FR3120952A1 - Method for regulating a heating apparatus and associated heating apparatus - Google Patents

Abstract

Method for regulating a heating apparatus and associated heating apparatus A method (202) of controlling a space heating apparatus, said apparatus comprising an electrical heating element; a control module able to adjust a room temperature to a set temperature; and a presence detector (20) in the room, connected to the control module. The control module memorizes several successive time slots, each associated with a programmed value of the setpoint temperature. According to the method, if the detector (20) detects no presence in the room, the setpoint temperature is lowered (206) to a target temperature lower than the programmed value. Depending on the difference between the programmed value of the range and the target temperature, the reduction is carried out directly or in the form of at least two successive temperature reductions. Figure for the abstract: Fig. 2

Description

Method for regulating a heating apparatus and associated heating apparatus

The present invention relates to a method for regulating a heating apparatus of a room, said apparatus comprising: an electric heating element; a control module capable of controlling said heating element so as to adjust a room temperature to a setpoint temperature; and a presence detector in the room, connected to the control module; the control module storing several successive time slots, each time slot being associated with a programmed value of the setpoint temperature, the programmed values of two successive time slots being distinct.

In electric heating installations, it is desirable to lower the set temperature of a room when it is not occupied. To this end, it is known to control the heating devices using a program anticipating the time slots of occupation of the rooms. This programming includes, for example, two setpoint temperatures, one corresponding to a “comfort” mode and the other to an “eco” mode.

It is also known to make use of a presence detector in the room and, when an absence is detected during a time slot in “comfort” mode, to trigger the switch to “eco” mode.

However, such a solution does not take into account multiple uses of the same room, which could be associated with multiple operating temperatures to optimize the comfort/energy saving ratio.

To this end, the subject of the invention is a regulation method of the aforementioned type, comprising the following steps: the setpoint temperature being equal to the programmed value of a time slot in progress, activation of the presence detector; then if the detector detects no presence in the room, lowering the setpoint temperature to a target temperature below said programmed value; so that: if a difference between the programmed value of the range and the target temperature is less than or equal to 1° C., then said lowering is carried out directly; and if said difference is greater than 1°C, then the lowering is carried out in the form of at least two successive decreases in temperature, each decrease being less than or equal to half of said difference, two successive decreases being separated by a first duration not zero.

According to other advantageous aspects of the invention, the regulation method comprises one or more of the following characteristics, taken in isolation or in all technically possible combinations:

- during the lowering step, each of the successive temperature reductions is greater than or equal to 0.5°C;

- the first duration between two successive temperature reductions is greater than or equal to 30 minutes;

- if the programmed value of the current time slot is less than the programmed value of the next time slot, the method then comprises a step such that, over a second duration before the transition to the next time slot, the setpoint temperature is increased to said programmed value of the next time slot;

- the control module stores an absence temperature, less than or equal to each of the programmed values of the successive time slots; and in that the target temperature of the lowering step is said absence temperature;

- if the programmed value of the current time slot is greater than the programmed value of the next time slot, the target temperature of the lowering step is the said programmed value of the next time slot;

- if the programmed value of the current time slot is lower than the programmed value of the next time slot and greater than the programmed value of the previous time slot, the target temperature of the lowering step is said programmed value of the previous time slot.

The invention further relates to a heater for heating a room, comprising: an electric heating element; a control module capable of controlling said heating element so as to adjust a room temperature to a setpoint temperature; and a presence detector in the room, connected to the control module; said device being provided with means for implementing a method as described above.

The invention further relates to a heating installation comprising a first room and a first heating device as described above, installed in said first room.

Advantageously, the heating installation further comprises: a second room; a second heater as described above, installed in said second room; and a centralized management unit, connected to the first and second heating devices.

The invention will be better understood on reading the following description, given solely by way of non-limiting example and made with reference to the drawings in which:

there is a schematic view of a heating installation according to one embodiment of the invention, comprising at least one heating device;

there is a flowchart of a process for regulating the heating device of the installation of the ;

there and the are graphic representations of temporal variations of the setpoint temperature of the heating device of the installation of the according to the process of .

There shows a heating installation 10 according to one embodiment of the invention. The heating installation comprises a first room 12 and a first heating appliance 14 installed in said first room.

The first heating apparatus 14 comprises: an electrical heating element 16; an electronic control module 18, capable of controlling said heating element 16; and a presence detector 20 in the first room 12, said detector being connected to the module 18. The first heating appliance 14 further comprises a temperature probe 22, connected to the module 18.

Optionally, the heating installation 10 further comprises at least a second room 112, separate from the first room 12, and a second heating device 114 installed in said second room. The first 12 and second 112 rooms are, for example, two separate rooms in the same building.

Optionally, the heating installation 10 further comprises an electronic centralized management unit 100, connected to each of the heating devices 14, 114 of said installation.

The second heater 114 is considered to be analogous to the first heater 14 described above. The description above and below of the first device 14 also applies to the second device 114.

