EP3117101A1 - Method for the configuration of an electromotive pump assembly - Google Patents

Abstract

The invention relates to a method for the configuration of a first electromotive pump assembly (1b) using configuration data. In this case, configuration data and/or operating data of a second pump assembly (1a) are stored in a non-volatile memory unit (6, 6a) of pump electronics (3a) of the second pump assembly (1a) and are transmitted from the second pump assembly (1a) to the first pump assembly (1b). Said first pump assembly then transfers said data into the pump electronics (3b) thereof. The transmission may be performed by way of a memory module, by radio or optically by means of a code. The invention also relates to pump assemblies (1a, 1b) which are correspondingly designed to be used in the method according to the invention.

Description

 Method for configuring an electromotive pump set

The present invention relates to a method for configuring a

electromotive pump set with configuration data.

Pump units must be adapted to the hydraulic conditions of their place of use. For this purpose, numerous options are available in the pump electronics of a pump set that are steadily increasing in complexity. Although intelligent pump units are increasingly coming onto the market that can adapt themselves optimally to their operating situation, a good initial configuration nevertheless is expedient since it usually takes several weeks or even months until an intelligent pump set has collected enough information to determine which operation or operating point of the energy table

Cheapest is. However, even these pump units can not all

Determine information automatically, for example, their purpose or the funded medium.

For an optimum setting of the pump unit, therefore, the knowledge of the connected piping network is absolutely necessary. As an example, here are the use of centrifugal pumps in heating systems,

Drinking water pumps in pressure booster systems for drinking water supply in buildings and sewage pumps for waste water disposal called. In such applications are nowadays electronically controlled and

Variable speed pumps with frequency converter in use, which can be operated not only at a constant speed but variable speed. This is usually done according to an adjustable characteristic that has a connection describes between the differential pressure provided by the pump and the volume flow produced by it. For example, so-called Δρ-c characteristic curves are known which keep the delivery height constant over the volume flow.

Δρ-ν characteristic curves which define a linear relationship between the delivery head and the volume flow, or temperature-controlled characteristic curves which define a delivery pressure in dependence on an outside temperature or the medium temperature. The area of application of the pump set is decisive for choosing the right or suitable characteristic.

Furthermore, detailed knowledge about the pipe resistance, a possible geodetic height and setpoints for a desired pressure in the

Pipeline network, i. a certain amount, and for a given amount

Volumetric flow required so that all radiators or heating surfaces are adequately supplied in the case of a heating system, and in the case of a drinking water system there is sufficient pressure at all tapping points.

In addition, modern pump sets offer a variety of activatable

Functions and settings as well as various communication interfaces for remote maintenance and remote signaling, which enable integration into a building management system.

If a pipe network with a pump set is first installed and commissioned, all settings and parameter settings must be made on the pump set. This is tedious, time consuming and usually requires detailed knowledge of the way in which the

Configuration is made.

It is therefore an object of the present invention, a method and

provide appropriate pump units for this, the one or the

Configuration of a pump set in a simple way, fast and without technical expertise on the implementation of the configuration on

Pump unit allows or enable. This object is achieved by a method having the features of claim 1. Advantageous developments are specified in the subclaims.

The core idea of the invention is, firstly, existing

Transfer configuration data of a second pump set to the first pump set to be configured. On the other hand, alternatively or additionally, operating data of the second pump set can be used in order to obtain configuration data therefrom by means of operating data evaluation software, which data are then transferred to the first pump set to be configured. This idea is based on the realization that in different situations complete configurations and valuable knowledge about a pipeline network in

Pump units are already available. Applying this data reduces the time required for the configuration when commissioning a new pump set to a minimum.

A first situation is, for example, a service case. Does it come with one

If the pump set is installed for a technical defect requiring replacement, the installer must re-make all the settings for the replacement pump. This leads to a correspondingly increased effort and

Personnel costs. In addition, a documentation of the hydraulic

Properties of the piping network and the pump usually are not or no longer present. Also, the installer of the replacement pump installer is usually not identical to the person who has installed the pump to be replaced. For an adjustment of the pump to the connected hydraulic network and for an energetically optimal setting of the pump would therefore be a renewed

Measurement and calculation of the pipeline network and its resistances required, which is hardly done in practice. Rather, the pump set is configured with universal settings based on assumptions and estimates. It follows that it is not energetically optimal.

