CA1190973A - Accumulating electric radiator - Google Patents

Abstract

The invention relates to improvements in storage radiators. It relates to an electric storage heater which includes a device for limiting the useful accumulative power according to the losses of the room where the device is installed, a device for storing, during a determined period of the day, a quantity of energy. variable depending on the difference between the temperature of the core of the device and a first reference temperature and a device for possibly reviving all or part of the accumulated power, during a restitution period extending over the rest of the day, depending on the difference between the core temperature and a second reference temperature. The invention applies to heating in particular domestic.

Description

~ 9 ~ 9 ~ 3 The present invention relates to radiators electric storage and more particularly identifies devices of this type equipped with specific means regulate both the charge of the accumulation nucleus and its discharge, day and night.
The object of the invention is to propose an apparatus reil capable, as regards the load, of choosing the amount of energy to be stored according to para ~
- predetermined meters and, with regard to discharge, restore stored energy by possibly relaunching the accumulator core.
The intention is also to achieve a device allowing charging for a determined period, preferably during so-called off-peak hours, and a restitution during the rest of the day with a possible revival of the nucleus, or, as desired, of the whole installed power (so-called 24-hour version), i.e.
of a fraction of said power (so-called 8-hour version) this fraction being advantageously 1/3 that is to say, corresponding to the commissioning of a single resistancechauf ~ ante in the case of devices operating in three-phase ~ e with three resistors each connected to one of the three phases.
this ef: ~ and, the invention more specifically for o} Jjet an electric radiator with charac terized accumulation in that it includes means for limiting the power accumulative useful according to the losses of a room 01 ~ is installed the radiator, constituted by a potentiometer load reylage, means for storing during a specific period of the day an amount of energy variable depending on the difference between the temperature of a no ~ at the radiator and a first reference temperature and mo ~ ens to possibly revive all or part of the installed power, during a restitution period 3S extending over the rest of the said day, depending on the ~ 7, ~ (39'7 ~

difference between core temperature and a second reference temperature.
Preferably, the charging period corresponds during off-peak hours, the start and end of this period being controlled by clock signals of a electrical distribution network.
During charging, said first temperature reference may be a first maximum temperature threshold delete one of the following three ways:
a) by the user through the poten-charge tiometer.
~,) from an external regulation circuit local.
c) ~ from an outdoor temperature sensor local.
Similarly, during the eventual relaunches said second reference temperature can be a second maximum temperature threshold displays from one in the following three ways ^
a) by the user through a boost di-t potentiometer, temperature maximum of no ~ al1 then being ~: ixed by con position, with potentiometers charye and stimulus.
b) from an external reyulation circuit in the room, the maximum core temperature being fixed by this circuit and modulated by the stimulus potentiometer.
c) from an external temperature sensor in the room, the maximum core temperature being fixed by this probe and modulated by the poten-relaunch tiometer.
Preferably, a multi-position switch tions is provided to allow the user to select 3 ~ one ~ of the three maximum reference temperatures for a ch, lr ~ e at night a ~ ec for each possibility of recovery ~: ~, 7 . ~ 9 ~) 973 day, or all, ~ a fraction of the load and according to another maximum temperature threshold cross out of three possibilities corresponding to those offered for the night charge.
Such a device is capable of ensuring itself its charge level according to thermal needs the room and the chosen reference temperature and ensure the level of restitution according to needs by adjusting the levels of restitution of the energy emma-gasinee, or any reminders in full hours, at strict necessary and at the level chosen by the user.
The invention therefore makes it possible to reduce the installed sessions, practically eliminating excess sances e ~ therefore the waste.
Other characteristics and advantages stand out of the following description of an embodiment-preferred tion of a radiator according to the invention, description given by way of example only and with reference to the sins annexes on which:
- Figure 1 shows the electrical diagram of principle of a radiator ~ accumulation fitted with a dispo-regulation sitive according to the invention;
- The Fiyure 2 represents the electrical diagram dcl: go to Gircu ~ it dc reyulcltlon of the device of 1 E; 'iyure l;
- I, a Fjyure 3 illustrates the possibilities of adjustment day reminders when using a load potentiometer;
- Fi ~ ure 4 is a diagram of two curves ideales for charging a device according to the invention in function tion of the outside temperature and for two modes of walking: 3 h and 24 h respectively, and - Figure 5 illustrates the choice of level of discharge from which recovery is possible according to display of the load potentiometer.
On the Fiyure 1 we have represented in 1 the elements i ,, . .

