DE102011011812A1 - Meter for electrical work, has units for remote data transmission and storage space that is established in meter, where measured value is determined by meter - Google Patents

Abstract

The meter has units for remote data transmission and a storage space that is established in the meter, where measured value is determined by the meter. The measured value is cyclically set with a value portion factor. The result of the settlement is stored within the storage. The meter transmits the value by the remote data transmission from central system.

Description

Due to the increase in the share of renewable energy in the electricity grid, the amount of energy available varies greatly. The price varies depending on the amount of available electrical energy. Since the storage of electrical energy is currently very expensive and expensive, it is advantageous to adjust the consumption accordingly. The invention relates to a counter, with which it is possible to constantly adjust the price of electricity, as desired. Due to the varying electricity prices, the consumption is controlled accordingly.

According to the prior art, so-called smart meters are known. The devices record the current power consumption in fixed time cycles and transmit it to the energy supplier. On the one hand, the information is made available to the customer via a web server so that the latter can monitor its consumption and, on the other hand, used to generate the invoice corresponding to the electricity prices in the respective time cycles.

The smart meter has the disadvantage that a total of large amounts of data must be transmitted and processed. Furthermore, the system is problematic in terms of data protection, as the habits of consumers can be very accurately understood from the data. The sensitivity of the customers for the data protection constantly increases, so that this could prevent the spreading of the production-fair control of the nets.

The invention has for its object to develop a counter for electrical work, which realizes the one hand, the known, price-controlled consumption control and on the other hand greatly reduces the amount of data to be transmitted and processed. A significant advantage of the meter according to the invention is that it is completely trouble-free in terms of data protection. Furthermore, regional consumption controls should also be possible.

The object is achieved by a counter having the features of the main claim. Advantageous embodiments or developments of the invention are given by subclaims.

In the proportion factor counter (AFZ) according to the invention, an electronic counter with means for remote data transmission (EDI) is expanded by at least one memory location (S2). By means of remote data transmission, the meter receives a value of factor (AF) cyclically from a central point or, if the price changes, a value. The AF is saved. Values for the AF are, for example, 0.5 for half the price or 2.0 for twice the electricity price relative to the basic price. Upon arrival of a new value for the AF or to an execution time appended to the value, the difference between the count at the time of the arrival of the last change or its conversion and the current count is formed. The difference is multiplied by the AF (eg 0.5) and added to the current value in memory S2. The result overwrites the old value in S2. By way of example, a real consumption of 10 KWh in the last 30 minutes is shown as a consumption of 5 KWh. The value in S2 thus always represents a portion of the electrical work actually measured. In the case of customers having a consumption focus at AF less than 1, the S2 value will then be smaller than the value actually measured; For customers who have a consumption focus at AF greater than 1, the S2 value will be correspondingly larger than the real measured value. In order to improve acceptance, the utility can provide best-in-class accounting; The customer can save if the value in S2 is smaller, but does not pay more for a larger value. In order to simplify billing, the S2 value can be transferred to the energy supplier via remote data transmission or retrieved from it.

A prior art electronic meter typically has a simple LCD numeric display. The display of different measured values is possible with the help of a button. In the case of the counter according to the invention, at least the value of S2, that is to say the portion to be paid, can then be displayed in the same way. It is also advantageous to record and display values for AF, accumulated real daily consumption and accumulated share daily consumption. As an alternative to the LCD digital display, higher-quality display systems can be used. Here then the o. A. Values are displayed simultaneously. The customer then sees at a glance the current savings and the previous savings success. Also conceivable is the additional display of direct funds for the values basic price, current price (basic price × AF), previously accrued costs with pure basic price calculation and costs incurred so far after calculation with the AF. Furthermore, the AF value can be displayed as a percentage value (eg 10% discount or 20% surcharge as current value).

In order to automate the consumption control, the counter according to the invention can be equipped with a connection or with an interface via which at least the value for the AF or a value assigned to it is output to external devices. Also conceivable is the transfer of display data and forecast data. Possible here are all common interfaces such. Eg S0 or RS 232/485. Consumers can go here directly be connected. Especially for controlling a plurality of consumers, it is advantageous to connect a control unit. For example, a simple PLC can evaluate a frequency of S0 corresponding to the AF and control devices connected with their integrated potential-free contacts as a function of the frequency level.

