DEVICE FOR COUNTING ELECTRIC ENERGY

专利摘要:
The present invention relates to a device for counting electrical energy intended to be associated with an electrical conductor for generating measurement data related to the electric current that passes through said electrical conductor. The device comprises in particular: a main storage unit (30) of electrical energy arranged to store a quantity of electrical energy; a secondary storage unit (31) of electrical energy connected to said main storage unit (30), Switching means (S2) controlled by the processing unit for triggering a transfer of power from said main storage unit (30) to said secondary storage unit (31) and to trigger a power supply of a data transmitter (40) wirelessly when a voltage threshold across the secondary storage unit (31) is exceeded to output a message containing data representative of the electric current flowing in said electrical conductor.
公开号:FR3052868A1
申请号:FR1655734
申请日:2016-06-20
公开日:2017-12-22
发明作者:Vianney Poiron
申请人:Gulplug；
IPC主号:

专利说明:

Electrical energy metering device
Technical Field of the Invention
The present invention relates to an electrical energy counting device intended to be associated with an electrical conductor for generating measurement data related to the electric current that passes through said electrical conductor and send them, for example, to a remote central station through a terminal. wireless communication network. The device of the invention has the advantage of being autonomous in electrical energy by feeding inductively due to the electric current flowing in the electrical conductor.
State of the art
Electrical energy management solutions to improve the energy efficiency of an infrastructure are increasingly present and require the determination of the electrical energy consumed by each infrastructure equipment. For this purpose, different types of devices are used which are conveniently placed at different points of the infrastructure in order to measure the electric currents and possibly to determine other parameters. The different measurement data are sent to a remote central station through a wireless communication network. Some known devices can collect and determine accurate information. However, it was found that in most applications the accuracy of the information was not decisive and that a simple estimate of the electrical energy consumed was already of interest, paving the way for the development of simple and therefore inexpensive. These devices are thus simple devices for counting electrical energy.
The patent application EP2354799A1 describes such an electrical energy metering device which comprises:
A current sensor arranged to supply a secondary current from a primary electric current flowing in an electrical conductor. An electrical energy storage unit connected to said current sensor and arranged to store a quantity of electrical energy from the secondary electric current.
A voltage threshold detection unit connected to said main electrical energy storage unit and arranged to detect an exceeding of a voltage threshold at the terminals of the electrical energy storage unit,
A processing unit connected to said electrical energy storage unit,
A wireless data transmitter coupled to said processing unit for sending a message containing data representative of the electric current flowing in said electrical conductor.
Switching means controlled by the voltage threshold detection unit for triggering a power supply of the processing unit and said transmitter when said voltage threshold at the terminals of the main electrical energy storage unit is exceeded for transmit a message containing data representative of the electric current flowing in said electrical conductor.
The latter device has the advantage of being simple operation, non-intrusive and require only a small amount of electrical energy to operate. Other wireless power metering devices that are self-sufficient in electrical energy are also known from WO2008 / 142425 or WO2010 / 119332.
The devices described in these documents are suitable for sending messages to central stations present locally and do not allow message transmission to more distant stations, for example through a long distance and low-speed communication network of the type. LPWAN (for "Low Power Wide Area Network") and based on a protocol such as LoRaWAN ("for Long Range Wide Area Network") or that developed by SigFox or Qowisio.
The aim of the invention is to propose an electrical energy metering device that can transmit messages over low-speed and long-range cellular networks such as those defined above, while allowing a simple counting solution to be maintained. electrical energy.
Presentation of the invention
This object is achieved by a wireless electric energy metering device comprising: a current sensor arranged to supply a secondary current from a primary electrical current flowing in an electrical conductor; a main storage unit; electrical energy connected to said current sensor and arranged to store a quantity of electrical energy from the secondary electric current; - a voltage threshold detection unit connected to said main electrical energy storage unit and arranged to detect a exceeding a voltage threshold at the terminals of the main electrical energy storage unit; a processing unit connected to said main storage unit; first switching means controlled by the threshold detection unit; voltage to trigger a power supply of the processing unit when said threshold voltage across one main electrical energy storage is exceeded, - a first wireless data transmitter coupled to said processing unit and for sending a message containing data representative of the electric current flowing in said electrical conductor, - a unit of secondary storage of electrical energy connected to said main storage unit; second switching means controlled by the processing unit for triggering a transfer of energy from said main storage unit to said secondary storage unit and to trigger a supplying said first wireless data transmitter when a voltage threshold at the terminals of the secondary storage unit is exceeded for transmitting a message containing data representative of the electric current flowing in said electrical conductor.
