Grundfos CIU 300 Functional Profile And User Manual

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GRUNDFOS INSTRUCTIONS

Grundfos CIU 300

BACnet MS/TP for Grundfos Hydro MPC, Control MPC and Multi-E

Functional proﬁle and user manual

Original installation and operating instructions.

CONTENTS

1. Symbol used in this document 3

2. Introduction 3

2.1 About this functional profile 3

2.2 Assumptions 3

2.3 Definitions and abbreviations 3

2.4 System diagram 4

2.5 Specifications 5

3. BACnet interface 6

3.1 BACnet bus topology 6

3.1.1 Line termination resistors 6

3.1.2 Bias resistors 6

3.2 CIM 300 BACnet module 7

3.3 Connecting to the BACnet network 7

3.4 Setting the BACnet transmission speed 7

3.4.1 DIP switch settings 7

3.5 Selecting the Device Object Instance Number 7

3.5.1 Default Instance Number 8

3.5.2 Custom Instance Number 8

3.6 Selecting the Device Object Name 8

3.7 Selecting the BACnet MAC address 8

3.8 Termination resistor 8

3.9 Cable length 8

4. LEDs 9

4.1 LED1, BACnet MS/TP communication 9

4.2 LED2, internal communication 9

5. Supported services 10

5.1 Data sharing services 10

5.2 Device management services 10

6. Object overview 11

6.1 Device Object 11

6.2 Binary inputs 12

6.3 Binary outputs 13

6.4 Multistate inputs 13

6.5 Multistate outputs 14

6.6 Analog inputs 15

6.7 Analog outputs 16

6.8 Analog values 16

7. Detailed descriptions 17

7.1 Control modes 17

7.2 Setpoint 18

7.2.1 Setpoint examples 18

7.3 BACnet communication watchdog 18

7.4 Fault monitoring and resetting 18

7.5 Fault simulation example 18

7.6 Control via BACnet 19

7.7 Product simulation 19

8. Commissioning 20

8.1 Step-by-step guide to hardware setup (CIU 300) 20

9. Fault finding 21

9.1 LED status 21

9.2 BACnet faults 21

10. BACnet telegrams 22

10.1 BACnet MS/TP telegram overview 22

10.2 Telegram types 22

11. Grundfos alarm and warning codes 23

12. BACnet MAC address 25

1. Symbol used in this document

2. Introduction

2.1 About this functional profile

This functional profile describes the CIU 300 (BACnet Communication Interface Unit 300) for the following Grundfos booster systems:

• Grundfos Hydro MPC (CU 351)

• Grundfos Control MPC (CU 351)

• Grundfos Hydro Multi-E. The object lists for Hydro MPC and Control MPC are identical, so in

the following, only Hydro MPC is mentioned. If not specifically mentioned, Hydro MPC and Hydro Multi-E are referred to as "booster".

The data in this document are subject to change without prior notice. Grundfos cannot be held responsible for any problems caused directly or indirectly by using information in this functional profile.

2.2 Assumptions

This functional profile assumes that the reader is familiar with commissioning and programming BACnet devices. The reader should have some basic knowledge of the BACnet protocol and technical specifications. It is also assumed that an existing BACnet MS/TP network is present.

2.3 Definitions and abbreviations

Note

Notes or instructions that make the job easier and ensure safe operation.

CIM

Communication Interface Module, a Grundfos add-on module

CIU

Communication Interface Unit, a Grundfos box for CIM modules

CRC

Cyclic Redundancy Check, a data error

detection method CU 351 Grundfos Control Unit 351 Device A node on the BACnet MS/TP network

GENIbus

Proprietary Grundfos fieldbus standard

based on RS-485

Inter-network

A set of two or more BACnet networks

interconnected by routers LED Light Emitting Diode

MAC

Media Access Control, a sublayer of

the data communication protocol MPC Multi-Pump Controller

MS/TP

Master-Slave / Token-Passing, a data

protocol used for BACnet RS-485

Router

A device that connects two or more

networks at the network layer Transmission speed Bits transferred per second

Trunk cable

Main RS-485 cable on a BACnet MS/TP

network

2.4 System diagram

The system diagram gives an overview of how to connect the CIM/CIU 300 to the Grundfos booster system that is to be connected to a BACnet MS/TP network.

The CIU 300 solution is a box with a power supply module and a CIM 300 BACnet module. It can either be mounted on a DIN rail or on a wall. It is used in conjunction with Grundfos Hydro MPC, Control MPC and Multi-E.

Fig. 1 CIU 300 solution for Hydro MPC and Hydro Multi-E

Note

The CU 351 must have an external GENIbus module installed to communicate with the CIU 300 BACnet unit.