A second situation is, for example, the case that pipeline networks are constructed with approximately identical structure and hydraulic properties, as is the case for example in terraced houses or model houses of the same type. Here several identical pump sets would have to be configured identically be, which also leads to a correspondingly high cost. However, according to the invention, this can be minimized if knowledge of one or knowledge about another pump unit is used, in the best case simply copied.

Accordingly, the invention proposes a method for configuring a first electromotive pump set with configuration data, in which

Configuration data and / or operating data of a second pump set in a non-volatile memory unit of a pump electronics of the second

Pump unit are stored, and are transmitted from the second pump unit to the first pump unit, which they then in his

Pump electronics takes over.

In the case of configuration data, these can be transferred directly to the operating software of the first pump set, so that the first pump set is configured according to the second set of pumps. This corresponds to copying existing configuration data from the other pump set.

In the case of operating data, the implementation of a

Intermediate step proposed in which from the operating data of the second

Pump unit can be obtained by means of a Betriebsdatenauswertesoftware configuration data, which then the first pump unit in his

Operating software can take over or take over. These

Operating data evaluation software can either be an integral part of the first pump set or represent a separate software solution, for example on an external computer. Background of this procedure is the fact that just the control technology in pump units, especially for efficiency and efficiency optimization continuously

developed so that the operating data of the second pump unit can always be evaluated according to the latest knowledge to obtain suitable configuration data and this configuration data are then available for the first pump unit. Operational data in this context is such data that defines operating conditions and / or operating points actually achieved by the second pump set, ie, a set of historical data representing the

Characterize the life history of the second pump set. The

Operating data can be occurred errors or measured data or calculated or estimated values of physical quantities of the pump set. One

Operating state, for example, the current speed, the electrical

Power consumption, the applied differential pressure or the subsidized

Volume flow of the pump set to be. An operating point, for example, by the two hydraulic variables volume flow and head

(Differential pressure) to be described, as is usually the case in a so-called HQ diagram. By means of a Betriebsdatenauswertesoftware can be determined from the operating data, for example, in which modes, which operating areas, along which characteristics a pump unit worked and what demands the hydraulic network has made to the pump unit, so that another pump unit, which are now connected to the hydraulic network should be optimally set up on this network. This is done by the operating data evaluation software evaluates the operating data and generates configuration data from them, which then stores the first pump unit for its control and / or regulation in its operating software.

For the purposes of the present invention, configuration data is understood as meaning data which can be given to a pump set, i. are adjustable and affect the pump unit in its operation, in particular to adjust the operation to a specific operating environment. The configuration data are preferably parameter value settings and / or at least one

Function setting of the first pump set.

The non-volatile memory unit is one commonly used in a

Pump electronics permanently integrated working or operating memory on which the

Operating software and any other data may be stored, additional physical memory that can hold stored data permanently. According to the invention, the configuration and / or operating data are stored from the working or operating memory in this additional memory unit. This can, for example, once during commissioning of the second

Pump unit take place, i. immediately after the pump set has been configured, which of course only relates to configuration data, as there are no operating data at this time. Alternatively, the

Storage of the configuration and / or operating data on the memory unit after some time after commissioning during operation. This can also be the case once, for example, as soon as all configuration data is present, or repeated, in particular at certain fixed times or periodically, so that always current configuration and / or operating data

are stored. This takes into account in particular the case that the

Pump unit is self-learning and seeks his optimal operation setting, for example, in terms of low power consumption itself. It may be, for example, that a previously set control characteristic is replaced by a more energy-efficient control characteristic. If this is the case, the

Configuration and / or operating data are updated or supplemented during the next storage. The update can be done by completely overwriting. Alternatively, only those configuration data that have changed can be overwritten.

In addition to the configuration and / or operating data, any further data from the second pump unit can also be taken over into the first pump unit by means of the method according to the invention.