The automated control may have the disadvantage that too many concurrent consumers cause disturbances in the network. To avoid this, the counter according to the invention provides to output the reception of an updated AF with a time delay at the interface for external devices. Advantageously, the time delay is randomized. A value range of 0 to 300 seconds would then cause all devices that switch on, for example, with an AF of 0.5, doing this not simultaneously, but evenly distributed over a period of 300 seconds.

Alternatively, the value for the delay or a value for the size of the spectrum for the value range of the random number generator in remote data transmission is added to the value of the proportion factor.

Remote data transmission for strings containing at least the factor value is a distinction made between simplex and duplex systems. The simplex systems include teletext and SMS as an example. In the SMS system, the meter factor value is transmitted to the meter via an integrated or external mobile adapter. With the videotext system, on the one hand there is the possibility of providing a separate videotext page for each energy supplier and, on the other hand, at least one page is provided for all / several energy suppliers. In this case, the values for the share factor are assigned an identification string for the respective energy supplier, so that the meter can recognize, store and process the value corresponding to its energy provider.

Duplex systems are, for example, Internet or mobile connections. In an existing connection, the counter polls the AF cyclically or at a time, which was in a previously received string for the AF attached to the AF value, from its utility. When querying the AF with an identifier associated with the identification string (IDZ), the utility can even make regional consumption controls, for example, in strong winds only the counters a small AF transmitted, which are in the range of larger wind turbines. Alternatively, the respective values for the AF can also be stored more or less centrally. For example, all utilities could submit their current AF values to the Federal Network Agency. From here, the values are then published and made available to the counters. An advantage of this solution is the comprehensible, public documentation of the AF values and thus of the price trend for the electricity.

• 1. Beginnzeitpunkt der Gültigkeit.
• 2. Endzeitpunkt der Gültigkeit.
• 3. Verfügbarkeitszeitpunkt einer folgenden Zeichenfolge für den AF Wert.
• 4. Gültigkeitsstempel aktuell; fortlaufende Nummern.
• 5. Gültigkeitsstempel der folgenden Zeichenfolge.
• 6. Sicherheitszeichen.
• 7. AF/Preis Verlaufsprognosen geplant.
• 8. AF/Preis Verlaufsprognosen verbindlich.
• 9. ID des Energieversorgers.
• 10. Ausgabeverzögerungszeit.
• 11. Zeitspektrum für den Zufallsgenerator für die Ausgabeverzögerungszeit.
• 12. Preise.
• 13. Dem AF zugeordnete Werte; Prozentwerte.
• 14. AF-Werte aus Ausfallzeiten.

The following extensions are useful / possible for the strings containing the AF value:

• 1. Start date of validity.
• 2. End date of validity.
• 3. Availability time of a following string for the AF value.
• 4. valid stamp current; ongoing numbers.
• 5. Validity stamp of the following string.
• 6. Safety signs.
• 7. AF / price historical forecasts planned.
• 8. AF / price history forecasts binding.
• 9. ID of the energy supplier.
• 10. Output delay time.
• 11. Time spectrum for the random number generator for the output delay time.
• 12. Prices.
• 13. Values assigned to AF; Percentages.
• 14. AF values from downtime.

For simplified installation, it is also advantageous in certain cases to equip devices / consumers directly with data transmission units. For example, a DVB-T unit with teletext and processing module is placed on a large water heater. The system now determines the current value for the AF with the same identification string as the counter that powers it, and then controls the memory. A separate connection line to the counter or its associated control unit can be omitted. Another way to simplify installation is to use an in-building installation bus system.

• 1. AF-Werte für Verbrauch und Einspeisung sind gleich.
• 2. Unterschiedliche AF-Werte für Verbrauch und Einspeisung werden durch zählerinterne Verrechnung bestimmt/abgeleitet.
• 3. Völlig separate Abfrage/Übertragung der AF-Werte vom/zum Energieversorger/Zähler, wobei hier die AF-Wert Quellen auch unterschiedlich sein können.