According to one feature, the processing unit comprises a microprocessor and a non-volatile memory and in that the microprocessor is arranged to increment an energy meter at the end of each charge cycle of the main storage unit.
According to a particular embodiment, the device comprises a second wireless data transmitter coupled to said processing unit and the microprocessor is arranged to control the transmission of a message using the second transmitter at the end of a charge cycle of the main storage unit.
Advantageously, this second transmitter is arranged to operate on a short-range network.
Advantageously, the first transmitter is arranged to operate on a long-range network.
According to the invention, the transmission of a message over a long-range network requires a large amount of energy and it is necessary to maintain a simple and reliable solution for counting the electrical energy consumed. The main storage unit is insufficient to provide the energy required to issue a message on the long-range network however it remains necessary to perform a simple count of the electrical energy consumed. Since the device of the invention must remain autonomous in electrical energy, that is to say do not use an electric battery or other energy source of this type, it was necessary to find a solution which makes it possible to store enough energy. energy for the transmission of the message on the long-range network. The solution of the invention thus consists in storing progressively the energy necessary for the transmission of the message in a secondary storage unit from the energy accumulated at each cycle in the main storage unit. The invention thus makes it possible to maintain a simple solution for counting electrical energy using the main storage unit, while enabling the transmission of a message over a long-range network and keeping a device entirely intact. autonomous.
Preferably, the device of the invention comprises a discharge unit connected to the main storage unit and controlled by the processing unit for discharging the main storage unit (30).
Advantageously, the processing unit is arranged to determine a datum representative of a duration.
Advantageously, the data representative of a duration corresponds to a counter of the number of charge cycles of the main storage unit.
According to an alternative embodiment, the device comprises a clock which makes it possible to determine the datum representative of a duration.
Preferably, the secondary storage unit comprises at least one supercapacitor.
According to another feature, the device comprises a rectifier circuit connected to the current sensor and intended to rectify the secondary current generated by the current sensor.
Advantageously, the device comprises a near-field communication circuit connected to a memory of the processing unit. The invention also relates to a method of counting electrical energy implemented using the device as defined above, the method comprising steps of: - Loading the main storage unit to store a quantity of electrical energy from the secondary electric current, - Transfer of electrical energy from the main storage unit to the secondary storage unit when the voltage across the main storage unit reaches a determined threshold.
Transmitting a message using the first transmitter when a data representative of a duration has reached a threshold value and when the voltage at the terminals of the secondary storage unit has exceeded a determined threshold.
According to one particularity, the data representative of a duration corresponds to a counter of the number of charge cycles of the main storage unit.
According to a particular embodiment, the data representative of a duration corresponds to an elapsed time determined using a clock.
Preferably, the method comprises a step of discharging the main storage unit implemented after the energy transfer step of the main storage unit to the secondary storage unit or transmission of a message .
BRIEF DESCRIPTION OF THE FIGURES Other characteristics and advantages will appear in the detailed description which follows, given with reference to the appended drawings, in which: FIG. 1 is a schematic representation of a first embodiment of the electrical energy metering device of FIG. the invention. FIG. 2 represents the functional block diagram of the electrical energy metering device of FIG. 1.
FIGS. 3A and 3B show two time diagrams illustrating the operating principle of the electric energy metering device of FIG. 1.
Figure 4 schematically shows a second embodiment of the electrical energy metering device of the invention.
FIG. 5 represents the functional block diagram of the electric energy metering device of FIG. 4.
FIG. 6 schematically represents an improvement of the electric energy metering device shown in FIG. 4.
FIG. 7 represents the functional block diagram of the electrical energy metering device of FIG. 6.
FIG. 8 represents an alternative embodiment of the electrical energy metering device represented in FIG. 6.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT The invention relates to a device for counting electrical energy operating through a wireless communication network in order to enable the transmission of messages, for example to a station power plant for the electrical energy management of an electrical network ("Smart Grid" or "Smart City" type). Preferably, the communication network will be a LPWAN long-distance and low-speed communication network (for "Low Power Wide Area Network") and based on a protocol such as LoRaWAN ("for Long Range Wide Area Network"). or the one developed by SigFox or Qowisio.
The electrical energy metering device of the invention is, for example, in the form of a casing coming to be clambered / positioned on an electrical conductor 20 and making it possible to determine measurement data related to the alternating electric current circulating in the conductor. electric. Preferably, the device of the invention allows a count of the electrical energy consumed by the equipment which is powered by the electric current flowing in the electrical conductor 20. It sends the electric energy meter (index d energy) and other data such as CO, CO2, temperature, acceleration, pressure ...
In the presence of an RTC type clock as proposed in one of the embodiments described below, the device is able to send other data representative of the measured electric current, in particular:
The rms value of the average current flowing in the electrical conductor 20;
The rms value of the minimum current flowing in the electrical conductor 20 over a given measurement time;
The rms value of the maximum current flowing in the electrical conductor over a given measurement time; - The presence of a current fault (overcurrent followed by a zero crossing of the electrical current);
In the following description, the device will be described for the counting of electrical energy that corresponds to the electric current flowing in the monitored electrical conductor.
In general, the device of the invention operates according to the following main principles:
The device of the invention is for example positioned on an electrical conductor 20 for supplying electrical equipment in which a current Ip flows.
The device of the invention is self-powered by an induced current Is derived from the electric current Ip which flows in the electrical conductor 20.
The device comprises a main storage unit 30 of electrical energy which is powered by said induced current and which supplies a CPU processing unit when it has enough electrical energy.
The device comprises a secondary storage unit 31 of electrical energy powered by the main storage unit 30, by sending a command by the processing unit UC.
The device comprises a transmitter 40 fed by the secondary storage unit 31 for transmitting a message on said communication network mentioned above when the secondary storage unit 31 has enough electrical energy.
With reference to FIG. 1, according to a first embodiment, the electrical energy metering device of the invention comprises a current sensor 21 which supplies a secondary current Is representative of the current Ip which flows in the electrical conductor 20. This current sensor 21 thus more precisely comprises a core in the form of a torus 200 intended to be traversed by the electrical conductor 20 whose current is to be measured. A winding 210 is formed around said torus 200. The torus is preferably open, which allows it to be positioned around the electrical conductor 20. When the current sensor 21 is in position on the electrical conductor 20, the electrical conductor 20 forms then the primary of a current transformer and the winding 210 forms the secondary of said current transformer. Thanks to this architecture, the current Is flowing in the secondary of the current transformer is the image of the current Ip flowing in the primary of the transformer.
The device of the invention also comprises an electronic circuit enclosed in its housing and connected directly to the two son of the winding 210 of the secondary described above.
The electronic circuit preferably comprises a rectifier 22 intended to rectify the secondary electric current Is. The rectifier 22 will for example consist of a diode or bridge of diodes connected to a first terminal of the secondary winding 210 of the transformer. It may also consist of a diode bridge connected between the two terminals of the secondary winding 210 of the transformer.
The electronic circuit comprises a main storage unit 30 of the electrical energy, connected to the rectifier 22 and to a second terminal of the secondary winding of the current transformer. This unit comprises at least one capacitor MC having a determined capacity.
The electronic circuit also comprises a detection unit 32 with a voltage threshold connected in parallel with said capacitor and intended to detect a voltage overshoot, designated MC_V, across the terminals of the capacitor MC beyond a determined threshold value, designated MC_V_TH.
The electronic circuit comprises first switching means Ty controlled by the detection unit 32 when the voltage threshold value MC_V_TH across said capacitor MC is exceeded. These first switching means Ty comprise, for example, a thyristor whose gate is connected to the output of the detection unit 32.
The electronic circuit comprises a secondary storage unit 31 of electrical energy, connected to the main storage unit 30, more precisely to the junction point X between the rectifier 22 and the main storage unit 30, and to a reference of voltage, for example the mass. The secondary storage unit 31 advantageously comprises a supercapacitor SC, for example of double layer type (EDLC for "Electric Double Layer Capacitor") but, alternatively or in addition, it may comprise a battery.
The electronic circuit comprises a measurement unit 34 of the voltage, designated SC_V, at the terminals of the secondary storage unit 31.
The electronic circuit comprises a processing unit UC, comprising at least one microprocessor and a non-volatile memory, connected in parallel with the main storage unit 30 when the first switching means Ty are closed in order to receive a power supply from this one. this. The CPU processing unit has an input on which is applied the voltage measured at the terminals of the secondary storage unit 31 by said measurement unit 34 of the voltage. With each load of the capacitor MC of the main storage unit 30, the microprocessor increments an energy meter by a defined amount (hereinafter referred to as "energy memory") and thereby stores an energy index (referred to as "energyjndex"). ) which corresponds to the cumulative amount of electrical energy consumed. The non-volatile memory of the processing unit UC is advantageously of the FRAM type.
The electronic circuit comprises second switching means S2 controlled by the processing unit UC for a transfer of energy from the main storage unit 30 to the secondary storage unit 31. These second switching means S2 are, for example connected firstly to the main storage unit 30, at the junction point X with the rectifier 22, and secondly to the secondary storage unit 31. This will be for example a switch type MOS transistor whose gate is connected to an output of the processing unit.
The electronic circuit comprises a wireless data transmitter 40 connected in parallel with the main storage unit 30 when the first switching means Ty are closed in order to be powered by it. The transmitter 40 is controlled by the processing unit UC for sending the message on the wireless communication network as mentioned above. The emission of a message takes place when a sufficient quantity of energy is available in the secondary storage unit 31.