7 ~

heaters of the accumulator core, in 2 the temp ssnde-erasure of the nucleus, in 3 the regulation box of the charge and discharge of the core, in 4 the potentiometer of charge of the core, in 5 the room thermostat incorporates its the apparell, in 6 the inter-.

_ 3 ~
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, .. .....

breakers on / off of the restituti.on circuit by tur-bine 7, I2 start / stop of the charging circuit and I3 start / stop stop additional heating (revival of the core), at 8 re-remote control and in 9 the power strip in 5 electric current (three-phase or single-phase).
The re ~ ulation box 3 is shown in more detail tail, with regard to its electrical diagram, in FIG. 2.
We have represented in Rl, R2, R3 the three relays of commissioning of the three heating elements 1 (split on 10 Fig. l).
The three relays R ~, R2, R3 are energized using two transistors T ~ and T2 controlled by a first photocoupler P ~ itself controlled from a clock signal H de-termi-during off-peak hours at night or of the signal Th delivered by the 15-room thermostat 5 (Fig. L).
The photocoupler Pc ~ is interposed between the transis-tors T ~ and T2 and the output of a dif amplifier: Eérentiel A
whose inverting input is connected to the 2O core probe The non-inverting input of amplifier A ~ is 20 connected via an operational amplifier A.2, mounted as a voltage follower, with a six-position switch (rotacteur) ~ we have a rep: res ~ nte in C the moving cursor avoc his contact key t.ravail C'l '. Ie cursor C is double ~ and cornpor-te two contacts C'L 'soliciaires dclns leu: r displacement ek. ~ uscept: l-25 hles ~ e cooper (, r each with ~ In set of s: ix fixed contacts a, b, c, ~
I:, es contact3 a ~ tb cor ~ e ~ pon ~ ent to an operation normal cllt of ap ~ areil, that is to say without regulation of the ex-térleux (without taking account of parameters outside the premises), 30 sc ~ it in 8 hour version (contac-t a), or in 24 hour version (contact b).
To this end, the contacts a, b are likely to connect the cursor Cc of the load potentiometer 4 to the amplifier cateur ~
The contacts c and d correspond to an operation of the device with an external control circuit Re, i.e.
in ~ hour version (contact ~), or in 24 hour version (con-t ~ t (l).
Finally, 1e ~ CJ cont ~ cts e and f correspond to a function-~ () neUIent de llapparf'.iL with regulat.lon via a temperature sensor outside the Se room, either in version 8 hours (contact e), or in a 24-hour version (contact f).
The r ~ glette 8 of -télécomman ~ e of the device (~ ig. 1) allows to connect the bo ~ tier 3 to the external probe Se by 5 the connection terminals 13 and 14. The terminals 15 and 16 allow try connecting to the circuit ~ e of external recJulation and terminals 17 and 18 allow connection ~ if necessary a ThM wall-mounted room thermostat (in sub ~ itution with thermos-incorporated state 5) placed in a place-t choi. ~; i.
In the box 3 is also incorporated a poten-- PR so-called stimulus gauge, the control button of which is accessed sible to the user. This PR potentiometer is inserted in the voltage follower link A ~ - amplifier Al so ~
modify and adjust the voltage level applied to the non-input inverting amplifier Al.
The PR potentiometer is turned on or off by a transistor T 3 itself controlled by a second photocoupLeur PC2 excited by the clock signal H. The pho-tocoupler Pc2 is also connected to one of the rotator CT working contacts 20C (right CT contact in fig. 2). This CT contact allows to connect the pho-tocoupler Pc2, ~ un -transis-tor T ,, de co ~ nande of the transistor Tl when c ~ r is opposite the contacts a, c, and e.
~ nfin, we repr ~ felt in l9 a trans ~ orrtlateur abaLs-~ eur de kensi.orl de ~ t: Ln ~ ~: I.'aLi ~ nerltatlon ~ leckr.l. ~ ue d ~ cir ~ uits