TM04 6037 4709

Grundfos Hydro MPC and Multi-E connected to CIU 300

GENIbus

RS-485

GENIbus

RS-485

BACnet

MS/TP

Hydro Multi-E

Hydro MPC

CIU 300

2.5 Specifications

General data Description Comments

GENIbus visual diagnostics LED2

Red/green status LED. See section

4.2 LED2, internal communication

. Communication Interface Unit (CIU 300) Power supply 24-240 V AC/DC Located in the CIU 300. GENIbus connection type RS-485 GENIbus wire configuration Three-wire + screen Conductors: A, B and Y. BACnet Data protocol BACnet MS/TP

BACnet connector Screw-type terminal

3 pins. See section

3.2 CIM 300 BACnet module

BACnet connection type RS-485

BACnet wire configuration Two-wire + ground

Conductors: Plus, Minus and Ground. See section

3.3 Connecting to the BACnet network

Maximum cable length [m] 1200 Equals 4000 ft

MAC address 0-127

Set via rotary switches SW6 and SW7. See section

3.7 Selecting the BACnet MAC address

Line termination On or Off

Set via DIP switches SW1 and SW2. See section

3.8 Termination resistor

Supported transmission speeds [bits/s] 9600, 19200, 38400, 76800

Set via DIP switches SW4 and SW5. See section

3.4 Setting the BACnet transmission

speed

. Data bits 8 Fixed value. Stop bits 1 Fixed value. Parity None Fixed value.

BACnet visual diagnostics LED1

Red/green status LED. See section

4.1 LED1, BACnet MS/TP communication

. Maximum number of BACnet devices 32 Using repeaters, this number can be increased. Grundfos BACnet vendor ID 227 BACnet segmentation support No

Character set support ANSI X3.4

Base definition for the widely used character code

known as ASCII. BACnet device profile B-ASC BACnet Application-Specific Controller. BACnet MS/TP master Yes The CIM/CIU 300 is a BACnet MS/TP master device. Manual slave address binding No

3. BACnet interface

3.1 BACnet bus topology

The Grundfos CIM/CIU 300 is connected as a BACnet MS/TP master directly to the BACnet MS/TP network.

Fig. 2 Example of BACnet MS/TP network

BACnet MS/TP is a multi-master system, meaning that there can be more than one master on the network. It uses a token to control access to the bus network. A master node may initiate the transmission of a data telegram when it holds the token. Both master and slave nodes may transmit data telegrams in response to requests from master nodes, but slaves never hold the token. Master nodes pass the token between them.

A BACnet MS/TP segment is a single contiguous medium to which BACnet nodes are attached. Segments can be connected by use of repeaters or bridges, thus forming networks.

Multiple networks may be interconnected by BACnet routers to form a BACnet inter-network.

3.1.1 Line termination resistors Line termination must be connected at each of the two ends of the

segment medium. The CIM/CIU 300 has optional line termination resistor on board.

3.1.2 Bias resistors At least one set, and no more than two sets, of network bias

resistors must exist for each segment so that an undriven communications line will be held in a guaranteed logical one state. The bias provides a reliable way for stations to detect the presence or absence of signals on the line. An unbiased line will take an indeterminate state in the absence of any driving node.

The CIM/CIU 300 has no bias resistors.

TM04 4274 1009

Master

Slave

Master

Slave

Master

Slave

LT = Line Termination BR = Bias Resistors

3.2 CIM 300 BACnet module

Fig. 3 CIM 300 BACnet module

3.3 Connecting to the BACnet network

A screened, twisted-pair cable must be used.

The ANSI/ASHRAE BACnet standard states that the cable screen must only be earthed at one end of the segment to prevent earth fault currents.

3.4 Setting the BACnet transmission speed

The transmission speed must be set correctly before the CIM 300 is ready to communicate on the BACnet MS/TP network. DIP switches SW4 and SW5 are used to set the transmission speed. The default transmission speed is 9600 bits/s, but higher speeds are recommended for better data throughput. All devices on the BACnet MS/TP network must communicate at the same transmission speed.

Fig. 4 BACnet transmission speed settings

3.4.1 DIP switch settings Available transmission speeds in bits/s: 9600, 19200, 38400 and

76800. Use DIP switches SW4 and SW5 to select the desired speed.

The default transmission speed is 9600 bit/s, as per the BACnet MS/TP standard. The transmission speed will be effective immediately after setting the values of the DIP switch.

3.5 Selecting the Device Object Instance Number

The Device Object Identifier value consists of two components:

• a 10-bit Object Type (bits 22 to 31)

• a 22-bit Instance Number (bits 0 to 21).

Fig. 5 Bit numbers

The Object Type is fixed and determines that it is a Device Object. The Instance Number is a numeric code that is used to identify the device. It must be unique inter-network-wide, i.e. on all interconnected networks.

The CIM 300 offers two different approaches to setting the BACnet Device Object Instance Number: default and custom, both described in the following subsections.