The module 18 of the device 14 is able to control the heating element 16, so as to adjust a temperature of the room 12, measured by the probe 22, to a setpoint temperature Tc, stored in said module 18.

More precisely, the module 18 stores a program 200 comprising several successive time slots P1-P6. Said time slots are represented schematically in FIGS. 3 and 4. Each time slot is associated with a programmed value T1-T6 of the setpoint temperature Tc.

The values programmed for two successive time slots are distinct. Said programmed values are preferably chosen according to a planned use of the room 12 according to the time of day. According to one embodiment, the programmed values T1-T6 corresponding to the time slots are adjustable directly by a user, by means of an interface of the module 18. Alternatively, the programmed values T1-T6 are adjustable at the level of the unit 100 centralized management.

The program 200 is also able to implement a method 202 for regulating the heating appliance 14, the method being schematically represented on the .

Method 202 includes the following steps:

The setpoint temperature Tc being equal to the programmed value Ti of a time slot Pi in progress, i being an integer, the presence detector 20 is activated (step 204). According to program 200, step 204 is implemented at a time t0 after the start of the current time slot Pi. The time t0 corresponds to a duration, zero or non-zero, after said start of the time slot Pi.

In step 204, if the detector 20 detects a presence in the room 12, the setpoint temperature Tc is maintained at the programmed value Ti.

We consider the case where the detector 20 does not detect any presence in the room 12. According to a first embodiment, during a first duration t1, the detector performs one or more other detections. If no presence is detected over the first duration t1, the method 202 proceeds to step 206 described below.

According to a second embodiment, the method 202 goes to step 206 from the first detection of absence in the room 12.

During step 206, the setpoint temperature Tc is lowered to a target temperature Te, lower than the programmed value Ti of the time slot Pi in progress.

If a difference between Ti and the target temperature Te is less than or equal to 1° C., then said lowering is carried out directly.

If said difference between Ti and Te is greater than 1°C, then the lowering is carried out in the form of at least two successive temperature decreases ΔT, each decrease being less than or equal to half of said Ti-Te difference. Preferably, each of the ΔT decreases is greater than or equal to 0.5°C.

Two successive decreases are separated by a second non-zero duration t2 which materializes a plateau 24 of temperature. Preferably, t2 is greater than or equal to 30 min.

Preferably, the temperature decreases ΔT and/or the second duration t2 between two successive decreases are calculated by the module 18 as a function of a set of parameters.

More preferably, said set comprises first parameters chosen from the values of Ti and/or Te and the power of the heating device 14. According to one embodiment of the invention, said set further comprises second parameters chosen between the insulation and the thermal inertia of room 12 as well as the meteorological conditions. Information on these second parameters is for example communicated to the module 18 by the centralized management unit 100.

Following step 206 of lowering, the setpoint temperature Tc is maintained at the target temperature Te (step 208).

During steps 206 and 208, if the detector 20 detects a presence in the room 12, the setpoint temperature Tc is raised to the programmed value Ti of the time slot Pi in progress.

Preferably, the method 202 then comprises a step 210 of anticipating the change in programmed value of the setpoint temperature. According to said step 210, at a time corresponding to a third duration t3 before the next time slot P(i+1), step 206 or 208 possibly in progress is interrupted and the set temperature Tc takes the programmed value T(i +1) of said next time slot. Said value is maintained until the change of time range. Process 202 is then incremented.

Similarly, if a first absence detection is performed during said duration t3, step 210 results in not implementing step 206 of lowering.

More preferably, step 210 is implemented only if the programmed value Ti of the current time slot is less than the programmed value T(i+1) of the following time slot.

Such a step 210 makes it possible to anticipate a possible return of users from room 12 during a change of time slot, for better comfort.

FIGS. 3 and 4 graphically represent, respectively, a first and a second embodiment of the method 202 described above, over a total period of 24 hours. Said embodiments are described below.

For each of Figures 3 and 4, reference A corresponds to the start of a period of absence in room 12, detected by detector 20; and reference B corresponds to the start of a period of presence in room 12, detected by said detector.

In the first mode of implementation of the , the module 18 stores an absence temperature Ta, less than or equal to each of the programmed values Ti of the successive time slots Pi. During steps 206 and 208 of method 202 described above, the target temperature Te is said absence temperature Ta.

In the example shown on the , the absence temperature Ta is several degrees lower than each of the programmed values Ti. For example, the lowest programmed value T4 is 15°C and the temperature Ta is equal to 12°C.

Such a mode of implementation allows optimization of energy savings in the event of prolonged absence in room 12 or in the building including said room.

According to a first variant, the absence temperature Ta is adjustable at the level of the module 18, by means of the interface. According to a second variant, the absence temperature Ta is adjustable at the level of the centralized management unit 100.