2 ~ by: the interm ~ cl: i.aire of a bridge redres.c, eur ~ (J, dlun conderlsateur 21 de ~ iltra ~ Je, d'wn stab: L] .: voltage isator 22 and a second capacitor 23 from Eiltraye.
The operation of the installation represents ~ e and described above is as follows.
According to a first characteristic of the installation tion, it is possible by a simple operation of the cursor of the rot, actor C, to put back the device: L in 8 hour version or in version 2 ~ hours.
In 8 hour di ~ e and 24 hour di version 351a charye of the nucleus is carried out in the same ~ ne rnani ~ re, pr ~ ference over a period of eight hours, at night, corresponding to so-called hollow hours6 (10 p.m. 6 a.m.).
By cons, during the res-titu-tion in the day ~ e ~ e ~ ne ~ ryie e ~ rurla ~ ar ~ in ~ e, it is possible ~ in ~ hour ~ version ~ ' . , to restart a fraction of the installed power while in 24 hour version the relaunch is done on all of the power ins-tall ~ e.
For operation in an 8-hour version, the CT tacts of the rotator are opposite the contacts a (position I), however for 24 hour operation, the CT contacts are put in position II (contacts b).
Thanks to potentiometer 4 of charye of the nucleus we regulate the maximum accumulating power used or power 10 accumulated.
In the 8 hour version, it is possible to install a power ~ equal to 2.5 ~ 3 times the losses (expressed in Kwh) of the room in which the device is installed.
We have, in fact, found that for this operating mode-15 nement a power installed ~ e included in said fourchettepermettait virtually eliminate overpower.
However, for 24-hour operation it is an installed power of 1 to 1.2 times the losses of the room which gives the best yield, taking into account the mode of 20 prices (current hours / full hours) current.
Then, with the same device designed according to the invention t: ion, it is very ~ acile for the utility: Lisat ~ eur d'lnstalle: r .la pu: Ls-sance opt.ima.1.e depending on the operating mode (~ heureL;
or 24 hours) chosen by ut: L: I.: Lc ~ ateu.r.
~ 5 Le po ~ el1t; lo m ~ ~ x ~ 4 pe rm et: une ada ~ tation (or correction) of the accumulating power in operation: Lon ~ e the season and the ~ one yéo ~ raphique in which is situated ~
the room ~ heat.
As we saw earlier, the choice between 8 and 24 hours 30 res exist for three types of operation of the installation, know :
. normal operation: rotator C in position I (8 h) or II (24 h);
. operation with external reyulation Re: (rotator C in position III (cr - c) for ~ h and in position IV IC ~ - d) for 24 h);
. - ~ onctctioning with. external probe Se; (rotator C erl pos: it.ion V lC ~ e) for ~ h and in position VI
(~ 'l ~ f) for 24 hj.
-G-1 ~ 3 In the 8-hour version, whatever the position (I, III or V) of rotator C, the three resistors R ~, ~ 2r R3 are simultaneously operating at night (off-peak hours).
In fact, the night clock phase H is active and excites the photocouplers Pc ~ and Pc 2 -The photocoupler Pc ~ authorizes the control of the tran sistors Tl and T 2 and the photocoupler Pa 2 condemns the transis-tor T 4 thus allowing the transistor Tl to be controlled ~
at the same time as T 2 `
During the night charge the photocoupler PC2 con-also damn the transistor T3 which disables the PR boost potentiometer.
The amount of stored energy is determined.
essentially born by the difference between the temperature of the nucleus (temperature detected by probe 2) and a first reference temperature constituted by a first maximum threshold bad temperature and displayed, either by the potentiometer load 4 (position I of rotator C), either by the external regulation Re (position III), either by the probe ex-Se (position V). If, for example, the kernel has to be charyed in 8 hours at 100% of the installed power, the Resistors 1 will be permanently in use over 8 hours ~
If, on the other hand, the core should not be loaded ~ 100 ~ at after 8 hours, the resistarlces 1 are put into servlce pen ~
ant une clur ~ e In ~ r.: leure ~ ~ 3 ileur ~ L in order to l; Lm; iter la ~ uantlt ~
d'frler (lle elnlna ~ Ja ~ ln ~ e. Cettc- ~ r ~ yulatLon is e ~ fectu ~ e by arn-pLl ~ i ~ atellr di ~ rentiel ~ I coand or not switching the transistors Tl, T2, depending on the difference between the core temperature and one of the three reference temperature thresholds.
On the other hand (always in 8-hour version), by day, one only resistance (R 3) is likely to be restarted under the control of the differential amplifier A which is triggered depending on the difference between the temperature of the nucleus ~ probe da n ~ yau 2) and a second reference temperature.
~ ne ~ fet, by day, the photocoupler Pc2 is no longer e ~ cit ~ and the transistor T4 which is no longer condemned ~ locks T
en ~ orte that the recovery will only concern resistance T ~ ~ ol ~ unandant the resistors ~ 1 and R2 and 'r2 cornmandant la res ~ sistarlce l ~) when ~ the therrno ~; mood will send the , ~, : ~ 19 ~ 3 active signal Th and will control the pho-tocoupler Pci, Ladi-te second reference temperature is a second maximum variable temperature threshold according to the positlon (I, III, or V) of the rotator C. In position I, the amplifier A ~ holds account to trigger or not the difference between the time-kernel temperature and the temperature threshold displayed by the user launcher on the PR stimulus pot.
In fact, the photocoupler Pc 2 not being exci-t ~, the potentiometer ~ I ~ then determines, depending on the position of the cursor Cc of the load potentiometer 4, the stop threshold of the stimulus by comparison (by A l) with the core probe 2.
The PR boost potentiometer therefore makes it possible to modulate the maximum temperature threshold reached by the nucleus during each reminder, this threshold being understood ~ within a range of temperatures itself determined according to the position , of the cursor Cc of the load potentiometer 4. FIG. 3 illustrates these adjustment possibilities.
There is shown on the ordinate in this fig. 3 the time.
kernel temperature in degrees C and on the abscissa the percentage of using the load potentiometer 4 ~
Curve A corresponds to the night load (position I or II of the rotator C) according to the position of the cur- ~ e ~ ur Cc of potentioln ~ t, re of charge ~ 4. At 100 '~ of use: Lsation la kemp ~ .ra-ture rrlclx: i.rnale ~ imag ~ llli5C of the nucleus is of ~ lron 193C. At 50de J, a court ~ e dll cur.C; eur Cc, this temperature is no longer ~ ue 1 () 5 C.
Curve B represents the maximum temperatures allowed for the nucleus during day raises with ie poten-PR stimulus tiometer in maximum stimulus position. Lacourbe C corresponds to the maximum temperatures allowed for the - nucleus during day raises with P ~ in raise position minimal. So we see for example ~ u'avec use ~ 100 ~ of the poten-tiom ~ kre of charge 4 the revival potentiometer allows to snodulate the maximum temperature reached by the nucleus in a temperature range between 50 C and 115 C
about. With Ull cursor Cc halfway l50 ~) said range of temp ~ ratl1res lirrlites du no, yau is between 47 C and 70 C approx.