TM04 1697 0908

Pos. Designation Description

1 Plus

BACnet Plus terminal (RS-485 positive data signal)

2 Minus

BACnet Minus terminal (RS-485 negative data signal)

3 Ground BACnet Ground terminal

4 SW1/SW2

On/off switches for termination resistor

5 SW3/SW4/SW5

Switches for selecting the BACnet transmission speed and the default or custom Device Object Instance Number

6LED1

Red/green status LED for BACnet communication

7LED2

Red/green status LED for internal communication between the CIM 300 and the Grundfos booster

8SW6

Hexadecimal rotary switch for setting the BACnet MAC address (four most significant bits)

9SW7

Hexadecimal rotary switch for setting the BACnet MAC address (four least significant bits)

1 2 34 5 6 7

BACnet terminal Recommended colour Data signal

Plus Red Positive Minus Green Negative Ground Grey Ground

TM04 1710 0908

Transmission speed [bits/s]

SW4 SW5

9600 OFF OFF 19200 OFF ON 38400 ON OFF 76800 ON ON

TM04 5977 4509

SW4 SW5

31 22

10 bits 22 bits

21 0

Object type Instance Number

...

3.5.1 Default Instance Number By default, the CIM 300 uses a pre-defined Device Object Instance

Number, which is 227XXX where XXX is the BACnet MAC address. This gives an Instance Number range of 227000 to 227127. See section

3.7 Selecting the BACnet MAC address

for more

information on MAC addresses. Example:

The BACnet MAC address is set to 20 via the hexadecimal rotary switches, so the Device Object Instance Number is 227020.

3.5.2 Custom Instance Number To use the complete Instance Number range, set the new Instance

Number with the BACnet object Custom Device Object Instance Number (AV, 0), and set SW3 to ON. This will immediately set the new Device Object Instance Number. See fig. 6 for DIP switch location.

Fig. 6 Device Object Instance Number

The default Present_Value of the Custom Device Object Instance Number is 231.

Example: The Present_Value of Custom Device Object Instance Number

(AV, 0) is 231, so the Device Object Instance Number is 231.

3.6 Selecting the Device Object Name

The property Device_Name is a character string that must be unique inter-network-wide. By default, the name will be constructed as "Grundfos - XXXXXX" where XXXXXX is the current Device Object Instance Number as described in section

3.5 Selecting the Device Object Instance Number

Example: The Device Object Instance Number is 227001, so the Device

Object Name is "Grundfos - 227001". If a new name is selected, it will be stored in the device and

replace the default naming scheme.

3.7 Selecting the BACnet MAC address

To set the BACnet MAC address, use the two hexadecimal rotary switches (SW6 and SW7).

The value must be within the range of 0 to 127. An illegal value will result in a MAC address of 0.

Fig. 7 Setting the BACnet MAC address

For a complete overview of BACnet addresses, see section

12. BACnet MAC address

3.8 Termination resistor

A termination resistor for line termination is fitted on the CIM 300 and has a value of 120 Ω. It should be cut in if the CIM 300 is set as the last station on the network.

The CIM 300 has two DIP switches (SW1 and SW2) for cutting the termination resistor in and out. Figure 8 shows the DIP switches in cut-out state.

Fig. 8 Cutting the termination resistor in and out

Default setting: Termination resistor cut-out.

3.9 Cable length

The maximum recommended cable length within a BACnet MS/TP segment is 1200 metres (4000 ft) with 0.82 mm

(AWG 18)

cable. The connection between the BACnet modules must be made by

use of a screened, twisted-pair cable with a characteristic impedance between 100 and 130 Ω.

TM04 1709 0908

Device Object Instance Number SW3

Default (227000 + BACnet MAC address) OFF Custom, set with object (AV, 0) ON

Note

The Present_Value of Custom Device Object Instance Number cannot be 4194303, as this is a reserved value.

TM04 1706 0908

Note

The BACnet MAC address must be set decimally from 0 to 127 and must be unique on the BACnet MS/TP segment.

SW3

SW6 SW7

TM04 1701 0908

Status SW1 SW2

Cut-in ON ON

Cut-out

OFF OFF

ON OFF

OFF ON

SW1 SW2

4. LEDs

The CIM 300 BACnet module has two LEDs.

• Red/green status LED (LED1) for BACnet MS/TP communication

• Red/green status LED (LED2) for internal communication between the CIM 300 and the Grundfos booster.

4.1 LED1, BACnet MS/TP communication

4.2 LED2, internal communication

Status Description

Off No communication. Flashing green Communication active. Flashing red Fault in the BACnet communication.

Permanently red

Fault in the CIM 300 BACnet configuration.

Status Description

Off

The CIM 300 has been switched off or is starting up

Flashing red

No internal communication between the CIM 300 and the booster.

Permanently red

The CIM 300 does not support the specific booster version.

Permanently green

Internal communication between the CIM 300 and the booster is OK.

Note

During start-up, there may be a delay of up to 5 seconds before the LED status is updated.

5. Supported services

BACnet Interoperability Building Blocks (BIBBs) are collections of one or more BACnet services. These are described in terms of an "A" and a "B" device. Both devices are nodes on a BACnet inter-network. In most cases, the "A" device will act as the user of data (client), and the "B" device will be the provider of this data (server).

The CIM/CIU 300 is a BACnet Application-Specific Controller (B-ASC) with a few additional services.