For example, information about the second pump set, such as its type or the version of the operating software. Such information may be important in a detailed fault analysis and provide valuable insight into failures in the hydraulic system.

According to a first variant, the transmission of the configuration and / or operating data from the second pump unit to the first pump unit can be done manually. For this purpose, the memory unit in the second

Pump unit be removably inserted memory module, which is transported from the second pump unit to the first pump unit and connected to the pump electronics of the first pump unit plug-in. By the Inserting the memory module in the first pump unit, it is connected electrically and communication technology with the pump electronics.

Ideally, the first pump unit then reads the configuration and / or operating data from the memory module and stores it for controlling and / or regulating its drive unit in an operating or working memory of its pump electronics. In the case of the configuration data, this takes place directly, in the case of the operating data indirectly, since here an evaluation of the

Operating data takes place, which leads to the extraction of suitable configuration data for the first pump set. These obtained configuration data are then from the first pump unit for controlling and / or regulating his

Drive unit stored in the operating or working memory of its pump electronics. The storage and / or evaluation of the operating data can be done automatically as soon as the memory module is plugged in, or by manually activating a corresponding transmission procedure.

To realize the first embodiment variant, the pump electronics of the first and second pump unit can each have at least one slot in order to connect a memory module to the pump electronics electrically and in terms of communication technology.

It is therefore according to the invention, a pump unit in particular for

Execution of the method according to the invention with an electromotive

Drive unit and a pump electronics for controlling and / or regulating the drive unit proposed in which the pump electronics has a slot with a removable plug-in memory module to connect the memory module electrically and communication technology with the pump electronics. As far as this pump unit forms the second pump unit, this is set up to store configuration data from its operating software or operating data determined during its operation on the memory module. As far as this pump unit forms the first pump unit, this is set up,

To load configuration and / or operating data from the memory module and to take over into its pump electronics, in particular in the case of

To transfer configuration data directly into its operating software or in the case of Store operating data in an operating or working memory of its pump electronics.

The slot or the memory module are preferably accessible from outside the pump electronics, so that the housing of the pump electronics does not need to be opened. This facilitates the insertion or removal of the

Memory module and prevents current-carrying parts of the pump electronics are touched inside the housing. In this case, it may nevertheless be provided that the slot and / or the memory module can be closed by a removable cover, in particular sealed, in order to protect the slot or the memory module from protection and, if necessary, from moisture.

The memory module is preferably a digital one

Storage medium, in particular according to the flash memory technology.

For example, it may be a SD card (Secure Digital Memory Card), a MMC card (Multimedia Card) or a SIM card (Subscriber Identity Module). The memory module may have any format, for example, the size of the classic SD, MMC and SIM card, or be designed as a mini, micro or nano card. Alternatively, it can also be designed as a USB memory stick (Universal Serial Bus). The storage media mentioned are well known, so that no further details are given. They are sturdy and easy to handle. Especially with USB memory sticks, it can be assumed that they represent a type of memory that has been available for years.

According to the storage medium used, the slot of the first and second pump unit is designed so that it has the appropriate

Record storage medium mechanically and contact electrically. To connect a USB memory stick, the slot can be configured accordingly as a USB socket. This has the advantage that in principle also an external hard drive can be connected to the pump set. It should be noted that there may also be two or more slots that can accommodate different storage media. According to a second variant, the transmission of the configuration and / or operating data from the second pump unit to the first pump unit can be carried out by radio.

For this purpose, it can preferably be provided that an RFID transponder (Radio Frequency Identification) of the second pump set reads out the configuration and / or operating data from the memory unit and transmits it by radio.

For this purpose, a pump unit with an electromotive

Propulsion unit and a pump electronics for controlling and / or regulating the drive unit proposed with a non-volatile memory unit that has stored configuration and / or operating data in the memory unit, wherein the pump electronics comprises an RFID transponder, read the memory unit and the configuration In this case, the transponder can be active, preferably passive, in order to avoid being energized for the readout.

