WO2009033848A2

WO2009033848A2 - Arrangement and method for transmitting meter data

Info

Publication number: WO2009033848A2
Application number: PCT/EP2008/059059
Authority: WO
Inventors: Gerd Völksen
Original assignee: Siemens Aktiengesellschaft
Priority date: 2007-09-06
Filing date: 2008-07-11
Publication date: 2009-03-19
Also published as: DE102007042445A1; WO2009033848A3

Abstract

The invention relates to an arrangement for transmitting consumption meter readings, particularly current meter readings, to an energy supply company (EVU). The arrangement comprises at least two consumption meters, each having a communication unit forming an ad hoc wireless network. One of the meters is further connected to the EVU. Read-out meter data is communicated to the meter connected to the EVU via the network, and provided to the EVU from that location. According to the invention the wireless network is a sensor radio network, while the communication units are sensor radio network units.

Description

description

Arrangement and method for transmitting meter data

Reading out a consumption meter, for example one

Electric meter, in a conventional manner by the customer of the utility company (EVU) or by a hired at the RU reader. In the first case rounding or reading errors occur regularly to the disadvantage of the RU, while the employment of a reader for the RU is relatively expensive.

Alternatively, smart meters can be connected to the RU via Powerline Communication so they can be polled remotely. In the deregulated energy market, the problem nowadays is that customers still receive their electricity from the RU, but that consumption is billed with a virtual energy supplier (vEVU) if necessary. The flow of information from the customer's electricity meter to the vEVU can then no longer be made via Powerline Communication, since the powerline leads to the RU, but not to the vEVU. The vEVU therefore does not have the remote consumption data for invoicing available.

This communication gap can be closed by means of a radio link (e.g., GSM, GPRS, UMTS) from the meter to the vEVU. However, this connection does not work where the radio-equipped counters are located in premises that do not allow radio network access (e.g., basement). In addition, the single consumption meter becomes disproportionately expensive due to the installation of a radio unit.

The aim of the invention is therefore to provide a cost-effective arrangement for data transmission from a Datenerfas- sungsgerät to an evaluation. This object is achieved by the inventions specified in the independent claims. Advantageous embodiments emerge from the dependent claims.

The proposed arrangement for transmitting data from an electricity meter to a vEVU assumes that e.g. in a cellar of a multi-party house at least two electricity meters are available, each having a communication unit. Only one of the electricity meters also has a remote interrogation module and is connected to a radio unit through which a connection to the vEVU can be made. The communication units set up an ad-hoc radio network and transmit data records, comprising at least the meter reading and the meter number, to the electricity meter connected to the vEVU so that the vEVU has access to the data relevant for billing.

According to the invention, the radio network is designed as a sensor radio network, in which the typical nodes of a radio network are formed by sensors or sensor network units which can exchange data over the network. These sensor network units form the communication units described above and, in contrast to radio units, are typically less expensive and less expensive. Such a sensor radio network consists of at least two sensor network units and is a self-organizing ad hoc network.

A sensor network unit has an EPROM for storing the application - in this case the reading of the electricity meter reading and counter identification in the form of the meter number - and a processor for its execution. Additional sensor network-specific functions include the computation and administration of routing tables, the routing of messages and watchdogs for other sensor network units. There is also a RAM for storing measurement data, routing tables, etc. as well as a communication module, which broad, wireless communication with other sensor network devices. The sensor functionality of the sensor network units is limited to the access to the interface of the electricity meter and the simple reading out of the relevant data. In addition, sensor network units are capable of building ad-hoc networks and communicating data within the network.

The more complex features of sensor-based networks, such as sensor localization and

Synchronization can be omitted. Likewise, the power management of the sensor network units plays no greater role, since they are connected in the present case directly to the electricity meter and are supplied via this.

The invention is equally applicable to the transmission of data from other utility meters such as heat, water and gas meters.

Further advantages, features and details of the invention will become apparent from the embodiment described below and from the drawing.

Showing:

Figure 1 shows a schematic representation of an inventive arrangement for transmitting data from a plurality of data acquisition devices to a Datenauswer- teeinrichtung.

1 shows a multiparty house 100, in which four data acquisition devices 11-14 designed as intelligent electricity meters detect the power consumption of the consumers 21 through 24 by means of counters 31 - 34. The consumers 21-24 represent all electric energy consuming devices Devices of the Individual Parties The power consumption measured by the counters 31-34 is stored in memory devices 41-44 along with other counter specific ones Data such as a unique meter number, a reading time and possibly information that several meter readings are present (main and night tariff), in the form of records Dl - D4 deposited.

The electricity meters 11-14 are each connected to a communication unit 51-54, which may be integrated in the housing of the electricity meter 11-14 or, as shown in FIG. 1, may be equipped with its own housing. The connection between the electricity meter 11-14 and the communication unit 51-54 is usually wired, but can also be realized via radio. The communication units 51-54 can access the memory devices 41-44 assigned to them in order to read out the data sets D1-D4 stored there, in particular the measured power consumption and the meter number identifying the power meter 11-14.

In addition, the communication units 51-54 include communication modules 61-64, with which a connection to the communication units 51-54 of the other electricity meters 11-14 can be recorded and a short-range ad-hoc wireless network 80 can be constructed, advantageously known protocols such as Bluetooth , ZigBee or similar to be used. In particular, the radio network 80 is a sensor radio network with the characteristics described above and with sensor radio network units 51-54.