The electronic circuit also includes a discharge unit 36 of the main storage unit connected in parallel with the main storage unit. This discharge unit comprises an assembly formed of at least one switch SI and a dissipation resistor RI connected in series. The switch is for example a transistor whose base is connected to an output of the microprocessor of the processing unit UC.
Advantageously, the electronic circuit also comprises a near-field communication circuit, for example of the NFC (Near Field Communication) or equivalent type, comprising an NFC chip 50 having a memory and a microprocessor and an NFC antenna. 51 allowing it to be powered from the outside, for example by a mobile terminal equipped with NFC technology and a suitable control application. Via the link in the near field, the mobile terminal will thus be able to directly feed the NFC chip and the processing unit UC, as well as its internal non-volatile memory, in order to copy data, in particular the energy meter to stored in the memory of the processing unit to the memory of the NFC chip. Via the NFC link it will also be possible to set the device of the invention, for example to set the different threshold values which will be described below.
FIG. 2 illustrates the operation of the device represented in FIG. 1. This operation is as follows: At the first power-up (INIT), the microprocessor of the processing unit UC initialises at zero two counters: a counter of Energy called energyjndex, which is the amount of total energy consumed by the equipment supplied through the electrical conductor 20.
A counter designated Mn which corresponds to a charge cycle counter of the capacitor of the main storage unit. The main storage unit 30 is charged by the secondary current induced on the secondary winding of the current sensor 21 and rectified by the rectifier 22 (step EO). - When the voltage across the main storage unit 30 reaches the voltage threshold MC_V_TH defined by the voltage-threshold detection unit 32, it controls the first switching means Ty on closing, causing the power supply of the CPU processing unit (step E1).
The microprocessor increments the energy counter by a determined increment (labeled energyjncrement) so that energyjndex = energy_index-i-energyjncrement - (step E2).
The microprocessor of the processor unit UC increments the counter Mn by one so that Mn = Mn-i-1 (step E2).
The microprocessor also controls the closing of the second switching means S2 to allow energy transfer from the main storage unit 30 to the secondary storage unit 31 (step E4). The conduction duration of the second switching means S2 is small compared to the charging time of the capacitor MC of the main storage unit 30. Once the conduction duration has been completed, the microprocessor controls the opening of the second switching means S2. .
The microprocessor tests the value of the counter Mn with respect to a stored threshold value, designated MnMax (step E5). - If the counter Mn has not reached the value of MnMax, the microprocessor ends the cycle by controlling the discharge of the capacitor MC of the main storage unit 30 by closing the switch S1 of the discharge unit 36 ( step E10). The microprocessor can then start a new cycle by charging the capacitor MC of the main storage unit 30 (step E0). If the counter Mn = Mn Max, this means that a certain duration has elapsed and it is time to send a message. The microprocessor then performs a test to know if the available electric energy in the secondary storage unit 31 is sufficient for the transmission of a message (step E6). If the voltage SC_V at the terminals of the secondary storage unit 31 is less than a stored threshold value, designated SC_V_TH, then the microprocessor can not control the transmission of a message. It decrements the counter Mn by one so that Mn = Mn-1 (step E7).
The microprocessor terminates the cycle by controlling the discharge of the capacitor MC from the main storage unit 30 by closing the switch S1 of the discharge unit 36 (step E10). The microprocessor can then begin a new cycle by charging the capacitor of the main storage unit (step EO). If the voltage SC_V at the terminals of the secondary storage unit 31 is greater than the stored threshold value SC_V_TH, the microprocessor resets the counter Mn to zero (step E8) and commands the transmission of a message (step E9). For this, the microprocessor: - Controls the closing of the second switching means S2 for supplying the transmitter 40 with the electric energy available in the secondary storage unit 31. - Generates the message to be sent which includes data representative of the energyjndex stored energy counter. The message comprises, for example, a preamble, a synchronization data, an identifier of the transmitting device or of the source, data representative of said energy meter and an end of transmission or control data. Patent application EP2354799A1 gives the example of an energy message structure that could be generated and transmitted. - Command the transmitter 40 for the transmission of the generated message.
Once the message is sent, the microprocessor completes the cycle by controlling the discharge of the capacitor MC of the main storage unit 30 by closing the switch S1 of the discharge unit 36 (step E10). The microprocessor can then begin a new cycle by charging the capacitor MC of the main storage unit 30 (step EO). - At any time, if a mobile terminal is approached from the device and supplies the NFC chip 50, the updated energy meter available in the non-volatile memory can be copied into the memory of the NFC chip to be read by the mobile terminal (step E3).
For example, we will have the following operating data:
Ip = 10A
Number of turns of the secondary winding: 3000 Capacitor capacity MC = 940 μΡ (tantalum capacitor)
Supercapacitor capacitance SC = 100 mP (capacitor type EDLC) Duration of a capacitor charge cycle MC = 1s T (Conduction time of S2) = 2 ms MnMax = 7200 (~ 2 hours)
MC_V_TH = 2.9V SC_V_TH = 2.8V
According to the invention, each long cycle at which the transmitter 40 sends a message is therefore composed of MnMax short cycles. This number MnMax is for example set in the device via the NPC link described above. It must be set according to the current Ip that powers the equipment.