The second mode of does not implement the absence temperature Ta. If the programmed value Ti of the current time slot is greater than the programmed value T(i+1) of the following time slot, the target temperature Te of steps 206 and 208 is said programmed value T(i+1) of the next time slot. The setpoint temperature Tc is thus determined on the ranges P1 and P3 of the .

In addition, if the programmed value Ti of the current time slot is less than the programmed value T(i+1) of the next time slot and greater than the programmed value T(i-1) of the previous time slot, the target temperature Te of the lowering step is said programmed value T(i-1) of the previous time range. The setpoint temperature Tc is thus determined on the range P5 of the .

This mode of implementation allows optimization of the user's comfort in the event of a return to room 12 following a prolonged absence.

Preferably, the program 200 can be configured at the level of the module 18 to choose between the first and second implementation modes described above with reference to FIGS. 3 and 4. Alternatively, the choice between the first and second modes implementation can be configured at the level of the centralized management unit 100.

Preferably, the method 202 concerns only certain time slots P1-P6 of the program 200. On other time slots P0 and P7, for example considered as night slots, the presence detector 20 is not activated and the temperature setpoint Tc is locked on the programmed value corresponding to each of said ranges.

It is now considered that the installation 10 comprises several premises 12, 112, several heating devices 14, 114 described above and a centralized management unit 100, connected to each of the modules 18 of said devices 14, 114.

It is also considered that the unit 100 stores a building absence temperature Tab, preferably lower than each of the programmed values Ti of the programs 200.

According to one embodiment of the invention, if the detectors 20 of each of the devices 14, 114 simultaneously detect an absence in the corresponding room 12, 112 for a duration t4, the unit 100 implements a step E of regulation according to which the setpoint temperature Tc is lowered to the building absence temperature Tab at the level of all said devices 14, 114. Such a regulation step E makes it possible to optimize the energy savings at the level of the building.

Preferably, such a regulation step E ends as soon as a presence is detected in one of the premises 12, 112.

Preferably, the program 200 of each of the devices 14, 114 includes a function making it possible to neutralize the implementation of step E in one or the other of the premises 12, 112, at the user's choice.

Claims (10)

A method (202) of controlling an apparatus (14, 114) for heating a room (12, 112), said apparatus comprising: an electrical heating element (16); a control module (18) capable of controlling said heating element so as to adjust a room temperature to a set temperature (Tc); and a presence detector (20) in the room, connected to the control module;
the control module storing several successive time slots, each time slot (Pi) being associated with a programmed value (Ti) of the setpoint temperature, the programmed values of two successive time slots being distinct;
the method comprising the following steps:
- the setpoint temperature being equal to the programmed value (Ti) of a current time slot, activation of the presence detector (20); Then
- if the detector does not detect any presence in the room (12), lowering of the setpoint temperature to a target temperature (Te) lower than said programmed value, so that:
if a difference between the programmed value of the range and the target temperature is less than or equal to 1° C., then said lowering is carried out directly; And
if said difference is greater than 1°C, then the lowering is carried out in the form of at least two successive temperature decreases (ΔT), each decrease being less than or equal to half of said difference, two successive decreases being separated by a first non-zero duration (t2, 24). Method (202) of regulation according to claim 1, in which, during the step of lowering, each of the successive decreases (ΔT) in temperature is greater than or equal to 0.5°C. Regulation method according to Claim 1 or Claim 2, in which the first duration (t2, 24) between two successive temperature reductions is greater than or equal to 30 minutes. Regulation method (202) according to one of the preceding claims, in which, if the programmed value (Ti) of the current time slot is lower than the programmed value (T(i+1)) of the following time slot, the method then comprises a step (210) such that, over a second duration (t3) before the transition to the next time slot, the setpoint temperature is increased to said programmed value of the next time slot. Regulation method according to one of the preceding claims, in which the control module (18) stores an absence temperature (Ta), less than or equal to each of the programmed values of the successive time slots; and in that the target temperature (Te) of the lowering step is said absence temperature. Regulation method according to one of Claims 1 to 4, in which, if the programmed value (Ti) of the current time slot is greater than the programmed value (T(i+1)) of the following time slot, the target temperature (Te) of the lowering step is said programmed value of the following time range. Regulation method according to Claim 6, in which, if the programmed value (Ti) of the current time slot is lower than the programmed value of the following time slot and greater than the programmed value (T(i-1)) of the previous time slot, the target temperature (Te) of the lowering step is said programmed value of the previous time slot. Heating apparatus (14, 114) for heating a space, comprising: an electric heating element (16); a control module (18) capable of controlling said heating element so as to adjust a room temperature to a set temperature (Tc); and a presence detector (20) in the room, connected to the control module; said apparatus being provided with means (200) for implementing a method (202) according to one of the preceding claims. Heating installation (10) comprising a first room (12) and a first heating appliance (14) according to claim 8, installed in said first room. Installation according to claim 9, further comprising: a second room (112); a second heater (114) according to claim 8, installed in said second room; and a centralized management unit (100), connected to the first and second heaters.