The data sets D1-D4 read out of the storage devices 41-44 by the communication units 51-54 are temporarily stored in the radio network 80. The intermediate storage can take place in such a way that a data set comprising all data sets D1-D4 is created which is buffered completely replicated on several of the communication units 51-54 so that increased data security and availability results on the one hand and on the other hand the access time is reduced because the individual data sets of the communication units 51-54 are present a transmission need not be collected first. Alternatively, it is possible that each communication unit 51 - 54 temporarily stores only the data record Dl - D4 read from the associated memory unit 41 - 44.

One of the electricity meters 11-14, in the illustrated embodiment the electricity meter 14, also contains a remote interrogation module 74 and has via the remote interrogation module 74 and a radio unit 90 a data connection to a Datenauswerte- device 200, which may be a possibly virtual power company vEVU. This connection can be realized via a mobile radio network 300 as illustrated in the figure. Alternatively, connections are via an S0 interface, an M-Bus, a PSTN modem or similar. possible. The transmission of the cached data sets Dl - D4 via the data connection is either triggered by a request from the RU 200 or automatically according to a predetermined scheme, for example once a year.

Usually, the electricity meter 11 - 14 are housed in the basement of the apartment building in the embodiment. However, the spatial arrangement of the electricity meters 11-14 is determined only by the range of the communication modules 61-64. Due to the use of a sensor network and the corresponding sensor network units, there are no network topology regulations, i. flexible spatial arrangements such as star architectures, meshed networks or linear chains can be realized.

Furthermore, the arrangement according to the invention is of course expandable to other metering devices to be read, such as heat, gas and / or water meters. Likewise, the invention is applicable to heterogeneous meter networks comprising metering devices of different types.

Claims

claims

1. A method for transmitting counter data to a data evaluation device (200) with the following steps: - generating at least one first data record representing first counter data (Dl - D3) by means of at least one first counter device (11-13),

Reading the first data set (D1-D3) by a first communication unit (51-53) connected to the first counter device (11-13),

- Generation of a second counter data representing second data set (D4) by means of a second counter means (14),

Reading the second data set (D4) by a second communication unit (54) connected to the second counter device (14),

Establishing a local ad hoc radio network (80) by the first and second communication units (51-54),

- Transmission of the first data set (Dl - D3) from the first to the second communication unit (51 - 53, 54) via a

Connection of local ad hoc radio network (80),

Establishing a connection between the data evaluation device (200) and a radio module (74, 90) of the second communication unit (54), the radio module (74, 90) and the data evaluation device (200) belonging to a second radio network (300), and

- Transmission of the first and the second data set (Dl - D3, D4) to the data evaluation device (200) via the established connection of the second radio network (300).

2. The method according to claim 1, characterized in that the data sets (Dl - D4) are cached in the radio network (80).

3. The method as claimed in claim 2, characterized in that each communication unit (51-54) temporarily stores the data set (D1-D4) read from the counter device (11-14) connected to it.

4. The method as claimed in claim 2, characterized in that a data set comprising all data sets (D1-D4) is buffered replicated on a plurality of the communication units (51-54).

5. The method according to any one of claims 2 to 4, characterized in that the transmission of the cached data sets (Dl - D4) by the second communication unit (54) via the radio link to the Datenauswerteeinrichtung (200) on request by the Datenauswerteeinrichtung (200) or automatically according to a predetermined scheme.

6. The method according to any one of the preceding claims, characterized in that the radio network (80) operates according to the Bluetooth or the ZigBee protocol.

7. Arrangement for transmitting counter data to a data evaluation device (200) with - at least one first counter device (11 - 13) for generating a first data record (D1 - D3) representing first counter data,

a first communication unit (51-53) connected to the first counter means (11-13) for reading out the first data set (D1-D3),

A second counter device (14) for generating a second counter data representing second data set (D4),

a second communication unit (54) connected to the second counter device (14) for reading out the second data set (D4),

A first and a second communication module (61-63, 64) for transmitting the first data set (D1-D3) from the first communication unit (51-53) via a connection of one through the first and second communication modules (61-63, 64) established local ad hoc radio network (80) and - One to the second communication unit (54) connected to a second radio network (300) associated radio module (74, 90) for transmitting the first and second data set (Dl - D3, D4) to the Datenauswerteeinrichtung (200).

8. Arrangement according to claim 7, characterized in that the radio network (80) as sensor network and the communication units (51 - 54) are designed as sensor radio network units.

9. Arrangement according to claim 7 or 8, characterized by means for buffering the records (Dl - D4) in the radio network (80).

10. Arrangement according to claim 9, characterized in that each communication unit (51-54) has means for buffering the data set (Dl-D4) read from the counter device connected to it.

11. Arrangement according to claim 9, characterized in that a plurality of the communication units (51-54) have means for temporarily storing a data set comprising all data sets (D1-D4).

12. Arrangement according to one of claims 7 to 11, characterized in that the data evaluation device (200) is a power supply company, that the counter means (11-14) are electricity meters, in particular smart meters, gas or heat meters and that the Data (Dl - D4) include counter readings as well as information for the identification of the counters.

13. Arrangement according to one of claims 7 to 13, characterized in that the radio network (80) operates according to the Bluetooth or the ZigBee protocol.