5.1 Data sharing services

5.2 Device management services

Name BACnet BIBB code Notes Initiate Execute

ReadProperty DS-RP-B The CIM/CIU 300 can be a provider of data. X

ReadPropertyMultiple DS-RPM-B

The CIM/CIU 300 can be a provider of data and return multiple values at one time.

WriteProperty DS-WP-B

The CIM/CIU 300 allows a value to be changed over the network.

WritePropertyMultiple DS-WPM-B

The CIM/CIU 300 allows multiple values to be changed over the network.

SubscribeCOV

DS-COV-B

The CIM/CIU 300 can be a provider of "Change Of Value" data. It supports up to 10 simultaneous COV subscriptions. Subscription lifetime can be limited or unlimited.

X ConfirmedCOVNotification X UnconfirmedCOVNotification X

Name BACnet BIBB code Notes Initiate Execute

Who-Is

DM-DDB-A

The CIM/CIU 300 can seek information about device attributes of other devices and interpret device announcements.

I-Am X

Who-Is

DM-DDB-B

The CIM/CIU 300 can provide information about its device attributes and responds to requests to identify itself.

X I-Am X Who-Has

DM-DOB-B

The CIM/CIU 300 can provide address information about its objects upon request.

X I-Have X

DeviceCommunicationControl DM-DCC-B

The CIM/CIU 300 can respond to communication control requests. It supports both limited and unlimited duration.

6. Object overview

6.1 Device Object

The following properties are supported in the Device Object (available for all booster types).

Property identifier Data type Notes Access

Object_Identifier BACnetObjectIdentifier

See section

3.5 Selecting the Device Object Instance

Number

Object_Name CharacterString See section

3.6 Selecting the Device Object Name

.W Object_Type BACnetObjectType DEVICE. R System_Status BACnetDeviceStatus OPERATIONAL. R Vendor_Name CharacterString Grundfos. R Vendor_Identifier Unsigned16 227. R

Model_Name CharacterString

Will show the Grundfos booster model to which the CIM/CIU 300 is connected.

Firmware_Revision CharacterString Revision of the firmware in the CIM/CIU 300. R Application_Software_Version CharacterString Software build date, DD-MM-YYYY. R

Location CharacterString

The user can enter a location here (maximum 200 characters).

Description CharacterString

The user can enter a description here (maximum 200 characters).

Protocol_Version Unsigned Actual version of the BACnet protocol. R Protocol_Revision Unsigned Actual revision of the BACnet protocol.R

Protocol_Services_Supported BACnetServicesSupported

Indicates which standardised protocol services are supported.

Protocol_Object_Types_Supported BACnetObjectTypesSupported

Indicates which standardised protocol object types are supported.

Object_List

BACnetARRAY[N]of BACnetObjectIdentifier

An array of objects available. R

Max_APDU_Length_Accepted Unsigned

The maximum number of bytes that may be contained in a single APDU. Fixed to 480.

Segmentation_Supported BACnetSegmentation

Indicates if segmentation of messages is possible. Will always read NO_SEGMENTATION.

APDU_Timeout Unsigned Indicates the amount of time in ms before timeout. R Number_Of_APDU_Retries Unsigned Maximum number of times an APDU is to be retransmitted. R

Max_Master Unsigned

Specifies the highest possible MAC address for master nodes and must be between 1 and 127. The default value is 127, but this value can be lowered by the user. The Max_Master value must be higher than or equal to the highest MAC address used by a master node in an MS/TP network.

Max_Info_Frames Unsigned

Specifies the maximum number of information frames that are sent before the token is passed on. Fixed to 1.

Device_Address_Binding List of BACnetAddress-Bindings Holds address bindings to other devices, if any. R Database_Revision Unsigned Logical revision number for the device database. R

6.2 Binary inputs

Binary objects that provide information from the Grundfos booster.

ID Object Name R/W Notes Multi-E MPC

BI, 0 Control source status R

Status of the actual control source. 0 = Local control 1 = Bus control.

BI, 2 Rotation status R

Rotation status. 0 = No rotation 1 = Rotation (one or more pumps running).

BI, 3 At minimum speed R

0 = Not running at minimum speed 1 = Running at minimum speed.

BI, 4 At maximum speed R

0 = Not running at maximum speed 1 = Running at maximum speed.

BI, 5 Standby pumps active R

0 = Standby pumps not active 1 = Standby pumps active.

BI, 6 Pressure relief active R

0 = Pressure relief not active 1 = Pressure relief active.

BI, 7 Soft pressure active R

0 = Soft pressure not active 1 = Soft pressure active.

BI, 8 Low flow boost active R

0 = Low flow boost not active 1 = Low flow boost active.

BI, 9 Low flow stop active R

0 = Low flow stop not active 1 = Low flow stop active.

BI, 10 Alternative setpoint active R

0 = Alternative setpoint not active 1 = Alternative setpoint active.

BI, 11 Digital input 1 status R

0 = Not active 1 = Active.

BI, 12 Digital input 2 status R

0 = Not active 1 = Active.

BI, 13 Digital input 3 status R

0 = Not active 1 = Active.