Because the use of passive RFID for radio transmission of the configuration and / or operating data has the advantage that the data can still be read out of the second pump unit, if this is no longer operational due to a defect, especially de-energized or whole

is switched off, so that the RFID transponder is not affected by the

Pump unit can be electrically powered. Because with the passive RFID technology, an area antenna in the RFID transponder generates a voltage from an electromagnetic field to supply a

M i croch ips, which is able to read a memory and the data on the surface antenna is able to re-radiate.

Advantageously, the non-volatile memory unit is an integral part of the RFID transponder. Since RFID transponders are equipped with an integrated memory unit as standard, it is thus not necessary to provide an additional physical electronic component which forms the non-volatile memory unit for storing the configuration and / or operating data in the Provide pump electronics. Rather, the storage can be done directly in the memory of the RFID transponder.

As already mentioned, an electromagnetic field is required to read a passive RFID transponder. This can be broadcast for example by means of an external mobile reader. It can then be provided that the mobile RFI D reader receives the transmitted configuration and / or operating data and forwards them to the first pump unit, which then receives them and for controlling and / or regulating its drive unit in an operating or working memory of its pump electronics stores. The configuration data can be used directly for the control and / or regulation of the drive unit, in the case of the operating data, this is done indirectly, since initially their evaluation for the purpose of obtaining configuration data is required.

An external reading device has the advantage that the forwarding of the configuration and / or operating data to the first pump set can take place in any way, for example also by radio or by cable. For the

Radio transmission can use any technology,

For example, also RFID, NFC (Near Field Communication), WLAN (Wireless Local Area Network), Bluetooth or Irda (infrared transmission). Also to

wired transmission can serve any technology

For example, a network connection to TCP / IP, a USB connection, a LON or CAN bus connection or a serial connection, for example of the RS-232 type. To the configuration and / or operating data in the first

As a rule, it is therefore possible to load a pump set, as a rule

existing communication interfaces are used.

Alternatively, the electromagnetic field can be emitted by the first pump unit, in particular its pump electronics. For this purpose, in the first pump unit or in the pump electronics, an RFID reader may be present which generates the electromagnetic field and the configuration and / or operating data transferred back from the second pump unit

receives and for controlling and / or regulating its drive unit in the Memory unit stores its pump electronics. This has the advantage that no separate reader is needed. It is sufficient to bring the second pump unit or its pump electronics in the vicinity of the first pump unit or its pump electronics, ie to bring the RFID transponder in the electromagnetic field of the RFID reader to make the transfer of the configuration data.

According to a third variant, the transmission of the configuration and / or operating data from the second pump unit to the first pump unit can be made optically by means of a code. This can be done in such a way that the data are displayed encrypted on a controllable display of the pump electronics of the second pump unit. The code is then read and

encrypted or decrypted provided the first pump set. The configuration and / or operating data are then stored after its provision on a pump unit for controlling and / or regulating its drive unit in an operating or working memory of its pump electronics. Again, the configuration data can be used directly, the operating data indirectly for controlling and / or regulating the drive unit.

The configuration and / or operating data may be on the part of the second

Pump unit in a string or two- or

multi-dimensional graphical code to be encrypted or in this

Character string or this graphic code must be displayed encrypted.

The string may be a sequence of alphanumeric characters and / or symbols. A string has the advantage that it can be read without a reader. The configuration and / or operating data, the

can be extensive, are thereby mapped to the comparatively few characters and / or symbols of the string, resulting in less data

are transmitted as in the case of uncoded configuration and / or operating data. The string can have any finite number of characters and / or symbols. The length can be dependent on the amount of configuration and / or operating data to be coded. The graphical code may be a one-dimensional dot or bar code (bar code) or a two-dimensional dot code, also called matrix code, such as a QR code. Also multi-dimensional codes consisting of nested bar and / or matrix codes are possible. You can record a variety of information encoded as well as redundancies and

Contain checksums to reduce the susceptibility to errors and are therefore particularly safe for the error-free transmission of data from one

Pump unit to another pump unit.

The reading of the character string can be done by a user who has the

Then also enter the character string manually on the first pump unit. This can be done with the aid of a control element, in particular a control knob, wherein the input characters are preferably displayed during their input on a display of the first pump unit.

