FR2528549A1 - Storage heating controller using logic circuit - uses measures of external weather conditions to calculate amount of energy which must be passed to storage medium - Google Patents

Abstract

The controller calculates the mean external temperature over a predetermined time period before each heat storage time and regulates the energy flow to the storage medium to limit the energy stored as a function of the mean measured temperature. Energy is supplied to the storage medium for a period dependent on the difference between a preset temperature level and the mean external temperature. The start of the storage period can be timed so that the end of the supply period corresponds to a specified time, for example the end of an off-peak tariff period. The accuracy is improved if a measure of the rate of change in temperature is used to vary the rate of supply of energy and wind and sunshine measures are used to adjust the mean temperature calculation.

Description

 "process and device intended for the storage of thermal energy".

 The present invention relates to a control method and device intended for the storage of thermal energy such as heat or cold in deans of accumulation with a view to its recovery, using energy supplying means. thermal to the means of accumulation.

 your heating installations frequently include means of thermal energy accumulation, notably using the network's electricity as an energy source. In general, it is particularly advantageous to operate the means supplying the thermal energy to the accumulation means intermittently or periodically and in particular at night.

 To limit the amount of thermal energy accumulated during each period or operating cycle of the means supplying thermal energy, in order to limit heating costs, current systems take into account the outside temperature at the start of the accumulation period. and vary the operating time of the means supplying thermal energy to the accumulation means as a function of this temperature. However, this measured temperature which is generally a night temperature reflects only very partially, or even not at all, the meteorological events which have occurred previously. as a result, the amount of thermal energy accumulated is poorly suited to the current weather conditions.

 The object of the present invention is to remedy this drawback in particular and first of all proposes a method making it possible to optimize, in a much more precise manner, the thermal energy to be accumulated.

 The method for storing thermal energy in thermal energy storage means such as heat or cold for the purpose of restoring it, in which the means supplying thermal energy to the storage means operate intermittently or periodic, is in fact such that it consists in calculating the average of the outside temperature over a determined period of time preceding each period of accumulation and in operating the means supplying thermal energy to the means of accumulation, during this period of accumulation, until the temperature of the means of accumulation, respectively the quantity of thermal energy which they contain, is brought to a predetermined value depending on the average value of the calculated outside temperature or during a predetermined duration depending on this vredetermined value.

 pe particularly advantageously, the method according to the present invention allows, if for example the average temperature is calculated over a period of time of 24 hours, to take into account in particular the ampiitûde of 'variation of the day and night temperatures which depend meteorological conditions and in particular of the nebulosity and the thermal contributions due to the sunning which are largely -variable, being noted moreover that the average of the outside temperature calculated on two j days days ~ consecutive days vary much only exceptionally and accidentally .

 In a variant, the method according to the present invention may consist in operating the means supplying the thermal energy to the accumulation means for a period depending on the difference between said predetermined value and the temperature of the accumulation means, respectively of the quantity of thermal energy which they contain, before the period of accumulation and of this temperature, respectively of this quantity of thermal energy.

 In another variant, the method according to the present invention may consist in shifting the start of the accumulation period so that the end of said predetermined period of operation of the means supplying thermal energy to the accumulation means takes place at a prefixed time. In this way, for a large number of heating installations operating in accordance with the method according to the present invention, the distribution of the instants of operation of the means supplying thermal energy is spread out over time. This advantage is particularly interesting in particular when the energy source is constituted by the electrical network.

 In particular for the implementation of the above method, the present invention also relates to a control device, for the storage of thermal energy such as heat or cold in means of accumulation of athermal energy, of the means supplying thermal energy to these accumulation means, making it possible to operate the means supplying thermal energy in an intermittent or periodic manner. According to the present invention, this control device comprises means for measuring the outside temperature, means for calculating the average of the outside temperature over a determined period of time, means for determining the temperature of the accumulation means to be reached as a function of the average of the calculated outside temperature, means for measuring the temperature of the means of accumulation, means for calculating the difference between the. temperature axes means of accumulation to be reached and their tewperatuKe measured, means for determining an operating time of the means supplying the thermal energy as a function of this difference in yue of reaching said temperature and means for operating the means supplying the thermal energy during this fixed period.

