FR2851404A1 - Heating device for e.g. personal heating application, has device for limiting current crossing heating cable and includes resistive unit that is chosen such that its resistance is negligible when cable has reached its stable mode - Google Patents

Abstract

The heating device has a heating cable (7) with a positive temperature coefficient (PTC) and a current limitation device for limiting a current crossing the PTC cable. The limitation device has a resistive unit (6) with a negative temperature coefficient (NTC) mounted in series with the heating cable (7). The NTC unit is chosen such that its resistance is negligible when PTC cable has reached its stable mode.

Description

The invention relates to the field of heating cables

Self-regulating.

  These self-regulating heating cables are generally used in individual home heating applications or in fluid line temperature maintenance applications (tracing).

  These cables consist of carrier conductors embedded in a positive temperature coefficient (PTC) semiconductor resin. The resistance of this semiconductor resin increases proportionally to the temperature of its environment.

  As a result, the heating capacity of the heating cable varies according to its temperature. This power decreases as the temperature of the cable increases to self-regulate to an equilibrium value. This type of cable thus has two essential properties: 1 / this cable is self-regulating: when the temperature of its environment varies, its resistance varies so as to produce thermal power and maintain it at an equilibrium temperature.

  2 / the temperature of this cable is self-limited: there is a temperature above which the heating power of the cable is zero.

  This property is of interest in the case of applications to electric radiant floors. Indeed, the highest temperature on the surface is always lower than the self-limiting temperature, and the risk of irreversible damage (degradation of the cable or the floor, burns, etc ..) are zero.

  A disadvantage, however, of these self-regulating heating cables is that they call for a high electrical power when they are energized. This power can indeed be of the order of 2 to 6 times the power consumed in steady state, depending on the environment 30 of the cable. As a result, the cable power supply installation is necessarily oversized with respect to the power to be supplied to the cable in steady state.

  This oversizing ensures operation of the heating system even when it is turned on (for example, in freezing conditions or at very low temperatures).

  In the context of applications of heating cables self-regulating heating or tracing, the management of the current in the cable can be provided by an unloader (cascado-cyclic start) to avoid excessive current calls.

  An object of the invention is to overcome these disadvantages.

  For this purpose, the invention proposes a heating device comprising a heating element with a positive temperature coefficient (PTC), characterized in that it furthermore comprises a device for limiting the current flowing through the heating element.

  In one embodiment of the invention, the current limiting device in the PTC heating element comprises a negative temperature coefficient (NTC) resistive element connected in series with the PTC element.

  In this implementation, the negative temperature coefficient element (NTC) is dimensioned so that: - either its resistance decreases with the current flowing through it, - or its resistance decreases when its temperature increases. In the latter case, the CTN element is thermally coupled with the CTP element so that the two elements are permanently at the same temperature.

  The negative temperature coefficient (NTC) element exhibits a behavior opposite to that of the CTP element: indeed, the resistance of the NTC element decreases as its temperature or the current flowing therethrough increases. Thus, when the CTP element is energized, the inrush current is limited by the element CTN.

  In addition, the CTN element is chosen so that, during the heating of the CTP element, the resistance of the CTN element decreases to become negligible with respect to the resistance of the CTP element.

  Therefore, the CTN element does not change the properties of the heater when it has reached its steady state.

  In another implementation of the invention, the current limiting device in the PTC heating element comprises a clipping element disposed in series with the PTC element and a switching element adapted to selectively direct current to the PTC element. the clipping element.

  This device makes it possible to reduce the amplitude of the current flowing through the CTP element when it is turned on. As soon as the temperature of the PTC element is sufficient, the switching element derives the current from the clipping element so as to stop clipping.

  The invention has the advantage of providing an autonomous device for managing the current in a PTC element, in particular in a self-regulating heating cable.