FIGS. 3A and 3B illustrate the operation of the device of the invention such as that described above in connection with FIGS. 1 and 2.
In FIG. 3A, it is well understood that the capacitor MC of the main storage unit 30 is charged by the rectified current coming from the secondary of the transformer, making it possible to supply the electronics, in particular the processing unit UC. At the end of each charging / discharging cycle of the capacitor MC of the main storage unit 30, part of the accumulated energy is transferred to the secondary storage unit 31 and the voltage across the unit of the storage unit 30. secondary storage 31 increases gradually. When this voltage across the secondary storage unit becomes sufficient, that is to say greater than the stored value SC_V_TPI, a message is sent at time T MSG1. The energy accumulated in the secondary storage unit 31 is then used for transmitting the message (from T MSG1 to T_MSG2).
In FIG. 3B, it will be noted that when the main storage unit 30 is loaded (from T1 to T3 and from T5 to T7), the first switching means Ty are in the state 1 causing the power supply of the electronic, and in particular of the CPU processing unit. The microprocessor of the processing unit UC is thus able to control the second switching means S2 so as to allow a transfer of energy from the main storage unit to the secondary storage unit (T2 to T3 and from T6 to T7). The voltage at the terminals of the secondary storage unit 31 therefore increases when the second switching means are closed. Once the energy transfer has been effected, the microprocessor controls the switch S1 to discharge the capacitor MC from the main storage unit 30 (from T3 to T4). When the voltage at the terminals of the secondary storage unit 31 becomes sufficient (from T7), the microprocessor generates the message to be sent (from T7 to T8), controls the second switching means S2 in the closed state to discharge the secondary storage unit 31 (from T8 to T9), thus making it possible to maintain a voltage greater than the detection threshold at the terminals of the main storage unit 30 and thus to keep the first switching means Ty in the closed state to supply the transmitter and the CPU for transmitting the message (from T8 to T9). Then, the microprocessor controls the opening of the switch S2, then the closing of the switch S1 to discharge the capacitor MC of the main storage unit 30 (T9 TOO).
FIG. 4 represents a second embodiment of the electrical energy metering device of the invention. In this second embodiment, in addition to the first transmitter 40 dedicated to communication over a long-range network, the device comprises a second transmitter 60 capable of transmitting data over a short-range wireless communication network. This will for example be a radiofrequency type communication network operating under a low consumption protocol of "Zigbee Greenpower" type. The other components remain unchanged.
In this second embodiment, starting from the topology described above in connection with FIG. 1, the second transmitter 60 is connected in parallel with the first transmitter 40. This topology makes it possible to take advantage of the two charging cycles of the two storage units 30, 31 for transmitting information over a long-range network and / or a short-range network. The short cycle is managed by the electrical energy stored in the main storage unit 30 while the long cycle, as described for the first embodiment, is managed by the electrical energy stored in the storage unit. secondary 31. This dual emission solution allows to multiply the uses of the device of the invention. Depending on its location and needs, the device can operate in short-range mode, long-range mode or short and long range combined mode. In the combined mode, it will for example be to trace energy data on the short-range network in real time and energy data and alarms on the long-range network. These alarms may be for example levels of average current out of template.
Figure 5 provides a better understanding of the operation of the device having a two-emitter topology as described above. Compared to the operating block diagram already described above, a step of emitting the energy counter "energyjndex" by the second transmitter 60 is controlled by the microprocessor when the electronics are powered by the main storage unit 30 ( step E15). The rest of the operation remains unchanged.
Figure 6 shows an improvement to the device shown in Figure 4 and described above. In this new topology, the device includes a clock (RTC for "Real Time Clock") to better regulate the sending of messages. This clock is connected to the microprocessor and is accessible for reading and writing by the microprocessor when it is powered. In this embodiment, the clock is powered by a power source such as an electric battery. In the solutions described above, the transmission of messages was controlled by following the criterion of the number of a charge cycle of the capacitor using the counter Mn. Thanks to a clock, the transmission of messages is clocked according to a time criterion. The use of a clock is particularly interesting when the two transmitters 40, 60 are present but it could be used when only the first transmitter of long-range type is present. The use of a clock is described below for a two-emitter topology as described above in connection with FIG. 4.
In this clock embodiment, the operating principle is described below with reference to FIG. 7. At the first power-up (INIT2), the microprocessor initializes the energy counter to zero so that energy_index = 0 - At the first power up, the microprocessor initializes a variable named "send_LR" to the value "False". The main storage unit 30 is charged by the secondary current induced on the secondary winding of the current sensor (step E20).
When the voltage MC_V across the terminals of the main storage unit 30 reaches the voltage threshold MC_V_TH defined by the voltage-threshold detection unit 32, the latter controls the first switching means Ty on closing, causing the supplying power to the CPU processing unit and the second transmitter (step E21).
The microprocessor increments the energy counter by a determined increment (named energyjncrement) so that energy_index = energy_index-i-energy_increment - step E22
