duct from the apartment for sensing the temperature of the apartment's exhaust air flow. is provided to measure the apartment's exhaust air flow and that calculation means are arranged to calculate a value of the apartment's heat consumption on the basis of the apartment's exhaust air flow and its heat content and that the calculated value is corrected with regard to the apartment's transmission losses. Device according to Claim 6, characterized by means for measuring heat energy supplied directly to the apartment, and calculation means for correcting the estimate of the heat consumption of the apartment on the basis of the measured value of directly supplied heat energy. Device according to claim 6 or 7, characterized by means for measuring supplied external energy from household electricity use to the apartment and means for correcting the apartment's estimated heat consumption based on household electricity use. Device according to one of Claims 6 to 8, characterized in that a temperature sensor is arranged to sense the temperature of the outdoor air and that the heat content of the exhaust air is evaluated relative to the outdoor air. 10 14 511 915 Device according to any one of claims 6-9, characterized by a monitoring device for the ventilation system of the house or an individual apartment, comprising a ventilation air duct which receives the total exhaust air flow from the house apartments or alternatively the air flow from a single pressure unit, a static sensor. in the exhaust air duct, a sensor for sensing dynamic pressure difference in the duct, means for calculating a system factor ratio on the basis of the values sensed by the sensors, an alarm trigger device which receives the system factor value and compares it with a constant limit value, and triggers an alarm signal, the system factor exceeds the limit value, for triggering the alarm device.