Alternatively, the transmission of the graphic code between the

Pump units preferably by optical reading by means of a mobile optical code reader done. The reading device can then provide the configuration and / or operating data to the pump electronics of the first pump unit.

The use of a code reader has the advantage that the reading can be done by machine, so that no errors in the acquisition of the

Configuration and / or operating data, in particular reading-related errors may occur. A further advantage is that the forwarding of the configuration and / or operating data to a pump unit can take place in any way, for example by radio or by cable. For the radio transmission, any known technology can be used, for example also RFID, NFC (Near Field Communication), WLAN (Wireless Local Area Network), Bluetooth or infrared transmission. Also to

wired transmission can serve any technology

For example, a network connection to TCP / IP, a USB connection, a LON or CAN bus connection or a serial connection, for example to RS-232. To the configuration and / or operating data in the pump set to Consequently, one of the usually existing communication interfaces can be used.

The operating data can be decoded by the first pump set or in the reader. Also, it is possible that the reader and the first one

Pump unit each perform a partial decoding.

To carry out the transmission of the configuration and / or operating data by optical means as coded information is proposed as a second pump unit according to the invention a pump unit with an electric motor drive unit and a pump electronics for controlling and / or regulating the drive unit with a non-volatile memory unit, wherein the

Pump electronics has a coding unit for coding configuration and / or operating data to a character string and / or a graphic code and a display for displaying the character string or the graphic code, wherein the coded configuration and / or operating data in the memory unit can be stored.

In a corresponding manner, a pump unit with an electromotive drive unit and a pump electronics for controlling and / or regulating the drive unit with an operating memory is proposed as the first pump unit, wherein the pump electronics has a decoding unit for decoding coded configuration and / or operating data, wherein the pump electronics to is set up, the decoded configuration and / or operating data for

Control and / or regulation of the drive unit in the operating memory

save.

Further features and advantages of the method according to the invention and the pump units according to the invention are described below with reference to three

Embodiments and the accompanying figures explained in more detail. Show it:

Figure 1: Transmission of configuration data by plugging a

 memory module

Figure 2: Transmission of configuration data by radio reading FIG. 3: Transmission of configuration data by optical readout

FIG. 1 shows on the right a first pump unit 1 b and on the left a second one

Pump unit 1 b. The first pump unit 1 b is prior to commissioning and requires a configuration, with parameter values and functions to be set. The second pump unit 1 a was already in operation and therefore has a complete configuration and operating data, its past

Characterize operating conditions and operating points that have been passed through. The first and the second pump unit 1a, 1b are structurally the same or at least similar in that the first pump unit 1b can replace the second pump unit 1a in the application in which it was operated.

Both pump units 1a, 1b have an electromotive drive unit 2a, 2b and pump electronics 3a, 3b for controlling and / or regulating the respective drive unit 2a, 2b. The pump electronics 3a, 3b each have a slot with a removable insertable memory module 6, for example in the form of an SD card. In the pump electronics 3a of the second pump unit 1 a such a memory module 6 is inserted. The slot is electrically and communicatively connected to a microprocessor 5a, which takes over the data transmission and data processing in the pump electronics 3a. Since the memory module 6 is inserted, this is also with the

Microprocessor 5a connected. In addition, the pump electronics 3a a non-volatile memory 4a, are stored in the operating data and in particular the operating software including configuration data.

This operating memory 4a is also communicatively connected to the microprocessor 5a.

The first pump unit 1 b has the same components. Its pump electronics 3b also has a slot for the memory module 6 and is electrically and communicatively connected to a microprocessor 5b, which takes over the data transmission and data processing in the pump electronics 3b. In addition, the pump electronics 3b has a non-volatile operating memory 4b for operating data and configuration data of the operating software. This operating memory 4a is also communicatively connected to the microprocessor 5a. The second pump unit 1 a is set up during operation to store operating and configuration data from its operating software, ie in particular from the operating memory 4 a to the memory module 6 at regular intervals. This configuration data includes all parameter value and function settings. The operating data comprise a history of operating points that have been passed through, optionally measured values of physical quantities of the operating data

Pump unit and / or error information.