The microprocessor generates a message to be sent which includes data representative of the energyjndex stored energy counter. As described above, the message comprises for example a preamble, a synchronization data, an identifier of the transmitting device or the source, data representative of said energy meter and an end of transmission or control data.
The microprocessor controls the second short-range transmitter 60 for transmitting the generated message (step E24).
The microprocessor then consults the RTC clock. If the RTC clock indicates a duration less than a memorized limit duration designated T1 (for example equal to 2 hours), the microprocessor does nothing. If the RTC clock indicates a duration greater than or equal to the stored time limit T1, the microprocessor assigns the value TRUE to the send_LR variable (step E25).
The microprocessor then controls the closing of the second switching means S2 to allow energy transfer from the main storage unit 30 to the secondary storage unit 31 (step E26). The conduction duration of the second switching means S2 is small compared to the charging time of the capacitor of the main storage unit. Once the conduction time has been completed, the microprocessor controls the opening of the second switching means S2.
The microprocessor tests the value of the send_LR variable (step E27). If the variable send_LR is not equal to the value TRUE, then the microprocessor ends the cycle by controlling the discharge of the capacitor of the main storage unit by closing the switch SI of the discharge unit 36 (step E31). The microprocessor can then start a new cycle by charging the capacitor MC of the main storage unit 31. - If the variable send_LR is equal to the value TRUE, it means that a certain duration has elapsed and that is time to send a message. The microprocessor then performs a test to know if the available electric energy in the secondary storage unit 31 is sufficient for the transmission of a message (step E28). - If the voltage at the terminals of the secondary storage unit 31 is less than a stored threshold value, designated SC_V_TH, then the microprocessor can not control the transmission of a message. The microprocessor terminates the cycle by controlling the discharge of the capacitor from the main storage unit 30 by closing the discharge unit switch (step E31). The microprocessor can then begin a new cycle by charging the capacitor MC of the main storage unit 30. In this situation, the send_LR variable thus remains at the value TRUE at the start of the next cycle. If the voltage SC_V at the terminals of the secondary storage unit 31 is greater than the stored threshold value SC_V_TH, the microprocessor then assigns the FALSE value to the send_LR variable (step E29) and commands the transmission of a message (step E30). For this, the microprocessor: - Controls the closing of the second switching means S2 for supplying the transmitter 40 with the electric energy available in the secondary storage unit 31. - Generates the message to be sent which includes data representative of the energyjndex stored energy counter. The message comprises, for example, a preamble, a synchronization data, an identifier of the transmitting device or of the source, data representative of said energy meter and an end of transmission or control data. - Command the transmitter 40 for the transmission of the generated message. - At any time, if a mobile terminal is approached from the device and supplies the NFC chip 50, the up-to-date energy meter available in the non-volatile memory of the processing unit UC can be copied into the memory of the NFC chip to be read by the mobile terminal (step E23).
For example, we will have the following operating data: lp = 10A
Number of turns of the secondary winding: 3000 MC = 940 pF (tantalum capacitor) SC = 100 mF (EDLC type capacitor)
Duration of a capacitor charge cycle MC = 1s T (conduction time of S2) = 2 ms
Time Tl of the clock RTC = 7200s (~ 2 hours)
MC_V_TH = 2.9V SC_V_TH = 2.8V
FIG. 8 represents an alternative embodiment of the device of FIG. 6, in which the clock RTC is no longer powered by a battery but by the secondary storage unit 31, rendering the device completely autonomous in energy.
In this solution, the clock RTC is connected in parallel with the secondary storage unit 31. As before, it is accessible for reading and writing by the microprocessor. As the secondary storage unit 31 discharges slowly, it can maintain a voltage across the clock to supply it.
As long as the secondary storage unit 31 has not been completely emptied, the operation of the device in this particular embodiment is identical to that described above with a clock powered by a battery. On the other hand, if the device has not been active for some time and the secondary storage unit 31 is empty, during power-up, the microprocessor initializes the clock. The time indicated by the clock will then be considered as the initial time from which the stored time T1 will be calculated to determine the time of sending a new message on the long-range network.
The solution of the invention thus has many advantages, among which: the solution is simple to implement and reliable. It thus makes it possible to manage the transmission of an energy message over a long-range network. - The solution is autonomous in that it does not require the use of a power source such as an electric battery. - The transmission of an energy message over a long-range network does not require the use of a local station to centralize the messages.
It makes it possible to manage both the transmission of a message on a short-range network and / or on a long-range network.
It does not necessarily require the use of a clock type RTC.
It makes it possible to directly send an energy accumulation message comprising the last calculated energy index. Thus, even in the event of communication failure, the receiver always receives an updated index. - Thanks to the NFC link, It allows direct access, at any time, to the updated energy index and a setting of the device.
It also allows access to other potentially available physical quantities by sensors connected to the CPU unit, for example, temperature, humidity, CO, CO2, pressure, acceleration, etc.

