FR2644584A1 - Electronic heating consumption distributor for communal housing (blocks of flats) - Google Patents

Abstract

The device according to the invention is an apparatus making it possible to measure the energy supplied by the convector, in order to allow distribution between the tenants of a block of flats. It comprises: two oscillators combined with two thermistors making it possible to obtain a frequency which is a function of the temperature of the radiator as well as the room air temperature, means making it possible to measure the frequency difference between these two oscillators, means for storing the measurement, and finally means making it tamper-proof.

Description

 The present invention relates to devices intended to allow the distribution of heating loads between the different tenants of a building, according to the actual consumption of each.

 More specifically, it relates to devices using a measurement of the surface temperature of radiators, and more particularly those with electronic sensors.

 In known devices of this kind, a thermistor is used placed in contact with the radiator, which, inserted in a suitable oscillator, converts the temperature into a frequency. The oscillations thus obtained are counted. The total is accumulated in an electronic or mechanical counter.

 These devices have the disadvantage of being quite expensive. In addition, they do not take into account the ambient temperature of the room, and therefore provide an erroneous measurement.

 The device according to the invention avoids these drawbacks, because it is much simpler to carry out, despite the fact that it is capable of making a more precise measurement, since it takes account in the calculation of the consumption of the temperature of the room, which penalizes users who push the heating thoroughly when opening the windows.

The invention relates to an electronic distributor of heating consumption for collective housing, comprising: two thermistor Ri and
R2 inserted in the circuit of two oscillators (2), (3) and (6), (7), means (8) and (9) allowing the subtraction of the oscillations of the two oscillators, means (10) allowing to store the result of successive subtractions, and finally security organs (21), (22), (24), (25), (29), (30), making the device inviolable.

 According to another characteristic, the thermistor R2 is in thermal contact with the wall of the convector, while the thermistor R1 is in contact with a metal part, which is at ambient air temperature.

 According to another characteristic, the thermistor R1 is replaced by a simple resistance.

 According to another characteristic, the means (8) and (9) making it possible to subtract, for a given period, the number of oscillations of each oscillator, are binary counters.

 According to another characteristic, the means (10) for performing the subtraction of the oscillations of the two oscillators consist of an up-down counter.

 According to another characteristic, the means making it possible to store a number of oscillations are constituted by a series of binary counters, possibly followed by a mechanical or thermal counter.

 According to another characteristic1 the safety devices making the device inviolable consist of a fuse (25), controlled by a flexible blade switch (ILS) (24), itself actuated by a permanent magnet (22), which radiates a magnetic field influenced by the presence of the convector, or by a mechanical switch (30).

The characteristics and advantages of the invention will emerge more clearly from the description which follows, given with reference to the accompanying drawings, in which:
- Figure 1 shows the operating principle of the electronics for performing the subtraction of the oscillations delivered by two oscillators. It gives the oscillograms present at the main points of the circuit.

 - Figure 2 shows a block diagram of the electronics used.

 - Figure 3 shows the positioning of the two thermistors R1 and R2.

 - Figure 4 gives a real diagram, which can be used.

 - Figure 5 shows in two views (section and left view cover removed) the bolier of the device.

 - Figure 6 shows the deformable membrane switch for arming security.

 - Figure 7 shows the operation of the ILS to detect any "disconnection" of the device.

 - Figure 8 shows the electrical safety circuit.

 - Figure 9 shows a mechanical version of the safety switch.

 Referring to Figure 1, we can understand the principle of the distributor. A first oscillator delivers square slots (Figure la) whose frequency F1 is a function of the temperature T1. This result is obtained using the oscillator (1), shown in Figure 2.