The memory module 6 is accessible from the outside, so that no housing of the

Pump electronics 3a needs to be opened. Because of this simple

Accessibility, it can be easily removed from the second pump unit 1 a and inserted into the slot of the pump electronics 3b of the first pump unit 1 b.

If the second pump unit 1a is defective and has to be replaced by the first pump unit 1b, the memory module 6 with the configuration data stored there is pulled out of the slot of the pump electronics 3a of the second pump unit 1a and into the corresponding slot of the pump electronics 3b of the second pump unit 1b put into it. This is illustrated by the dashed arrow. The first pump unit now loads the configuration and operating data from the inserted memory module 6 and takes it into its pump electronics by being stored by the microcomputer 5b in the operating memory 4b. Configuration data is transferred directly to the operating software. The operating data are first evaluated by means of an evaluation software, wherein from the operating data information about a suitable configuration of the first pump unit, for example, one for the hydraulic network to which the first pump unit to be connected, optimal characteristic can be determined. The configuration is then transferred to the operating software of the first pump set.

According to this first embodiment, the transmission of the

Configuration and operating data from the second pump unit 1a to the first pump unit 1 b consequently manually by means of a transported physical Storage medium that carries the configuration and operating data and from a slot of the second pump set in a slot of the first

Pump unit is transferred.

Figure 2 shows an alternative embodiment for the transmission of

Configuration and operating data from the second pump unit 1a to the first pump unit 1 b, in which the data is read by radio. Below are just those components and properties of the two

Pump units 1a, 1 b addressed, in which they differ from the first

Different design variant.

According to the second embodiment, the second pump unit 1a has a passive RFID transponder 7a, wherein the non-volatile memory unit 6a is part of this RFID transponder 7a. The memory unit 6a can accordingly be read out by the RFID transponder 7a as soon as an electromagnetic field passes through the RFID transponder 7a.

To generate the electromagnetic field and to read the RFID transponder 7a or its storage unit 6a, a mobile RFID reader 8 is used. This receives the emitted from the RFID transponder 7a configuration and operating data and directs them in any way to an interface 9 of the first pump unit 1 b, which is expressed by the dashed arrow. This can be wired or by radio, so that the interface 9 can be configured either as a radio receiver or as a socket for a cable, the interface 9 is connected within the pump electronics 3b to the microcomputer 5b, so that the

Configuration and operating data can be transmitted to this and stored by the latter in the operating memory 4b.

The first pump unit 1b also has a passive RFID transponder 7b with a non-volatile integrated memory unit 6b into which the

Microcomputer 5b can store configuration and operating data, so that the first pump unit offers the possibility of configuration and

Read operating data via RFID. FIG. 3 shows a further alternative embodiment variant for the transmission of the configuration and operating data from the second pump unit 1 a to the first pump unit 1 b, wherein the readout of the data takes place optically. Hereinafter, only those components and properties of the two pump units 1 a, 1 b are addressed in which they differ from the first

Different design variant.

According to this third embodiment, the second pump unit has a display 10a with a display 13a. The non-volatile memory unit 6a, in which the configuration and operating data are stored, is part of the

Ad control of the display 10a.

Furthermore, the pump electronics 3a of the second pump unit 1 a has a coding unit for coding the configuration and operating data to a

String 14 and / or to a graphic code. The coding unit can be a separate electronic unit within the pump electronics 3a or part of the microcomputer 5a, as is the case in the third embodiment variant in FIG. The coding unit here encodes the configuration and operating data and stores them in this coded form in the memory unit 6a, so that they can be displayed immediately on the display 13 a. At the third

Variant this is done in the form of an alphanumeric string 14th

The character string 14 can be read from the display 13a, in particular by a user, who then has to enter them on the first pump unit 1b. This can be done via an input means 15b, in particular a control knob, which is connected to the microcomputer 5b. Also, the first pump unit 1 b has a display 10b with a display 13b, on which the successively entered characters of the string can be displayed. It should be noted that the second pump unit also has an input means 15a, which also makes it possible to enter a character string there.