权利要求:
Claims (16)
[1" id="c-fr-0001]
A wireless electrical energy metering device comprising: a current sensor (21) arranged to supply a secondary current (Is) from a primary electric current (Ip) flowing in an electrical conductor; primary storage (30) of electrical energy connected to said current sensor and arranged to store a quantity of electrical energy from the secondary electric current; a voltage threshold detection unit (32) connected to said storage unit; main electrical power and arranged to detect an exceeding of a voltage threshold at the terminals of the main electrical energy storage unit. A processing unit (CPU) connected to said main storage unit (30), first switching means (Ty) controlled by the voltage threshold detection unit (32) for triggering a power supply of the storage unit processing when said voltage threshold at the terminals of the main electrical energy storage unit is exceeded, - a first wireless data transmitter (40) coupled to said processing unit and making it possible to send a message containing data representative of the electric current flowing in said electrical conductor, - characterized in that it comprises: - a secondary storage unit (31) of electrical energy connected to said main storage unit (30), - second switching means ( S2) controlled by the processing unit for triggering a transfer of energy from said main storage unit (30) to said secondary storage unit (31) and for triggering a power supply of said first wireless data transmitter (40) when a voltage threshold across the secondary storage unit (31) is exceeded for transmitting a message containing data representative of the electric current flowing in said electrical conductor.
[2" id="c-fr-0002]
2. Device according to claim 1, characterized in that the processing unit comprises a microprocessor and a non-volatile memory and in that the microprocessor is arranged to increment an energy meter at the end of each charge cycle. of the main storage unit (30).
[3" id="c-fr-0003]
3. Device according to claim 2, characterized in that it comprises a second transmitter (60) of wireless data coupled to said processing unit (UC) and in that the microprocessor is arranged to control the transmission of a message using the second transmitter at the end of a charge cycle of the main storage unit (30).
[4" id="c-fr-0004]
4. Device according to claim 3, characterized in that the second transmitter (60) is arranged to operate on a short-range network.
[5" id="c-fr-0005]
5. Device according to one of claims 1 to 4, characterized in that the first transmitter is arranged to operate on a long-range network.
[6" id="c-fr-0006]
6. Device according to one of claims 1 to 5, characterized in that it comprises a discharge unit connected to the main storage unit and controlled by the processing unit to unload the main storage unit (30). ).
[7" id="c-fr-0007]
7. Device according to one of claims 1 to 6, characterized in that the processing unit (UC) is arranged to determine a data representative of a duration.
[8" id="c-fr-0008]
8. Device according to claim 7, characterized in that the data representative of a duration corresponds to a counter of the number of charge cycles of the main storage unit (30).
[9" id="c-fr-0009]
9. Device according to claim 7, characterized in that it comprises a clock which determines the data representative of a duration.
[10" id="c-fr-0010]
10. Device according to one of claims 1 to 9, characterized in that the secondary storage unit comprises at least one super-capacitor.
[11" id="c-fr-0011]
11. Device according to one of claims 1 to 10, characterized in that it comprises a rectifier circuit (22) connected to the current sensor (21) and for rectifying the secondary current generated by the current sensor (21). .
[12" id="c-fr-0012]
12. Device according to one of claims 1 to 11, characterized in that it comprises a near-field communication circuit (50, 51) connected to a memory of the processing unit (UC).
[13" id="c-fr-0013]
13. A method of counting electrical energy implemented using the device as defined in one of claims 1 to 12, characterized in that it comprises steps of: - Charge the storage unit main device (30) for storing a quantity of electrical energy from the secondary electric current, - transferring electrical energy from the main storage unit (30) to the secondary storage unit (31) when the voltage at the terminals of the main storage unit (30) reaches a determined threshold (MC_V_TH), Transmission of a message using the first transmitter (40) when data representative of a duration has reached a threshold value and when the voltage across the secondary storage unit (31) has exceeded a determined threshold (SC_V_TH).
[14" id="c-fr-0014]
14. The method of claim 13, characterized in that the data representative of a duration corresponds to a counter of the number of charge cycles of the main storage unit (30).
[15" id="c-fr-0015]
15. The method of claim 13, characterized in that the data representative of a duration corresponds to an elapsed time determined using a clock.
[16" id="c-fr-0016]
16. Method according to one of claims 13 to 15, characterized in that it comprises a step of discharging the main storage unit (30) implemented after the energy transfer step of the unit main storage (30) to the secondary storage unit or transmission of a message.