This can be achieved, for example, by using an inverting "and" gate (2), followed by an inverting amplifier (3), the output of which drives a binary counter (8), at the same time as it is connected to a capacitor C1. The other terminal of this capacitor is connected to a thermistor R1 whose other connection goes to the input of the amplifier (3), at the same time as a resistor (4) whose other connection goes to the input of the reversing door (2). This well-known diagram gives an oscillation whose frequency F1 is
Fl = (1)
2.3 R1 C1
If R1 is constituted by a thermistor, the ohmic value of R1 depends on the temperature according to the law 1 1
B (- - -)
R1 = R1 e T1 T0 (2)
(T) (T0) where B is a coefficient generally between 2 800 and 4 450
Kelvins and R1 (T0) denote the value of R1 at temperature To, which is arbitrary.

 For the case at hand, it is practical to take To = 273 (temperature of 0 Celcius).

Under these conditions, expression (2) becomes
B (273 - T1)
R1 = R1 e 273 T1 (3)
(T) (273)
To fix the ideas, let's take an average value of B. For example
B = 3500 K and let us pose: T1-300 ee expressing the temperature in degrees Celcius.

 We can then write a simplified form of the relation (3) by noting that T1 varies in fact quite little in our application, say from 300 to 360 K, and that, consequently, we can replace it by an average value of 330 K .

We then find:
-3.88.10-2 e
R1 = R1 e (4)
(e) (o)
We can then express F1:
F1 = (5)
(e) -3.88.10-2 e
2.3 Cl R1 e
(o)
This oscillator attacks the binary divider (8), of which an output S corresponding to a division by N. is used. Its temporal variation is shown in FIG.

 A second oscillator (12), shown in Figure 2, is similar to the previous one. It uses to fix its frequency F2 a capacitor C2 and a variable resistor R2, which can also be constituted by a thermistor. The output of this oscillator is shown in Figure lc. It is noted that the oscillation is interrupted periodically, that is to say as long as S1 is in the high state. This is obtained by using the output SI to block the door (6) and, consequently, to prohibit the operation of this second oscillator (12) at the same time as the contents of the counter (9), which is attacked by said oscillator, is reset to zero.

 Thus, the oscillator (12) operates between times t2 and t4.

The oscillogram of figure id represents the state of the S2 output of the counter (9). Between tl and t, the level is low, since S1 performs a reset. Between 52 and t3, 52 is low, until the number
N is reached. At this instant, noted t, the output S2 becomes high, and the rest for the duration #t, between t3 and t4.We can write the relation:
1 1 #t = N = [- - -] (F1 # F2) (6)
F1 F2
During the interval #t the output of the oscillator (1) can be transmitted to the storage counter (10), via the resistor (11). Outside this time interval, the input of the counter (10) is kept low by the diode D which is connected to the output S2.

The oscillogram in the figure shows it the n pulses entering the counter (10) and which are equal to:
1 1
n = F1 N [- - -] (7)
F1 F2
Now, we have: 1
F1 = (8)
2,3 C1 R1 e-3,88.10-2 # 1 (o)
and:
1
F2 = (9)
2,3 C2 R2 e-3,88.10-2 # 2
(o)
For simplicity, we will take: R1 (o) = R2 (o) = Ro and C1 = C2 = C, which allows us to express n.We thus find, all calculations made: n = 2.3 F1 N Ro C e -3.88.10-2 # 1 [1 - e-3,88.10-2 (# 2- # 1)] (10)
By setting R '(thermistor value at room temperature) such that
-3.88.10-2 t (11)
R '= Ro e
we have :
n = N [1 - e-3,88.10-2 (# 2 - # 1)] (12)
which shows that n is a function of the temperature difference between the two sensors Ri had R2. If (# 2- # 1) is small, relation (12) takes the simplified form:
n = 3.88.10-2 N (# 2 - # 1) (13)
Thus, the counter (10) will accumulate the different values Ni corresponding to the temperature differences (# 2- # 1) i recorded during a long period t (for example, a few months). It indicates a number Nc such as: tFl / N
Nc = z 3,8.10-2 N (92-el) i (14)
i = l
To give an idea of the result obtained, we will admit that (# 2- # 1) remains constant, or more exactly that we know how to define an average value
zon = -ol.