As an alternative to the optical reading of the display 13a by a user, a mobile optical reader 11 can be used that via a code scanner 12 or a CCD camera 12 has. A mobile reading device 11 is particularly suitable if the configuration and operating data are encoded in a graphic code and displayed on the display 13a, since in this case it is no longer possible to human read the encoded data.

FIG. 3 thus shows an alternative variant for the optical reading of the coded configuration and operating data, in which these are displayed as a graphic code on the display 13a of the display 10a. If the optical reader 11 has read in the code, it can decode the configuration and operating data and send it to the pump electronics 3b of the first pump unit 1b in decoded form. Alternatively, the decoding of the data within the

Pump electronics 3b of the first pump unit 1 b carried out, the mobile reader 11 then the optically recorded data electrically wired and / or electromagnetically by radio to an interface 9 of the pump electronics 3b of the first pump unit 1 b zuleitet.

According to this variant, the first pump unit 1b has a decoding unit which may be a separate electronic unit of the pump electronics 3b or may be part of the microcomputer 5b. The decoding unit then decodes the encoded data accordingly, which is subsequently transferred from the microcomputer 5b to the

Operating memory 4b are stored. If the decoding already in the

Reader 11 is done, the microcomputer 5b can store the decoded configuration and operating data directly into the operating memory 4b.

All of these variants make it possible to easily transfer configuration and / or operating data of a second pump unit to a first pump unit, so that only a minimal amount of time and no special knowledge about the configuration of the pump unit 1 b is required.

Claims

claims

1. Method of configuring a first electromotive

 Pump unit (1 b) with configuration data, characterized in that configuration data and / or operating data of a second

 Pump unit (1 a) in a non-volatile memory unit (6, 6 a) pump electronics (3 a) of the second pump unit (1 a) stored and transferred from the second pump unit (1 a) to the first pump unit (1 b), which they in its pump electronics (3b) takes over.

2. The method according to claim 1, characterized in that the first

 Pump unit (1 b) takes over the configuration data in its operating software and / or from the operating data by means of a

 Operating data evaluation software gains configuration data and transfers this into its operating software.

3. The method according to claim 1 or 2, characterized in that the

 Storage unit (6) in the second pump unit (1 a) removably inserted memory module (6), which transported from the second pump unit (1 a) to the first pump unit (1 b) and with the

 Pump electronics (3b) of the first pump unit (1 b) is pluggable connected.

4. The method according to claim 3, characterized in that the first

Pump unit (1 b) reads out the configuration data and / or operating data from the memory module (6) and stores for controlling and / or regulating its drive unit (2b) in a memory unit (4b) of its pump electronics (3b).

5. The method according to claim 1 or 2, characterized in that an RFID (Radio Frequency Identification) transponder (7a) of the second

 Pump unit (1 a) reads the configuration data and / or operating data from the memory unit (6a) and transmits by radio.

6. The method according to claim 5, characterized in that the

 Memory unit (6a) is part of the RFI D transponder (7a) and the

 Storage of the configuration data and / or operating data directly into this memory unit (6a) of the RFID transponder (7a) takes place.

7. The method according to claim 5 or 6, characterized in that a

 mobile RFI D reader (8) receives the transmitted configuration data and / or operating data and forwards to the first pump unit (1 b), which receives them and for controlling and / or regulating his

 Drive unit (2b) in a memory unit (4b) of its pump electronics (3b) stores.

8. The method according to any one of claims 5, 6 or 7, characterized in that an RFI D reader (7b) of the first pump unit (1 b) the

 transmitted configuration data and / or operating data receives and control and / or regulation of its drive unit (2b) in a

 Memory unit (4b) of its pump electronics (3b) stores.

9. The method according to claim 1 or 2, characterized in that the

 Configuration data and / or operating data encrypted on one

 controllable display (10a, 13a) of the pump electronics (3a) of the second pump unit (1 a) are displayed, wherein the encrypted

 Configuration data and / or operating data read and encrypted or decrypted on the first pump unit (1 b) are entered, which it stores for controlling and / or regulating its drive unit (2b) in a memory unit (4b) of its pump electronics (3b).