  Other features and advantages will become apparent from the description which follows, which is purely illustrative and not limiting and should be read with reference to the accompanying drawings in which: - Figure 1 shows schematically a heating device comprising a heating cable CTP and a current limiting device according to a first embodiment of the invention; FIG. 2 represents the variation of the resistances of the elements CTP and CTN of the device of FIG. 1 as a function of their temperature; FIG. represents the variation of the current in the CTP element of FIG. 1 as a function of time, - FIGS. 4 and 5 schematically represent heating devices comprising a current limiting device according to a second embodiment of the invention, FIG. 6 represents the variation of the current in the CTP element of the devices of FIGS. 4 and 5 as a function of time.

  In FIG. 1, the heating device represented comprises a thermal regulation module 3 connected to a probe 2 making it possible to measure the ambient temperature. This thermal regulation module 3 receives as input a temperature setpoint 1.

  The heating device further comprises a self-regulating heating cable 7 having a positive temperature coefficient (PTC), powered by an AC voltage generator 5.

  The heating device also comprises a relay 4 controlled by the thermal regulation module 3 and a device for limiting the current in the CTP cable 7. This current limiting device includes a resistive component with a negative temperature coefficient (CTN) 6 arranged in series and thermally coupled with the CTP cable 7.

  The CTN component is dimensioned so that its resistance varies according to its temperature. The resistance of the CTN component decreases as its temperature increases.

  The thermal regulation module 3 continuously compares the ambient temperature measured by the probe 2 with the set temperature 1.

  When the ambient temperature is greater than or equal to the set temperature 1, the thermal regulation module 3 controls the relay 4 to keep it in an open state. In this configuration, the CTN component 6 and the CTP cable 7 are not powered by the AC voltage generator 5.

  When the ambient temperature falls below the set temperature 1, the thermal regulation module 3 controls the closing of the relay 4. The CTN component 6 and the CTP cable 7 are then powered by the generator 5.

  When switching on the heating device, the thermal regulation module 3 controls the closing of the relay 4. The passage of the current in the CTP cable 7 causes the heating thereof by Joule effect. As the CTP cable 7 is thermally coupled to the CTN component 6, the latter sees its temperature increase. As the temperature increases, the resistance of the CTP cable 7 increases as the resistance of the CTN component decreases.

  Figure 2 shows the variations of the resistances of the CTN component and the CTP cable as a function of their temperature. This figure also shows the variation of the overall resistance of the CTN component and the associated CTP cable in series. It can be seen that this overall resistance is always greater than the resistance of the PTC cable alone.

  In particular, during a start-up phase of the heating device, the CTN component makes it possible to maintain the resultant resistance above a certain threshold.

  On the other hand, the CTN component has negligible resistance when the CTP cable has reached its steady state.

  Figure 3 shows the variation of the current in the PTC cable as a function of time during a start-up phase. Dashed lines in this figure show the variation of the current that would have been obtained if the heating device did not include the CTN component. It can be seen that the presence of the CTN component makes it possible to eliminate the peak current occurring at the start of the heating device.

  Such a current limiting device progressively limits the variation of current in the CTP cable 7.

  According to a variant of the device of FIG. 1, the component CTN is dimensioned so that its resistance varies as a function of the current which passes through it and no longer as a function of its temperature. Thus, the resistance of the CTN element decreases with the current flowing through it. In this variant, it is no longer necessary for the CTN component to be thermally coupled to the CTP cable.

  FIG. 4 represents a heating device according to another embodiment of the invention.

  Similarly to the device of FIG. 1, the heating device of FIG. 4 comprises a thermal regulation module 3 connected to a temperature sensor 2 and receiving a temperature setpoint 1. The thermal regulation module 3 controls the temperature control unit 3. opening and closing a relay 4 of the heating circuit. The heating circuit comprises a CTP heating cable 7 and an AC voltage generator 5 for supplying this cable. The heating device further comprises a device for limiting the current flowing through the CTP cable 7.