_ ~, During the recovery, one of the resistance ~ 1 (R3) and the blowing turbine 7 are put into temporary operation then out of service.
In position III of the rotary switch C, the amplifier A
takes into account the temperature difference between the core and a reference temperature supplied by the re-circuit external regulation Re and itself modulated by the potentiometer PR stimulus following a range whose amplitude depends on the external reference in the same way as the case of the poten-charge tiometer (fig. 3) Finally, in position V, the amplifier Al-takes into account of the temperature difference between the nucleus and a temp ~ -reference strip supplied by the external probe Se, it even modulated by the stimulus potentiometer.
This probe head is for example a thermistor ~ coefficient of negative temperature placed on the exterior facade of the room preferably north facing.
For a given thermistor, the slope of the curve load is fixed but the thermistor can be changed and adapted to climatic conditions of different regions.
In 24-hour version, whatever the position (II, IV or VI) of the rotator C, the three resistors Rl R2, R3 are simultan ~ ent in serv: ice or out of serv: i ~ e as well the night closed ~ day.
By day, in eff-f3 ~, Ia reLarlce se ~ a: Lt sur le ~ s troi ~
r ~ Lstance ~ and following ~ exactly ~ es same modalit ~ s in po ~ 3; itl0n II, IV and VI of the rotator C only in position I, III and V.
Ia Fig. ~ shows the ideal curve in solid lines 8 hour charge of the device depending on temperatures outside the room. In Fig. 4 there is shown in ordon-born the charge level of the nucleus of the device expressed in pros centering and abscissa the temperature outside the room such than detected by the external probe Se.
It is thus that for an outside temperature of OC, the no ~ au is charyed after 8 hours ~ 87 - 90 ~ of its capacity (determined and displayed by the load potentiometer ~, col ~ urle explained ~ more above).
~ Jowr u ~ le terllp ~ ratllre ext ~ riewre de - 10C, le nucleus is increased ~ ~ its capacity rnaximc, Le (~) uisC; ance installed ~ e) ,, ~