BI, 14 Digital output 1 status R

0 = Not active 1 = Active.

BI, 15 Digital output 2 status R

0 = Not active 1 = Active.

BI, 16 Subpump 1 presence R

0 = Subpump not present 1 = Subpump present.

BI, 17 Subpump 1 communication status R

0 = Communication OK 1 = Communication fault.

BI, 18 Subpump 2 presence R

0 = Subpump not present 1 = Subpump present.

BI, 19 Subpump 2 communication status R

0 = Communication OK 1 = Communication fault.

BI, 20 Subpump 3 presence R

0 = Subpump not present 1 = Subpump present.

BI, 21 Subpump 3 communication status R

0 = Communication OK 1 = Communication fault.

BI, 22 Subpump 4 presence R

0 = Subpump not present 1 = Subpump present.

BI, 23 Subpump 4 communication status R

0 = Communication OK 1 = Communication fault.

BI, 24 Subpump 5 presence R

0 = Subpump not present 1 = Subpump present.

BI, 25 Subpump 5 communication status R

0 = Communication OK 1 = Communication fault.

BI, 26 Subpump 6 presence R

0 = Subpump not present 1 = Subpump present.

BI, 27 Subpump 6 communication status R

0 = Communication OK 1 = Communication fault.

BI, 28 Fault simulation status R

Fault simulation status. 0 = Fault simulation disabled 1 = Fault simulation enabled.

6.3 Binary outputs

Binary objects for control of the Grundfos booster.

6.4 Multistate inputs

Objects that contain an enumeration value from the booster.

ID Object Name R/W Notes Multi-E MPC

BO, 0 Set control source W

Sets the control source. Set to 1 to enable control via BACnet. 0 = Local control (default) 1 = Bus control.

BO, 4 Reset fault W

Resets alarm if bus control is enabled. (Triggered on rising edge). 0 = No resetting (default) 1 = Resetting.

BO, 5 Fault simulation W

Enables fault simulation. 0 = Disabled (default) 1 = Enabled.

ID Object Name R/W Notes Multi-E MPC

MI, 0 Actual control mode R

Reads the current control mode. 1 = Constant speed 2 = Constant pressure 3 = Proportional pressure 4 = RESERVED 5 = Constant flow 6 = Constant temperature 7 = Constant level 8 = Constant percentage. See section

7.1 Control modes

for details

on the control modes.

MI, 1 Actual operating mode R

Reads the current operating mode. 1 = Start (normal) 2 = Stop 3 = Minimum 4 = Maximum.

MI, 3 CIM status R

Reads the status of the CIM module, useful for fault finding. 1 = OK 2 = EEPROM fault 3 = Memory fault.

MI, 4 Subpump 1 control source R

1 = Buttons 2 = GENIbus 3 = GENIlink 4 = External control.

MI, 5 Subpump 2 control source R

1 = Buttons 2 = GENIbus 3 = GENIlink 4 = External control.

MI, 6 Subpump 3 control source R

1 = Buttons 2 = GENIbus 3 = GENIlink 4 = External control.

MI, 7 Subpump 4 control source R

1 = Buttons 2 = GENIbus 3 = GENIlink 4 = External control.

MI, 8 Subpump 5 control source R

1 = Buttons 2 = GENIbus 3 = GENIlink 4 = External control.

MI, 9 Subpump 6 control source R

1 = Buttons 2 = GENIbus 3 = GENIlink 4 = External control.

6.5 Multistate outputs

Objects that set an enumeration value in the booster.

ID Object Name R/W Notes Multi-E MPC

MO, 0 Set control mode W

Sets the control mode if bus control is enabled. 1 = Constant speed 2 = Constant pressure 3 = Proportional pressure 4 = RESERVED 5 = Constant flow 6 = Constant temperature 7 = Constant level 8 = Constant percentage. See section

7.1 Control modes

for details on the control modes. Note: Multi-E always runs constant pressure mode.

MO, 1 Set operating mode W

Sets the operating mode if bus control is enabled. 1 = Start (normal) 2 = Stop 3 = Minimum (MPC only) 4 = Maximum.

MO, 2 Product simulation W

Enables product simulation (for commissioning and testing purposes, can only be enabled when no physical booster is present). 1 = Disabled 5 = Hydro Multi-E 6 = Hydro MPC. See section

7.7 Product simulation

for details.

6.6 Analog inputs

Objects with measured values and status information from the booster.

X = Always available. S = Sensor required.