Of course, the counter according to the invention can be used instead of as a consumption counter as a feed counter or bidirectional counter. As a feed-in meter for a biogas plant, corresponding AF values corresponding to higher feed-in tariff are leaked to the meter when little power is available. The operator of a biogas plant can then z. B. move through a gas storage feed-in capacity in time ranges in which a higher remuneration is paid. In the case of a bidirectional counter, as used, for example, in solar systems with self-consumption control, the following variants exist for the AF value:

• 1. AF values for consumption and feed are the same.
• 2. Different AF values for consumption and feed-in are determined / derived by internal metering.
• 3. Completely separate query / transmission of the AF values from / to the energy supplier / counter, where the AF value sources can also be different.

Particularly important in the invention rules for failure scenarios of the DUN. A counter operating on an out-of-date AF value generates false values at S2; the amount to be paid becomes too high or too low. For this reason, AF is automatically set to 1 by the counter for the duration of a dial-up failure. In principle, the system according to the invention is thereby temporarily switched off. The increase in S2 corresponds to the real measured increase in the downtime until a new valid value for the AF arrives. For optimization, the meter can log the consumption during downtime comparable to a smart meter. If the AF values for the failure period are later retrieved, the S2 value can then be corrected. The counter stores at least the real meter readings at the beginning and at the end of the downtime.

Examples of failure detection:

• 1. The meter detects failures at layer 1-3 OSI.
• 2. A following value for the AF does not arrive according to the time frame or is not available.
• 3. A follow-up value for the AF does not arrive at a time appended to the value of the last AF, or is not available.
• 4. A server request remains unanswered.
• 5. The value of the AF is appended with a constantly changing validity string. If z. B. in the videotext version after the expiration of a Zeitzyklusses no new / changed validity string is detected, this indicates a fault.

• 1. Direkte WAN-Schnittstelle am Zähler. Hier sind als wichtigste WLAN und Ethernet zu nennen, über die er mit einem gängigen Router verbindbar ist.
• 2. Einsteckmodule. Der Zähler wird durch Einsteckmodule an verschiedene Umgebungen angepasst. Beispiele: Ethernet, WLAN, Bluetooth, RS232/485 DVB-T/Videotext, USB.
• 3. Externe WAN-Adapter Eine beispielhafte externe Box hat als WAN-Schnittstelle zum Router Ethernet und als LAN-Schnittstelle für die Zähler Bluetooth. Bei Bedarf können sich hier auch mehrere mit Bluetooth-Schnittstellen ausgestattete Zähler mit der Box verbinden um die AF Werte abzufragen.

For remote data transmission of the counter, the following variants are possible, among others:

• 1. Direct WAN interface on the meter. Here are the most important WLAN and Ethernet call, via which he is connectable to a popular router.
• 2. Plug-in modules. The meter is adapted to different environments through plug-in modules. Examples: Ethernet, WLAN, Bluetooth, RS232 / 485 DVB-T / Teletext, USB.
• 3. External WAN adapters An exemplary external box has Bluetooth as a WAN interface to the router and as a LAN interface for the counters. If required, several meters equipped with Bluetooth interfaces can also be connected to the box to query the AF values.

The invention will be explained in more detail by means of an embodiment.

In the example, the meter is equipped with a Bluetooth and an S0 interface. The meter is connected via the Bluetooth interface with an external box, which in turn is connected via a wireless adapter to an Internet router and thus to the Internet. The S0 interface is connected to a PLC with means for frequency measurement. A frequency corresponding to the current AF (eg 1000 Hz at AF = 1) is output at the S0 interface. Via a potential-free contact of the PLC, a hot water storage tank is switched with the usual use of an auxiliary relay. The memory should switch on at half the electricity price (AF = 0.5).