10. The method according to claim 9, characterized in that the

Configuration data and / or operating data on the part of the second Pump unit (1a) are scrambled in a string (14) or in a two- or multi-dimensional graphic code.

11. The method according to claim 10, characterized in that the

 Transmission by optical reading of the code by means of a mobile optical code reading device (11), wherein the reading device (11) the

 Transfer configuration data and / or operating data to the pump electronics (3b) of the first pump unit (1 b).

12. The method according to claim 10 or 11, characterized in that the

Configuration data and / or operating data on the part of the first

 Pump unit (1 b) and / or decoded by the reader (11).

13. The method according to any one of the preceding claims, characterized in that the configuration data parameter value settings and / or

 at least one function setting of the first pump unit (1 b).

14. The method according to any one of the preceding claims, characterized in that the storage of the configuration data during commissioning of the second pump unit (1 a) takes place, and / or

 that the storage of the configuration data and / or operating data after some time after startup during operation of the second pump unit (1 a), at certain fixed times and / or occurs periodically.

15. pump unit (1a, 1b) with an electromotive drive unit (2a, 2b) and a pump electronics (3a, 3b) for controlling and / or regulating the drive unit (2a, 2b), characterized in that the

 Pump electronics (3a, 3b) a slot with a removable

plug-in memory module (6), wherein the pump unit (a, 1 b) is configured to store configuration data from its operating software (3b) and / or operating data of its operation on the memory module (6) or configuration data and / or operating data from the memory module ( 6) and to take over into its pump electronics (3b).

16. Pump unit (1a, 1b) according to claim 15, characterized in that the slot and / or the memory module (6) from outside the pump electronics (3a, 3b) is accessible.

17. pump unit (1 a, 1 b) according to claim 15 or 16, characterized

 in that the slot and / or the memory module (6) can be closed by a removable cover, in particular sealing

 is closable.

18. Pump unit (1a, 1b) according to one of claims 15 to 17, characterized in that the slot is a receptacle for an SD card, MMC card or SIM card or a USB socket.

19. Pump unit (1a) with an electromotive drive unit (2a, 2b) and a pump electronics (3a) for controlling and / or regulating the drive unit (2a) with a non-volatile memory unit (6a), characterized in that in the memory unit ( 6a) configuration data and / or operating data are stored and the pump electronics (3a) comprises a particular passive RFID transponder (7a), the

 Memory unit (6) read out and the configuration data and / or

 Operating data can be transmitted by radio.

20. The method according to claim 19, characterized in that the

 Memory unit (6a) is part of the RFI D transponder (7a).

21 pump unit (1 b) with an electric motor drive unit (2b) and a pump electronics (3b) for controlling and / or regulating the

 Drive unit (2b) with an operating or working memory (4b), characterized in that the pump electronics (3b) comprises an RFI D reader (7b), by means of which emitted configuration data and / or operating data of an RFI D transponder (7a) receivable are, and the

Pump electronics (3b) is adapted to store received configuration data and / or operating data for controlling and / or regulating the drive unit (2b) in the operating or main memory (4b).

22. Pump unit (1 a) with an electric motor drive unit (2 a) and a pump electronics (3 a) for controlling and / or regulating the

 Drive unit (2a) with a non-volatile memory unit (6a), characterized in that the pump electronics (3a) an encoding unit for encoding configuration data and / or operating data to a

 Character string (14) and / or to a graphic code and a display (10a, 13a) with a display (13a) for displaying the character string (14) or the graphic code, wherein the coded configuration data and / or operating data in the memory unit ( 6a) are storable.

23. Pump unit (1 a) according to claim 22, characterized in that the

Memory unit (6a) is part of a display control of the display (10a).

24. pump unit (1 b) with an electromotive drive unit (2b) and a pump electronics (3b) for controlling and / or regulating the

 Drive unit (2b) with an operating memory (4b), characterized

 in that the pump electronics (3a) has a decoding unit for decoding encoded configuration data and / or operating data, wherein the pump electronics (3b) is set up to decode the decoded

 Configuration data and / or operating data for the control and / or

 Control of the drive unit (2b) in the operating memory (4b) store.