ID Object Name R/W Notes Unit Multi-E MPC

AI, 0 Fault code R

Grundfos fault code. See section

11. Grundfos alarm and warning codes

-XX

AI, 1 Warning code R

Grundfos warning code. See section

11. Grundfos alarm and warning codes

-XX

AI, 3 Capacity R Actual capacity value (process feedback). % X X AI, 4 Head R Actual system head/pressure. bar S S AI, 5 Flow R Actual system flow. m

/h S S AI, 6 Relative performance R Performance relative to maximum performance. % X X AI, 9 Actual setpoint R Actual setpoint. % X X AI, 10 Motor current R Actual motor current. A X AI, 13 Power R Total power consumption of the system. W X X AI, 15 Inlet pressure R System inlet pressure. bar S AI, 16 Remote pressure R Measured pressure at external sensor. bar S AI, 17 Level R Tank level. m S S AI, 20 Remote temperature R Temperature at external sensor. °C S S AI, 25 Auxiliary sensor input R Auxiliary sensor input. % S AI, 27 Runtime R Total operating time of the system. h X X AI, 30 Energy consumption R Total energy consumption of the system.kWhXX AI, 33 Ambient temperature R Ambient temperature. °C S AI, 34 Forward temperature R Flow-pipe temperature. °C S AI, 35 Return temperature R Return-pipe temperature. °C S AI, 36 Differential temperature R Differential temperature. °C S AI, 37 Outlet pressure R System outlet pressure. bar S AI, 38 Feed tank level R Actual level in the feed tank. m S AI, 39 Subpump 1 fault code R Fault code of subpump 1. - X X AI, 40 Subpump 1 runtime R Total operating time of subpump 1. h X X AI, 41 Subpump 1 speed R Actual speed of subpump 1. % X AI, 42 Subpump 2 fault code R Fault code of subpump 2. - X X AI, 43 Subpump 2 runtime R Total operating time of subpump 2. h X X AI, 44 Subpump 2 speed R Actual speed of subpump 2. % X AI, 45 Subpump 3 fault code R Fault code of subpump 3. - X X AI, 46 Subpump 3 runtime R Total operating time of subpump 3. h X X AI, 47 Subpump 3 speed R Actual speed of subpump 3. % X AI, 48 Subpump 4 fault code R Fault code of subpump 4. - X X AI, 49 Subpump 4 runtime R Total operating time of subpump 4. h X X AI, 50 Subpump 4 speed R Actual speed of subpump 4. % X AI, 51 Subpump 5 fault code R Fault code of subpump 5. - X X AI, 52 Subpump 5 runtime R Total operating time of subpump 5. h X X AI, 53 Subpump 5 speed R Actual speed of subpump 5. % X AI, 54 Subpump 6 fault code R Fault code of subpump 6. - X X AI, 55 Subpump 6 runtime R Total operating time of subpump 6. h X X AI, 56 Subpump 6 speed R Actual speed of subpump 6. % X

6.7 Analog outputs

Object for setting a new setpoint in the booster.

6.8 Analog values

Objects for configuration of the CIM/CIU 300 and/or the booster.

ID Object Name R/W Notes Unit Multi-E MPC

AO, 0 Set setpoint W

Sets the booster setpoint if bus control is enabled. A value of 0 does not imply a stop. See section

7.2 Setpoint

%X X

ID Object Name R/W Notes Multi-E MPC

AV, 0 Custom device object instance number R/W

Value for Custom Device Object Instance Number. Used in conjunction with DIP switch SW3. See section

3.5 Selecting the Device Object Instance

Number

. Present_Value range: 0-0x3FFFFE. Default Present_Value: 0xE7.

AV, 1 BACnet watchdog R/W

Time in seconds before BACnet communication watchdog times out, and sets the booster to use its local settings. See section

7.3 BACnet communication watchdog

. 0 = Disabled (default) Set to a value between 5 and 3600 to enable.

AV, 4 Simulation event code R/W

Event code to simulate. The following event code values are available for simulation (among others): 000 = No alarm 003 = External fault 010 = Pump communication alarm 089 = Closed-loop feedback sensor signal fault 088 = General (meas.) sensor signal fault 203 = All pumps in alarm 210 = Pressure high 211 = Pressure low 214 = Water shortage 231 = No Ethernet address from DHCP server.

AV, 5 Simulation device type R/W

Device type of simulated event. 0 = Controller 2 = Pump 3 = IO 351 4 = Primary sensor 7 = IO 351 8 = System 9 = Analog input 10 = Pilot pump 11 = Limit-exceeded function.

AV, 6 Simulation device number R/W

Device number of simulated event. If the device type is "Pump", the device number indicates the pump number [1-6]. If the device type is "Analog input", the device number indicates the sensor that generated the event [1-7].

AV, 7 Simulation event action type R/W

The associated action to the event. 0 = Go to operating mode "Stop". 1 = Go to operating mode "Stop" (delay). 2 = Go to operating mode "Minimum". 3 = Go to operating mode "User-defined". 4 = Go to operating mode "Maximum". 5 = Set pumps in source mode to "Local control". 6 = No action (warning only). 7 = Go to operating mode "Emergency run".

AV, 8 Simulation event reset type R/W

Resetting type for simulated event. Manual or automatic. 0 = Manual resetting 1 = Automatic resetting.

7. Detailed descriptions

7.1 Control modes

H = Pressure (Head) Q = Flow

Control modes Description Illustration

Constant speed

Open loop The setpoint of the booster system will be interpreted as setpoint for the system performance.

The setpoint value is a percentage of the maximum performance of the subpumps.