The last string containing the AF value retrieved by the utility had the following content:
AF value = 2
Start validity = 09:00
End of validity = 09:15
Delay spectrum = 100 seconds
New AF value available from 09:10

Just in time before the end of the validity period (eg 09:10), the meter queries the energy provider for the current AF value with its ID. The response string has the following content:
AF value = 0.5
Start validity = 09:15
End of validity = 09:45
Delay spectrum = 50 seconds
New AF value available from 09:25

• 1. Der real gemessene Verbrauch zwischen 09:00 und 09:15 wird erfasst (Zählerstand 09:15 minus Zählerstand 09:00 im Ergebnis beispielsweise 20 KWh).
• 2. Das Ergebnis wird mit dem für den Zeitraum gültigen AF-Wert multipliziert (20 × 2 = 40 KWh).
• 3. Das Ergebnis wird zum im S2 gespeicherten Wert hinzuaddiert (z. B. 2300 + 40 = 2340).
• 4. Der berechnete und in S2 gespeicherte zu bezahlende Anteil (z. B. 2340) wird im Display angezeigt.
• 5. Der neue AF-Wert (0,5) wird im Display angezeigt.
• 6. Der Zufallsgenerator ermittelt eine Verzögerungszeit im bestimmten Bereich (0 – 50 z. B. 24 sec.)
• 7. 24 Sekunden nach 09:15 senkt der Zähler die Frequenz an S0 von 2000 Hz auf 500 Hz.
• 8. Die angeschlossene SPS wertet den Wert von S0 aus, vergleicht ihn mit Vorgabewerten und schaltet auf Grund der Preissenkung den Brauchwasserspeicher ein.

At the beginning of the new AF value (09:15), following a successful plausibility check:

• 1. The real measured consumption between 09:00 and 09:15 is recorded (count 09:15 minus count 09:00 in the result for example 20 kWh).
• 2. The result is multiplied by the AF value valid for the period (20 × 2 = 40 KWh).
• 3. The result is added to the value stored in S2 (eg 2300 + 40 = 2340).
• 4. The calculated portion to be paid (eg 2340) stored in S2 is shown in the display.
• 5. The new AF value (0.5) is shown in the display.
• 6. The random number generator determines a delay time in the defined range (0 - 50 eg 24 sec.)
• 7. 24 seconds after 09:15, the counter lowers the frequency at S0 from 2000 Hz to 500 Hz.
• 8. The connected PLC evaluates the value of S0, compares it with default values and turns on the hot water tank due to the price reduction.

Abbreviations:

• AF

  proportional factor

  AFZ

  Share factor numerator

  IDZ

  an identification string associated with a counter

  Dial

  Remote data transmission

Claims (9)

Counter for electrical work, characterized in that means for remote data transmission are arranged on the counter, that at least one further memory location S2 is created in the counter, that the measured values determined by the counter are cyclically offset with a value proportional factor, that the result (s) the billing in the memory S2 is / are stored and that the counter / the value / s share factor is transmitted by remote data transmission from central systems / are. Counter for electrical work according to claim 1, characterized in that the memory value of S2 is displayed in addition to the current count in the display. Counter for electrical work according to claim 1, characterized in that the memory value of S2 can be displayed as an alternative to the current counter reading per key in the display. Counter for electrical work according to claim 1, characterized in that in the event of a malfunction of the remote data transmission, the value factor factor for the period of the disturbance automatically assumes the value 1 and thus causes in the calculation that for the period of the disturbance of the increase in value at S2 the increase of corresponds to the measured value determined by the counter. Meter for electrical work according to claim 1, characterized in that a connection is arranged at the counter with the aid of which the share factor or a value assigned to it is made available to further devices. Counter for electrical work according to claim 1 and 5, characterized in that the share factor or its associated value of other devices random control, time delay is provided. Meter for electrical work according to claim 1, characterized in that at least the current value for the share factor is maintained on at least one central server and that this value is retrieved by the counter with a unique identification string associated therewith. Counter for electrical work according to claim 1 and 7, characterized in that counters receive individual values when interrogating the value for the proportion factor with their identification strings and that thus regional consumption control becomes possible. Counter for electrical work according to claim 1 to 8, characterized in that the counter is used as Einspeisezähler or as a bidirectional counter.