VS! ~ l ~ V9 ~ 3 We have represented ~ dashed the ideal curve the load in 24 hewres version. With an outside temperature of O ~ C
the core is loaded ~ 97 ~ with its capacity (installed power) at the end of the charging period, which is always a hour (as in 8-hour version).
For a temperature of + 10 C, it is charged ~ ~ 82 envirpn (while it is only 57 ~ in version 8 hours, but with a higher installed capacityJ.
These two curves are ideal in the sense that they allow adjustment of charge and return levels ~
tion of f ~ energy stored in the bare essentials. They correspond to lay ~ a thermistor ~ CTN de-finished. This is the kind of curves which is obtained by placing the rotator C in position V or VI.
For a different thermistor ~ C'l'N, we will get curves which will be the same but translated.
Load corrections as a function of temperature outside ture are done automatically thanks to the circuit of regulation of FIG. 2.
During the release period in version 8 hours, the therrnosta-t of ~ nbiance 5 turns on and off-vice the blowing tur ~ ine 7 according to: The needs displayed.
In 24-hour version, the -thermostat 5 controls, c ~ u ~ l whatever the moment, the turbine 7 ~ cJcllenlent en ~ onctlon des be ~
25 <; OlrlS cl ~ iCh ~ S ~ ~ n clf: h ~ rs d ~ La p ~ rio (le de ~ charye.
rJCI lk ~. 5 repr ~ sentf3 keys of level of load clu nucleus ~ from dwquel the relarlce will be poss: i.ble given of ~ the positlon of the re-setting of the load potentiometer 4.
This potentiometer determines the accumulated power. We has represented six positions (1 to 6 ~ of this thermostat on the abscissa however ~ u'en ordonn ~ e is carried the percent of the charge of the nucleus.
The ~ four curves shown correspond to ~ qwa-tre positions of the cursor Cc of the load potentiometer 4, respectively tivermenk resets to 1/4, ~ 1/2, 3/4 and maximum threshold.
The ~ onct: tion curves correspond to the posi-I and II rotator C (~ or 24 hour version).
For each pos: i-tion of the cursor (c, the correction of ni ~ / e, ~ le restitlltior1 (reJ.arlcf) Sf faik awtornatiquement gr ~ cf3 , ~ 9 ~ 3 ~.

at the fiy circuit. 2 and according to the shape of the curves of Fig. 3. Note that the device does not stop auxiliary convector for the recovery.
Such a device therefore has a very large flexible ~
adapt to the room to be heated and used while avoiding excess power, waste and adjusting the levels of restitution of stored energy or events reminders in full hours as strictly necessary and level chosen by the user.
Of course, the invention is not limited ~ e to mod ~
shown and described above but covers on the contrary all the variants in particular with regard to electronic means of control, switching on and off heating resistors service according to the different parameters taken into account.