 The control device according to the present invention may advantageously comprise means for memorizing the heating characteristic of the accumulation silks for the purpose of determining the temperature of the accumulation means to be reached, means which may also be provided for modify this registered heating characteristic.

 The control device according to the present invention may also comprise means for memorizing the rate of variation of the temperature of the accumulation means under the effect of the means supplying thermal energy for the purpose of determining said operating time of the means supplying thermal energy, means which can also be provided for modifying the rate of variation of the temperature of the stored accumulation means.

 The control device according to the present invention may also include means for delaying the start of the operating period of the means supplying thermal energy, means which may be provided for determining the offset as a function of a pre-set stop time of the operation of the means providing thermal energy and said determined duration of operation of these means.

 The control device according to the present invention may also include means for stopping the operation of the means supplying thermal energy as soon as the temperature of the means of accumulation reaches said determined temperature.

The present invention will be better understood from the study of a storage heating installation comprising storage means and control means of the means supplying thermal energy to these storage means described by way of example limiting and illustrated schematically in the drawing on which
- Figure I shows this heating installation;
- Figure 2 shows a curve of outside temperatures recorded over five consecutive days;
- Figure 3 shows, -sr these five days and below. the form of slots the periods of operation of the means providing thermal energy
- And Figure 4 shows the curve of variation of the tempera.ture of the means of accumulation over these five days.

 Referring to FIG. 1, it can be seen that the storage heating installation shown generally indicated by the reference 1 comprises a heat accumulator generally indicated by the reference 2, means for heating capable of supplying heat to the accumulator 2 generally indicated by the reference 3 as well as a device for controlling the means supplying the heat 3 generally indicated by the reference 4.

 In the example shown, the accumulator 2 is formed by a balloon 5 filled with water capable of circulating outside of this balloon, for example in radiators not shown. Any other means of accumulation could have been foreseen.

 The means 3 capable of heating the water contained in the tank 5 are formed, in the example, by a heating resistor 6 immersed in the tank 5, this heating resistor 6 being connected to the electrical network 7 via a power interface 8 comprising for example a relay.

 The control device 4 comprises an outside temperature probe or sensor 9 connected to an averager 10 via an amplifier 11, this averager 10 being capable of calculating the average of the outside temperature over a period of time determined from external temperatures supplied by the probe 9. In addition, this averager 10 is capable of taking into account, by weighting the external temperatures it receives or the average it calculates, other physical parameters supplied to it by for example by one or more auxiliary probes 12, these physical parameters being for example the wind or the sunshine.

 The control device 4 also comprises a computer 13 which receives from the averager 10 information corresponding to the average of the calculated outside temperature and which is capable of supplying at its output information corresponding to a temperature of the accumulator 2 to be reached at the end accumulation period by interrogating a set of memory 14 containing a heating curve depending on the thermal parameters of the room to be heated such as for example its heat loss coefficient and heat capacity and the heating system used and associated with the tank 5 , these parking meters can be wodiXxes thanks to a circuit 15 in order to adapt the recorded heating curve u local considered. This heating curve represents the temperature of the accumulator to be reached as a function of the average outside temperature and is generally a substantially linear and decreasing function.

 The information leaving the computer 13 and corresponding to the temperature of the accumulator 2 to be reached is transmitted to a subtractor 16 which also receives information corresponding to the temperature of the accumulator 2 which is supplied to it by a probe or sensor 17 through an amplifier 18. This subtractor 16 is capable of supplying at its output information corresponding to the difference between the temperature of the accumulator to be reached and the temperature of the latter measured by the probe 17.