No sensor is required.

Constant pressure

Closed loop The setpoint of the booster system will be interpreted as setpoint for the pressure.

The controller in the booster system will change the booster speed so that the pressure is constant, regardless of the flow.

A pressure sensor is required.

Constant flow Constant level Constant temperature Constant percentage

Closed loop Constant flow, constant level, constant temperature or constant percentage can be obtained by replacing the main pressure sensor with another sensor, e.g. a flow sensor is needed for flow control, a level sensor is needed for level control and a temperature sensor is needed for temperature control.

Constant flow is illustrated to the right.

Proportional pressure

Closed loop The setpoint of the booster system will be interpreted as basic setpoint for the proportional-pressure mode (the black dot in the illustration).

A pressure sensor is required.

7.2 Setpoint

This object accepts values ranging from 0 to 100 (0 % to 100 %). This is illustrated in fig. 9.

The setpoint value can represent speed, pressure, flow, etc., depending on the selected control mode.

A setpoint of 0 does not imply a stop.

Fig. 9 Setpoint

7.2.1 Setpoint examples Closed loop

If the control mode is set to Constant pressure (closed loop) and the pressure sensor is in the range of 0 to 10 bar, a setpoint of 80 % will result in an effective setpoint of 8 bar.

If the sensor range was 0 to 16 bar, a 50 % setpoint would be 8 bar, a 25 % setpoint would be 4 bar, and so on.

Fig. 10 Constant pressure

Open loop If the control mode is set to Constant speed (open loop), the

setpoint is interpreted as setpoint for the booster performance.

Fig. 11 Constant speed

7.3 BACnet communication watchdog

A BACnet communication watchdog is implemented in the CIM/CIU 300. If no BACnet communication is detected for the time period defined by the BACnet watchdog object (AV, 1), and the control source of the booster is set to Bus control (BO, 0), the CIM 300 will make the booster run with the settings defined in local mode.

This functionality can be used to define the booster behaviour in case of a BACnet communication breakdown. Before enabling the watchdog, the local booster settings should be made with either a Grundfos PC Tool or the Grundfos R100 remote control (for Multi-E only). This ensures that the booster behaves as expected if the BACnet communication breaks down.

When BACnet communication is re-established after a watchdog timeout, the booster will run with the remote settings again.

When the Present_Value of the AV, 1 object is set to 0, the watchdog is disabled (default). To enable the watchdog, set the Present_Value to [5-3600] seconds.

7.4 Fault monitoring and resetting

This example shows how to monitor faults or warnings in the booster and how to manually reset a fault.

The Fault code object (AV, 0) and the Warning code object (AV, 1) can both hold a Grundfos-specific fault code. See section

11. Grundfos alarm and warning codes

for code interpretation.

Warnings are notifications only, and a warning will normally not stop the booster system.

If a fault is to be manually reset, use the Reset fault object (BO, 4). When the Present_Value of this object is set to 1, a Reset fault command is sent to the device.

7.5 Fault simulation example

Fault simulation can be helpful for testing alarm behaviour for a Hydro MPC booster system. The system will behave exactly as if a real alarm was present.

This example shows how to simulate a "Pressure high" alarm on a Hydro MPC that will result in a stop of all pumps, and require manual resetting.

• Set "Simulation event code" (AV, 4) to 210 (Pressure high).

• Set "Simulation device type" (AV, 5) to 8 (System).

• Set "Simulation device number" (AV, 6) to 1 (System).

• Set "Simulation event action type" (AV, 7) to 0 (Stop).

• Set "Simulation event reset type" (AV, 8) to 0 (Manual resetting).

• Set "Fault simulation" (BO, 5) to 1 (Enabled).

• The CU 351 will now enter into the system mode "Event action", and in this case stop all pumps, and the red LED on the CU 351 will be on. On the CU 351 display, the "Pressure high" alarm is indicated.

• Read "Fault simulation status" (BI, 28), and see that it is set to 1 (Fault simulation enabled).

• Remove the simulated alarm settings by setting "Fault simulation" (BO, 5) to 0 (Disabled).

• Reset the alarm via the CU 351 display or via the BACnet object "Reset fault" (BO, 4), and the CU 351 will go back to normal operation.

Note

The setpoint is a percentage of the maximum setpoint or sensor maximum (max. = 100 %).

TM04 2373 2508TM04 2371 2508TM04 2372 2508

Sensor maximum

Minimum setpoint

Effective setpoint

0 % 100 %Setpoint [%]

10 bar

8 bar

0 % 100 % 80 %

Maximum booster performance

50 % system performance

0 % 100 %

50 %

7.6 Control via BACnet

This example shows how to set a Hydro MPC to 50 % setpoint, constant-pressure mode and bus control.

Before enabling control via BACnet, values for setpoint, control mode and operating mode should be set.

• Enable bus control via the CU 351 display (settings/secondary functions/control source, and select "controlled from bus").

• Set operating mode with Multistate output 1 (MO, 1). In this example, the value for operating mode should be 1 (Start).