The relation (14) then becomes remarkably simple
Nc = 3.88.10-2 F1 mt (15)
Let us now examine the functioning of a domestic radiator.

Its surface temperature, which should be designated by # 2, is generally too low for heat exchange by radiation to play a significant role. These are the convection phenomena which will allow the "radiator", which it is preferable to call "convector", to transfer its energy to the ambient air, which is at the temperature ei.
P thus exchanged can be expressed by the relation:
P = A (# 2- # 1) (16) where A is a coefficient which depends on the shape and the surface of the convector.

The device that we have just described makes it possible to measure this power. Indeed, by combining (14) and (16), we can write:
tF1 / N
Nc = 3.88.10-2 N # Pi (17) A i = 1
We can as before, define an average power Pm. We have then
3.88.10-2
Nc = Fl Pm t (18)
AT
This result can still take an integral form
3.88.10-2 t
N, Fîf P (t) dt
AO
It can therefore be seen that the content of the counter N is representative of the energy dissipated in the room by the radiator. It is therefore an excellent means of measuring energy consumption.

It should be noted here that the system could operate with a single thermistor, R2 in this case. In this case, R1 would remain constant and, therefore, F1 too. This would amount to saying that the ambient room temperature is assumed to be constant, which is not necessarily the case. To be convinced of the interest of a device measuring the real temperature differences, let us examine two identical radiators, placed in identical rooms, except that the first is well insulated and the second poorly insulated. The temperature o2 of the second radiator will be lower than that o2 of the first radiator, if the temperatures and water flow rates are identical. With a measurement with a single thermistor, we will therefore find that the poorly insulated room consumes less energy
Figure 3 shows the practical arrangement of the two temperature probes. The thermistor R2 is fixed to the body (13) of the convector, while the thermistor Ri is placed at a distance, so as to be in contact with the downward flow of ambient air. The two thermistors are electrically connected to the electronic shoemaker (14) whose function has been detailed above.

 FIG. 4 represents, by way of indication and of course in no way hesitant, an exemplary embodiment of the electronic circuit. It consists of four CMOS integrated circuits; two 4060 and two 4020.

The first two include an R-C oscillator, giving the frequencies F1 and F2, while the last two are 14-stage binary dividers. They are connected in series and constitute the storage counter (10), which therefore has a total of 28 floors, which allows it to count up to 6.68.108. Only the 10 most significant bits come out on a 13-pin socket (15) (one for ground, one for reset, and finally one to check that the device has not been violated).

The oscillator F1 has a frequency close to 10 Hz. The division in the counters (8) or (9) is carried out on 9 bits. N is therefore worth
N = 512
The frequency at output S1 is therefore 10/512 = 1.95.10-2 Hz (51 s period). Thus, every 51 seconds, a measurement is made.

The number of counts counted for each measurement is therefore
n = 19.86 (q2-q1) (20)
For a temperature difference of 50 "C, we will therefore count
n50,993 shots
We see that the precision can be excellent.

The number of strokes per day, on the same assumption of o = 50 C, will be:
n50 .1 day = 1.68.106
or again, for a heating year, which can be estimated at 100 days
nan = 1.68.108
which allows, given the capacity of the meter, to store 4 years of heating.

The number recorded on the counter, therefore on the 10 bits accessible, will be
Nc (1 year) = 640
We feel that, even for low consumption, say the tenth for example, the accuracy of the measurement will remain in the order of a percent, which is excellent.

 The mechanical mounting of the device according to the invention is shown diagrammatically in FIG. 5.

 The shoemaker consists of two shells. One (17) is plastic and has a brass insert (16), which is in thermal contact with the convector, not shown in the figure. The other shell (18) is made of die-cast aluminum, and has fins allowing as good thermal contact as possible with the ambient air. This case (18) is in thermal contact with the thermistor R1, while the insert (16) is in thermal contact with the thermistor R2. On a printed circuit board (26) are fixed all the electronic components and in particular the circuits integrated (23), a flexible blade switch (ILS) (24), a deformable blade switch (21), a resistance rated fuse (25) and the power supply battery (20).