 The information leaving the subtractor 16 and the information corresponding to the temperature of the accumulator 2 supplied by the probe 17 are transmitted to a multiplier 19. This multiplier 19 is capable of supplying at its output information corresponding to a duration qu it determines using a curve recorded in the memory assembly 20 and representing the heating speed of the accumulator 2 as a function of its temperature, this heating speed depending on parameters such as the power of heating, the energy speed of the heating means 3 and in particular of the resistor 6 and of the storage capacity of the accumulator 2. These parameters can be modified by means of a circuit 21 in order to adapt the speed curve of heats up with the accumulator and the considered heating means.

The information coming from the multiplier 19 and corresponding to a duration is transmitted to a time subtractor 22. This time subtractor 22 also receives, from a circuit 23, a first piece of information corresponding to the start of each of the time periods at during which it is desired to operate the heating means 3 and a second item of information corresponding to the end of each of these periods. The subtractor 22 is capable of operating the heating means 3, by acting on the power interface 8, by shifting the start-up of these heating means 3 relative to the time when it receives from circuit 23 the first information of a duration corresponding to the difference between the length of the period
of time separating the first-and lss second information and the in
training he receives from the multiplier 19 corresponding to the duration
calculated. The subtractor 22 is also capable of stopping the func
operation of the heating means 3 as soon as it receives from circuit 23 the
second information: Between subtractor 22 and the power interface
this 8, an AND gate 24 has been provided which also receives information
from a comparator 25 in order to stop the heating means
3 as soon as there is a coincidence between the information that this comparator
25 receives from the probe 17 and the computer 13, that is to say as soon as there is a coincidence between the temperature of the accumulator 2 reached and
the temperature to be reached determined by the computer 13.

Referring to Figures 2 to 3, we will now describe
re an example of operation of 11 heating installation 1 represented
felt in Figure 1 to understand its value.

First, we consider that we will calculate the average
24-hour outdoor temperature every day from
from 9 p.m., and we want to operate the heating means
fage within a period of time starting at 9 p.m.
necessarily ending at 7 am, successive time periods
being supplied by circuit 23.

In FIG. 2 is shown a curve of the temperature
external ture measured on 5 consecutive days.

During each 24-hour day, starting at 9 p.m.
hours, the averager records the outside temperature. At 9 pm,
it calculates the average outside temperature to supply it to the
calculator] 3. In the example shown in Figure 2, we see that
successively over the first three days the average temperature
external re decreases slightly and gradually while the qua
third day it is noticeably higher and the fifth day sensi
significantly lower, the averages having been represented, for each
day, in strong solid lines.

Each day at 9 p.m., the computer 13 determines
using the heating curve contained in memory assembly 14
the temperature that the accumulator 2 must reach at 7 am the next day 5, the subtractor 16-measures the temperature of the accumulator 2
using probe 17 and calculates the difference between the temperature at
reach provided by the computer 13 and the temperature of the accumulator
reader, the multiplier calculates the operating time of the means
of heating necessary to heat the accumulator -2 to the temperature which it must reach at 7 hours and the time subtractor 22 calculates the offset with respect to 21 hours so that at 7 hours the operating time of the means of heating is elapsed, this offset corresponding to a start-up time of the heating means 3 more or less 21 hours away. At the end of the determined offset from 21 hours, the multiplier starts the heating means 3 by acting on the power interface 8 through the AND gate 24 which is passable since the temperature of the accumulator 2 is lower at the temperature it should reach.

 - At 7 o'clock, when it receives the second information from circuit 23, the multiplier imperatively stops the heating means 3.

 If the temperature of the accumulator 2 reaches the peratureaqutil time must reach before 7 hours, the comparator 25 blocks the door AND and the heating means 3 are then stopped earlier.

 Referring to FIG. 3, it can be seen that the operating times of the heating means 3 in the three periods ranging from 9 pm to 7 am, consecutive to the first three days ending at 9 pm, are increasing means that the average outside temperature decreases, the shifts going, consequently decreasing.