Claims (12)

The realizations of the invention on the subject of-what an exclusive property right or lien is claimed, are defined as follows: 1.- Characterized electric storage heater in that it includes means for limiting the power accumulative useful according to the losses of a room where the radiator is installed, consisting of a potentio-load adjustment meter, means for storing during a specified period of the day a quantity of variable energy depending on the difference between the temperature ture of a core of the radiator and a first temperature of reference and means to possibly revive all or part of the installed power, during a restitution period extending over the rest of said day, depending on the difference between the temperature of the nucleus and a second reference temperature. 2.- Radiator according to claim 1, character-se in that said first reference temperature during charging is a temperature threshold displayed by the user via said potentiometer charge. 3.- Radiator according to claim 1, character-se in that said first reference temperature during charging is a temperature threshold displayed at from a control circuit outside the room and controlling several radiators in a set. 4.- Radiator according to claim 1, character-se in that said first reference temperature during charging is a temperature threshold displayed by a probe outside the room. 5.- Radiator according to claim 4, character-in that the outdoor sensor is arranged on a facade of the room facing north. 6.- Radiator according to claim 1, character-that said second reference temperature is during the possible revival is a temperature threshold displayed by the user via a poten-stimulus tiometer allowing a range of temperatures limits of the nucleus during reminders, said range being itself modulated according to the position of said poten-charge tiometer. 7.- Radiator according to claim 3, character-in that said second reference temperature during the possible revival is a temperature threshold displayed from the external control circuit and modulated by the user through a potentio-stimulus meter. 8.- Radiator according to claim 4, character-in that said second reference temperature during the possible revival is a temperature threshold displayed by the external sensor and modulated by the user via a stimulus potentiometer. 9.- Radiator according to claim 1, character-se in that it includes a multi-position switch per-putting the core at night depending on the gap between core temperature and first temperature of reference chosen from three reference temperatures displayed respectively by:
-1) the load potentiometer;
-2) a regulation circuit outside the room;
-3) a temperature sensor outside the room;
and allowing to possibly revive the kernel during the day as a function of the difference between the core temperature and the second reference temperature chosen from three reference temperatures displayed respectively by:

-1) a stimulus potentiometer within limits tes determined by said load potentiometer;
-2) said stimulus potentiometer in li-moths determined by said external regulation;
-3) said stimulus potentiometer in limits determined by said external probe. 10.- Radiator according to claim 9, characterized in that the means for controlling the load and the possible relaunches of the core as a function of said references temperature rences consist of an amplifier differential having a first input connected to a probe of core temperature and a second input connected by via a voltage follower stage multiposition mutator, said differential amplifier having an output which controls resistance excitation heating tances under the authorization of a first photo-coupler controlled by clock signals or by signals from a room thermostat, a second photocoupler controlled by said clock signals being responsible for deactivate said stimulus potentiometer at night interposed between said voltage follower stage and said differential amplifier. 11.- Radiator according to claim 9, characterized in that for each of the above three temperatures of load reference and the three above temperatures stimulus reference corresponding to them respectively, said multi-position switch has two positions, one authorizing the revival of only a fraction of the installed power, and the other authorizing the revival of all of this installed power. 12.- Radiator according to claim 10, characterized in that for each of the above three temperatures of load reference and the three above temperatures stimulus reference corresponding to them respectively, said multi-position switch has two positions, one authorizing the revival of only a fraction of the installed power, and the other authorizing the revival of all of this installed power, and that the recovery of all or part of the installed power is eff-made through a working contact of the said multi-position switch connected to said second photocoupler and associated fixed contacts connected to an auto-transistor power supply of part of the resistances of heater.