FR2506937A1 - METHOD AND APPARATUS FOR ANALYZING THE ENERGY CONSUMPTION OF A BUILDING - Google Patents

Abstract

The method consists in simultaneously measuring the operating duration of a heating apparatus and the external temperature, and in storing these values in memory in an automatic apparatus. This apparatus, of small dimensions, includes a microprocessor, a memory and an electrical battery capable of keeping power applied to the apparatus for seven days. The capacity of the memory allows hourly samples for three weeks. The apparatus can be sent by post, for reading and processing the measurements by a microcomputer.

Description

METHOD AND APPARATUS FOR ANALYZING THE ENERGY CONSUMPTION OF A BUILDING
The present invention relates to a method for analyzing theenergetic consumption of a building, and an apparatus for implementing this prot
Devices are already known for measuring the operating time of a heating system powered by the power grid.

These devices are either roller meters for monthly readings, or meters equipped with an output that can be connected to a tape recorder or a recorder with a paper strip and a stylus pen.

Roller meters must be read monthly, which requires the provision of a large and competent staff. The recorder counters, which eliminate this disadvantage, are on the other hand expensive apparatus.

The present invention proposes to overcome the aforementioned drawbacks by providing a fully automatic method and apparatus, and by providing precise indications which make it possible to establish an energy signature of a building.

For this purpose, the method according to the invention is characterized in that measurements of the temperature outside the building and the operating time of the heating system of this building are carried out regularly for at least a given time interval. , and that the results of these measurements or data extrapolated from these results are recorded in memory.

In order to establish the relationship between the indoor temperature and the outside temperature of the building, at least one interior temperature of the building is also measured.

According to a preferred embodiment, said measurements are carried out at intervals Lt and an averaging of the measurement results is carried out every n tt, where n represents a multiplying factor> 1, and said calculated averages are stored in memory. On this basis, it is possible for example to perform a measurement every minute then calculate and record in memory the hourly averages of these measurements.

The measuring apparatus for the implementation of this method is characterized in that it comprises means for performing regularly and simultaneously for at least a predetermined time interval, measurements of the temperature outside the building and the time of operation of the heating system of this building and storage means for recording in memory either the results of these measurements or extrapolated data from these measurements.

To allow the measurement of at least one temperature inside the building, the apparatus comprises at least one temperature sensor disposed at a predetermined location of the building.

The apparatus includes means for automatically performing said measurements for predetermined time intervals, and means for automatically averaging said measurement results at predetermined time intervals where n is a multiplier factor 1.

This apparatus comprises at least one microprocessor arranged to perform these measurements and calculate these averages during periods fixed in advance.

This device is compactly designed and comprises in the same housing at least one microprocessor, at least one memory, connection means for adapting at least one external temperature sensor, connection means for adapting at least one measuring device operating time of the building heating system, and at least one connecting member for connecting a reading apparatus arranged to read and / or interpret the stored data.

In addition, this device may include one or more connecting members for connecting sensors for measuring the interior temperature of the building.

The present invention will be better understood with reference to the description of an exemplary embodiment and the appended drawing in which:
FIG. 1 represents a block diagram of the apparatus according to the invention,
FIG. 2 represents a graph illustrating the power consumed as a function of the temperature outside the building,
The figure graphically represents the power consumed as a function of the temperature outside the building for a discontinuous operation of the heating system,
FIG. 4 shows graphically the energy signature of the building before and after thermal remediation and,
Figure 5 shows graphically the efficiency of thermal remediation as a function of the temperature outside the building.

With reference to FIG. 1, the apparatus according to the invention comprises an insulating casing 1, for example a synthetic material such as polystyrene, inside which are mounted the main components.

The apparatus is equipped with a power supply unit 2 connected to the network at 3, which notably comprises an accumulator, preferably a nickel cadmium battery, for storing the stored data, in particular in the event of a power grid failure. The block 2 also comprises a device for detecting network power outages, this device being connected to the memory 4 through the microprocessor 5 to record in real time the time and duration of the failure. One or more external temperature probes 6, connected to an analog-to-digital converter 7, provide the microprocessor 5 with the measurement of the outside temperature at one or more points outside the building. It is also possible to equip the apparatus with one or more a plurality of temperature probes 8 connected to an analog-to-digital converter 9, to provide the microprocessor with measurements of the internal temperature at different points of the analyzed building.

An intermediate system 10 may be connected via its output 11 to a reading and / or interpreting device (not shown) for reading and / or analyzing the data stored in memory.

One or more probes 12 are connected through an adapter 13 to the microprocessor 5 to allow the recording of the operating time of the heating system.

The method according to the invention, although reflecting the commonplace "the colder it is outside, the more it is necessary to heat inside to maintain a certain comfort", however goes further by allowing to quantify for a building given the surplus consumption following a lowering of the outside temperature. In more technical terms, the so-called "energy signature" quantity is defined by a substantially linear relationship between the dissipated power and the outside temperature. More precisely, the hour-by-hour knowledge of this dependence between consumption and outside temperature, allows a monitoring of the dynamic life of a building which leads to the evaluation of certain thermal properties of the consumption (overall coefficient of losses, inertia, use of free energy) or the installation of heaters (dimensions, losses keeping temperature, operation of the regulation).

The additional advantages of such a method are on the one hand to be able to isolate certain critical days such as weekends, holidays, and on the other hand to be able to consider any interval of time, since the hour until several days, in order to obtain the most significant average values.