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同族专利:

---

公开号 | 公开日

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EP3472631A1|2019-04-24|

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WO2017220887A1|2017-12-28|

---

JP2019527341A|2019-09-26|

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CN109477859B|2022-02-18|

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BR112018076248A2|2019-03-26|

---

KR20190019169A|2019-02-26|

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FR3052868B1|2021-01-01|

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CN109477859A|2019-03-15|

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JP6965286B2|2021-11-10|

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US20190324071A1|2019-10-24|

引用文献:

---

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

---

US20100264906A1|2009-04-16|2010-10-21|Panoramic Power Ltd.|Apparatus and Methods Thereof for Power Consumption Measurement at Circuit Breaker Points|

---

EP2354799A1|2010-02-08|2011-08-10|Schneider Electric Industries SAS|Device and method for metering electric energy|

---

GB0709893D0|2007-05-23|2007-07-04|Onzo Ltd|Apparatus for monitoring rescue consumption|

---

CN101221229A|2008-01-29|2008-07-16|郑州万特电气有限公司|Method for testing synthetic measuring error of high tension electric energy metering installation|

---

CN101901367A|2010-07-29|2010-12-01|苏州盖娅智能科技有限公司|Dual-power active RFID tag and control and implementation method thereof|

---

CN103278791B|2013-05-10|2015-09-02|国家电网公司|The electronic mutual inductor amplitude phase error check system that Networkable detects|

---

CN203259592U|2013-05-20|2013-10-30|深圳市芯海科技有限公司|Electric energy metering device and electric energy metering chip thereof|CN108279395A|2018-01-30|2018-07-13|成都开谱电子科技有限公司|A kind of high accuracy capacitance decade box|

---

CN108132451A|2018-01-30|2018-06-08|成都开谱电子科技有限公司|A kind of wide-range standard capacitance box|

---

US10935579B2|2018-06-18|2021-03-02|Atlas Copco Airpower, Naamloze Vennootschap|Current sensor|

法律状态:
2017-06-26| PLFP| Fee payment|Year of fee payment: 2 |

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2017-12-22| PLSC| Publication of the preliminary search report|Effective date: 20171222 |

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2018-06-22| PLFP| Fee payment|Year of fee payment: 3 |

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2020-07-01| PLFP| Fee payment|Year of fee payment: 5 |

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2021-06-30| PLFP| Fee payment|Year of fee payment: 6 |

优先权:

---

申请号 | 申请日 | 专利标题

---

FR1655734A|FR3052868B1|2016-06-20|2016-06-20|ELECTRICAL ENERGY METERING DEVICE|FR1655734A| FR3052868B1|2016-06-20|2016-06-20|ELECTRICAL ENERGY METERING DEVICE|

---

KR1020197001530A| KR20190019169A|2016-06-20|2017-06-14|Electric energy meter|

---

CN201780036955.4A| CN109477859B|2016-06-20|2017-06-14|Electric energy metering equipment|

---

EP17740050.4A| EP3472631A1|2016-06-20|2017-06-14|Electricity metering device|

---

JP2018566363A| JP6965286B2|2016-06-20|2017-06-14|Wireless electrical energy measuring device and electrical energy measuring method|

---

PCT/FR2017/051540| WO2017220887A1|2016-06-20|2017-06-14|Electricity metering device|

---

BR112018076248-2A| BR112018076248A2|2016-06-20|2017-06-14|wireless electric energy metering device and electric energy metering method implemented using the|

---

US16/311,304| US20190324071A1|2016-06-20|2017-06-14|Electricity metering device|