 The two shells of the case are assembled by means of two or three screws (27), placed in such a way that they are inaccessible when the device is fixed on the convector.

The shell (18) has in its center a hole in which one can introduce a rod (19) comprising at its end 13 touch points which will be supported on the tracks of the printed circuit so as to establish a contact. The connector (15) indicated in FIG. 4 is thus produced. This operation enables the counter (10) to be raised.
To avoid that the distributor according to the invention cannot be disconnected by an indelicate user, it comprises a break-in detector, which essentially consists of an ILS (24), which closes as soon as the distributor is no longer in contact with the metal (steel) surface of the radiator. This result is obtained thanks to the arrangement of FIG. 7.

A permanent magnet (22) is inserted in the plastic shell (17), so as to be very close to the wall of the radiator. Its magnetic flux therefore closes by this wall. If we remove the wall, it spreads in space and can act on (24), causing it to close. This ILS (24) is placed in the circuit of FIG. 8. When the distributor is assembled with the radiator, one can introduce, by a hole provided for this purpose in (18), a thin steel rod which comes to close the contactor with deformable blade (21)
If the ILS (24) closes, it destroys the fuse (25), the integrity of which can be checked each time a lift is made. A "break-in test" output is available on the connector (15). Figure 6 shows a detail of the contactor (21). It essentially consists of a circular metallic membrane (27), stamped in its center following a spherical cap. It is bonded to the printed circuit (26), via an insulating spacer (28), so that a track of the printed circuit passes below. It is also electrically connected to another track by bridging. If we press on the membrane, which is originally convex, with a rod, we suddenly deform the membrane, which then becomes concave (dotted lines), which ensures contact between the two tracks, without it being possible, with the rod, to go back. Security is therefore armed. "

 The distributor can be attached to the convector by means of the insert (16), which can be screwed or riveted on said convector.

It is also possible to have an insert leveling the flat surface of the bottom of the housing (17). I1 can then be glued to the convector surface.

 According to another embodiment of the invention, the oscillators (1) and (12), delivering frequencies F1 and FZ, each drive a binary divider by N. The two outputs of these dividers attack a down-counter, which makes information storage office directly. Security is achieved this time by replacing the ILS (24) by a mechanical switch, shown in Figure 9. It is constituted by a flexible blade (30), ensuring contact at its end with a track of the printed circuit (26 ), on which it is welded. In the "closed case" position, the blade is pushed back by a rod (29), which leaves the case (17) through a small hole. If we take off (17) from the wall of the convector, the contact closes.

Claims (6)

 1) Electronic distributor of heating consumption for collective housing, characterized in that it comprises two thermistors, R1 and R2, inserted in the circuit of two oscillators (2), (3) and (6), (7), means (8) and (9) for subtracting the oscillations of the two oscillators, means (10) for storing the result of successive subtractions, and finally safety devices (21), (22), (24 ), (25), (29), (30), making the device inviolable.  2 *) Device according to claim 1, characterized in that the thermistor R2 is in thermal contact with the wall of the convector, while the thermistor R1 is in contact with a metal part which is at ambient air temperature.  3 *) Device according to claim 1, characterized in that the thermistor R1 is replaced by a simple resistance.  4 *) Device according to claims 1, 2 or 3, characterized in that the means (8) and (9) for subtracting, for a given period, the number of oscillations of each oscillator, are binary counters.  5) Device according to claims 1, 2 or 3, characterized in that the means for performing the subtraction of the oscillations consist of an up-down counter.  6 *) Device according to claims 1 to 5, characterized in that the means (10) for storing a number of oscillations, are constituted by a series of binary counters, possibly followed by a mechanical or thermal counter.  7g) Device according to any one of claims 1 to 6, characterized in that the safety members making the device inviolable consist of a fuse (25), controlled by an ILS (24), actuated lul-meme by a permanent magnet (22) which radiates a magnetic field influenced by the presence of the convector, or by a mechanical switch (30).