The device described memorizes hour by hour the energy consumption and the average outside temperature, for example for a period of three weeks. This time elapsed, the recorded measurements are read using a microcomputer, in order to be interpreted thanks to a suitable infrastructure to perform the analysis of the measurements.

FIG. 2 graphically represents the curve of the consumption of the heating installation in kW, as a function of the temperature in degrees C.

The equation of the average line is as follows
P = - 3.27 T + 62.0
The interpretation of this graph shows that - the installed capacity of the heating system is such that the building in question can withstand a daily outdoor temperature of -300C without the level of internal comfort being affected.

- the value of the average daily outdoor temperature over which it is no longer necessary to heat this building is 190C.

This temperature is called base temperature and is an indicator of use by this building of free energy, such as solar energy or the use of electrical appliances.

With regard to the construction itself, the low dispersion of the measuring points around the right indicates that we are dealing with a low thermal inertia construction, well sealed against air infiltration (influence negligible wind, corresponding to points A and B), and insensitive to solar gain (influence of non-perceptible sunshine, corresponding to points C and D).

Knowing the average outdoor temperature T over the entire heating season, it is then possible from this graph to determine the average power P dissipated during this same period, which allows to deduce the energy consumption for the period of heating, and therefore the energy index of the building examined.

In the case where the buildings under consideration are subjected to different operating regimes throughout the day, for example following a nocturnal decrease in the temperature in the rooms, it is possible thanks to this method to visualize the operation of the control and to determine its effectiveness.

On the graph of Figure 3, there is shown a building for which - from 23 h to 6 h (night time), the heating is cut, the consumption during this period only for maintaining boiler temperature. (See right N).

- From 6 am to 7 am (stimulus), the heating is relaunched strongly to quickly compensate for falling indoor temperatures of premises due to the night reduction. It can be seen that the boiler has to run at full speed during this period as soon as the outside temperature drops below -4 C (see right R).

- from 7 am to 11 pm (daytime operation), the heating is normally switched on to ensure the required level of comfort in the premises (right J).

On the basis of this information, it is then possible to quantify the saving achieved by this nocturnal lowering of the temperature, or if necessary, to find the optimal regulation that can bring maximum savings. In the example given, the savings made during the period considered can be estimated at 15%.

When the building has undergone a thermal improvement, it is possible by comparnson energy signatures before the improvement and after the improvement to quantify the real effectiveness of the intervention carried out, and if it is not satisfactory to find some remedies.

FIG. 4 represents straight lines Q and S respectively corresponding to the energetic signatures of a building after and before the transformations intended to improve the thermal insulation of this building.

The curve in FIG. 5 illustrates the efficiency of thermal remediation as a function of the outside temperature.

The apparatus described is suitable for all conventional heating systems, including central heating systems supplied with liquid or gaseous fuel, electric heaters or remote heaters.

In practice the apparatus is installed for a given period during which it performs the storage of the date, the storage of the running time of the heating system, for example by performing a detection every five seconds, the storage of the average hourly the temperature measured every minute. After disconnecting the device, it can be connected to the analysis device that allows you to strip the recorded data.

Although the present invention has been described with reference to a particular embodiment of the apparatus and method, these may be modified in a variety of ways and in various ways that are not readily apparent to those skilled in the art. In particular, in some cases, it may be useful to have a more detailed analysis of the building, for example to know the interior temperatures room by room. In this case, it is possible to have in each room or in a predetermined number of rooms of the building, temperature probes taking the internal temperatures. Moreover it would be possible to consider using the device according to the invention directly with the microcomputer for performing the analysis and analysis of the recorded data.

Claims (9)

1. A method of analyzing the energy consumption of a building, characterized in that it is carried out regularly for at least a determined time interval, simultaneous measurements of the temperature outside the building and the operating time of the heating system of this building, and that the results of these measurements or data extrapolated from these results are recorded in memory. 2. Method according to claim 1, characterized in that one also measures at least one temperature inside the building. 3. Method according to any one of claims 1 or 2, characterized in that one carries out said measurements at intervals of time in that one automatically proceeds to calculate an average of the results of measurements every nht, where n represents a multiplying factor 21, and in that said calculated averages are stored in memory. 4. Measuring apparatus for implementing the method according to claim 1, characterized in that it comprises means for performing regularly and simultaneously for at least a predetermined time interval, measurements of the temperature outside the building and the operating time of the heating system of this building and storage means for recording in memory either the results of these measurements, or extrapolated data from these measurements. 5. Apparatus according to claim 4, characterized in that it also comprises means for measuring at least one temperature inside the building. 6. Apparatus according to claim 4, characterized in that it comprises means for automatically performing said measurements at predetermined time intervals t, and means for automatically averaging the results of these measurements at predetermined time intervals. where n is a multiplying factor 2 1. 7. Apparatus according to claim 6. characterized in that it comprises at least one microprocessor. 8. Apparatus according to claim 4, characterized in that it comprises, mounted in the same housing, at least one microprocessor, at least one memory, connecting means for adapting at least one sensor for measuring the outside temperature, connecting means for adapting at least one measuring member of the operating time of the building heating system, and at least one connecting member for connecting a reading apparatus arranged to read and / or interpret the stored data. 9. Apparatus according to claim 8, characterized in that it comprises connecting members for connecting at least one sensor for measuring the interior temperature of the building.