  The current limiting device comprises a diode 8 arranged in series with the CTP cable 7 and a relay 9 arranged in parallel with the diode 8. This relay 9 is controlled by a clock 10 connected to the thermal regulation module 3.

  The thermal regulation module 3 continuously compares the ambient temperature measured by the probe 2 with the set temperature 1.

  When the ambient temperature is greater than or equal to the set temperature 1, the thermal regulation module 3 controls the relay 4 to keep it in an open state. In this configuration, the CTP cable 7 is not powered by the AC voltage generator 5.

  When the ambient temperature falls below the set temperature 1, the thermal regulation module 3 controls the closing of the relay 4. The CTP cable 7 is then powered by the generator 5.

  When switching on the heating device, the thermal regulation module 3 commands the closing of the relay 4. The clock 10 2 0 detects the closing command of the relay 4 and triggers a timing.

  The AC voltage generator 5 supplies the CTP cable 7.

  However, since the diode 8 is only turned on when the current flows in a given direction in the heating circuit, the current supplied by the generator 5 is clipped. The diode 8 suppresses an alternation of the signal. As a result, the overall intensity flowing in the circuit is divided by a factor of 2.

  At the end of a preprogrammed delay time, the clock 10 commands the closing of the relay 9. The supply current of the CTP cable 7 7 is therefore branched towards the branch of the relay 9. As a result, the CTP cable 7 is powered by the entire AC current.

  Advantageously, the preprogrammed time delay can be modified at any time by a user or a technician intervening on the installation. For this purpose, the current limiting device comprises means for setting the delay time.

  FIG. 5 represents a variant of the device of FIG. 4 in which the delay time is determined by the thermal regulation module 3 as a function of the difference between the set temperature 1 and the ambient temperature measured by the probe 2.

  Figure 6 shows the variation of the current flowing through the CTP cable 107 as a function of time. Dashed lines in this figure show the current variation that would have been obtained if the heating circuit did not include the diode 8 and the relay 9. It is noted that the value of the current supplied to the CTP cable 7 during the delay phase T (when relay 9 is open) is divided by 2 with respect to the current that would be supplied if the circuit did not include a current limiting device.

Claims (11)

  Heating device comprising a heating element (7) with a positive temperature coefficient (PTC), characterized in that it further comprises a device for limiting the current flowing through the heating element (7).   2. Device according to claim 1, characterized in that the current limiting device passing through the PTC heating element (7) comprises a resistive element (6) negative temperature coefficient (NTC) 10 connected in series with the element. PTC heater (7).   3. Device according to claim 2, characterized in that the CTP element is thermally coupled with the CTP heating element (7).   4. Device according to one of claims 2 or 3, characterized in that the CTN resistive element (6) is selected so that its resistance is negligible when the CTP heating element (7) has reached its steady state.   5. Device according to claim 1, characterized in that the current limiting device passing through the PTC heating element (7) comprises a clipping element (8) arranged in series with the PTC element 20 and a switching element. (9) capable of selectively directing the current to the clipping element (8).   6. Device according to claim 5, characterized in that the current limiting device comprises timing means (10) able to detect the flow of current in the CTP heating element 25 (7) and at the end of a delay time (T) controlling the switching element (9) to derive the current to a branch parallel to the clipping element (8).   7. Device according to claim 6, characterized in that the delay time (T) is preprogrammed.   8. Device according to claim 7, characterized in that the delay time (T) is modifiable.   9. Device according to claim 6, characterized in that the delay time (T) is determined as a function of the difference between a set temperature (1) and a temperature measured by a temperature sensor (2).   10. Device according to one of claims 5 to 9, characterized in that the clipping element (8) is a diode.   11. Device according to one of the preceding claims, characterized in that it comprises a thermal control module (3) adapted to control a switching element (4) to allow or not 10 passage of the current in the element PTC heater (7) as a function of the difference between a set temperature (1) and a temperature measured by a temperature sensor (2).