 On the other hand, as the average outside temperature of the fourth day is appreciably higher, the duration of operation of the heating means 3 in the period from 21 hours to 7 hours following is significantly shorter, the start-up delay heating means compared to the end of this fourth day being consequently significantly more important.

 On the fifth day, the average outside temperature being much lower, the start-up delay of the heating means 3 is much lower and consequently the operating time of these heating means 3 is much longer.

 Referring to FIG. 4, it can be seen that at the end of the periods of operation of the heating means 3, consecutive respectively to the first three days, the temperatures reached by the accumulator 2 increase while at the end of the period of operation of the consecutive heating means 3: on the fourth day, the temperature of the accumulator 2 is significantly lower, the temperature of the accumulator decreasing between all these periods due to the fact that it yields more or less its accumulated heat as a function of the outside temperature.

 The present invention is not limited to the example described above. Many alternative embodiments and uses, in particular in more complex heating installations or in refrigeration or air conditioning installations, are possible without departing from the scope of the present invention.

Claims (11)

REyENDICATIONS  1. A method for storing thermal energy in thermal storage means such as heat or cold as a result of its restitution, in which the means providing thermal energy to the storage means operate from intermittently or periodically, characterized in that it consists in calculating the average of the outside temperature over a determined period of time preceding each accumulation period and in operating the means supplying thermal energy to the accumulation means , during this accumulation period, until the temperature of the accumulation means, respectively the quantity of thermal energy which they contain is brought to a predetermined value depending on the average of the calculated outside temperature or during a predetermined duration depending on this predetermined value.  2. Method according to claim 1, characterized in that it consists in operating the means supplying the thermal energy to the accumulation means for a period depending on the difference between said predetermined value and the temperature of the means d accumulation, respectively the amount of thermal energy that it contains, before the period of accumulation and of this temperature, respectively of this amount of thermal energy.  3. Method according to one of claims 1 and 2, characterized in that it consists in shifting the start of the accumulation period so that the end of said predetermined period of operation of the means providing thermal energy the means of accumulation takes place at a fixed time.  4. Control device, for the storage of thermal energy such as heat or cold in means for accumulating thermal energy, means supplying thermal energy to these means for accumulating intermittently or periodically, characterized by the fact that it comprises means for measuring the outside temperature, means for calculating the average of the outside temperature over a determined period of time, means for determining the temperature of the accumulators to be reached according to the mean of the calculated outside temperature, means for measuring the temperature of the accumulation means, means for calculating the difference between the temperature of the accumulation means to be reached and their measured temperature, means for determining a duration of operation means supplying thermal energy in order to reach said temperature as a function of this difference and means for operating the means providing thermal energy during this determined period.  5. Control device according to claim 4, characterized in that; l comprises means for memorizing the heating characteristic of the accumulation means with a view to determining the; -temperature of the accumulation means to be reached .  6. Control device according to claim 5, characterized in that it comprises means for modifying the heating characteristic of the stored accumulation means.  7. Control device according to any one of claims 4 to 6, characterized in that it comprises means for memorizing the speed of variation of the temperature of the accumulation means under the effect of the means supplying ther energy. mi only for the purpose of determining said duration of operation of the means supplying thermal energy.  8. Control device according to claim 7, characterized in that it comprises means for modifying the speed of variation of the temperature of the means of storage recorded.  9. Control device according to claim 4, characterized in that it comprises means for delaying the start of the operating period of the means supplying thermal energy.  10. Method according to claim 9, characterized in that it comprises means for determining the offset as a function of a fixed moment of stopping the operation of the means supplying thermal energy and of said predetermined duration.  11. Control device according to any one of claims 4 to 6, characterized in that it comprises means for stopping the operation of the means supplying thermal energy as soon as the temperature of the accumulation means reaches said determined temperature.