• Set control mode with Multistate output 0 (MO, 0). A value of 2 corresponds to Constant pressure.

• Set the setpoint to a value of 50 with Analog output 0 (AO, 0). See section

7.2 Setpoint

for details on setpoint.

• To enable bus control via BACnet, set the Binary output 0 (BO, 0) to a value of 1.

Now the Hydro MPC should be running at 50 % in constantpressure mode with bus control.

7.7 Product simulation

Product profile simulation (booster simulation) can be useful for testing and pre-commissioning purposes. It is possible to simulate a booster profile when using a CIU 300 that is not connected to any product. The CIU 300 will behave as if a booster was connected on the GENIbus, even if that is not the case. The objects supported by the simulated product will be available, although the data will only be dummy values that do not simulate real booster behaviour.

Product simulation is enabled by setting the Multistate output object "Product simulation" (MO, 2):

Product to simulate Value

Disabled (no simulation) 1 Multi-E 5 Hydro MPC (CU 351) 6

Note

Product simulation will always be disabled on power-up.

Note

If a physical booster is detected on GENIbus at power-up, it will not be possible to enable product

simulation.

8. Commissioning

8.1 Step-by-step guide to hardware setup (CIU 300)

Step Action

1 Complete the booster configuration, e.g. sensor configuration. 2 Select the BACnet MAC address (0-127) on the CIM 300. See section

3.7 Selecting the BACnet MAC address

3 Select the transmission speed of the CIM 300. See section

3.4 Setting the BACnet transmission speed

4 Select Device Object Instance Number. See section

3.5 Selecting the Device Object Instance Number

5 If necessary, set line termination. See section

3.8 Termination resistor

. 6 Connect the GENIbus cable from the CIU 300 to the booster. 7 Connect the necessary cables from the CIU 300 to the BACnet network. See section

3.3 Connecting to the BACnet network

8 Connect the power supply cable to the CIU 300, and switch it on.

Confirm that the GENIbus LED is constantly green and that the BACnet LED is either off or flashing green (indicating communication). See section

4. LEDs

The CIU 300 is now configured and ready.

9. Fault finding

9.1 LED status

Faults in a CIM/CIU 300 can be detected by observing the status of the two communication LEDs. See the table below.

9.2 BACnet faults

Fault (LED status) Possible cause Remedy

1. Both LEDs (LED1 and LED2) remain off when the power supply is connected, and 5 seconds have passed.

a) The CIM 300 is defective. Replace the CIM 300.

2. The LED for internal communication (LED2) is flashing red.

a) No internal communication

between the CIM/CIU 300 and the Grundfos booster.

• Check the cable connection between the booster and the CIU 300.

• Check that the individual conductors have been fitted correctly.

• Check the power supply to the booster.

3. The LED for internal communication (LED2) is constantly red.

a) The CIU 300 does not support the

connected booster.

Contact the nearest Grundfos company.

4. The BACnet LED (LED1) is constantly red.

a) Fault in the CIM 300 BACnet

configuration.

• Ensure that the BACnet MAC address has a valid setting. See section

3.7 Selecting the BACnet MAC address

• Ensure that the Device Object Instance Number is within the allowed range. See section

3.5 Selecting the Device Object Instance

Number

5. The BACnet LED (LED1) is flashing red.

a) Fault in the BACnet communication

(cyclic redundancy check).

• Check the transmission speed (switches SW4 and SW5). See section

3.4 Setting the BACnet transmission

speed

• Check the cable connection between the CIM 300 and the BACnet network.

• Check the termination resistor settings (switches SW1 and SW2). See section

3.8 Termination resistor

Fault Possible cause Remedy

1. The CIM/CIU 300 does not communicate on the BACnet MS/TP network.

a) Configuration or wiring fault. Ensure that the cable between the BACnet MS/TP

devices is connected correctly. See section

3.3 Connecting to the BACnet network

Ensure that the BACnet MAC address and Device Object Instance Number are configured correctly and are unique on the network. See section

3.7 Selecting the BACnet MAC address

and

3.5 Selecting the Device Object Instance Number

for

address selection. Ensure that the transmission speed is configured

correctly. See section

3.4 Setting the BACnet transmission speed

Ensure that each end of the BACnet MS/TP trunk cable is terminated, if necessary. See section

3.8 Termination resistor

for line termination

of the Grundfos CIM/CIU 300. Ensure that the bus topology for

a BACnet MS/TP network is correct.

b) The CIM/CIU 300 is instructed to

not communicate on the BACnet network via the DeviceCommunicationControl service.

Use the Device Communication Control service to enable communication from the device.

2. The booster does not react to control commands from the bus.

a) The booster is running in local

mode.

• Set the booster to bus control by setting the Present_Value of BO, 0 to 1.

• Set bus control on the CU 351display (settings/ secondary functions/control source, and select "controlled from bus").

3. There are only a few BACnet objects available, and the GENIbus LED flashes red.

a) There is no communication

between the CIM 300 and the booster.

Ensure that the GENIbus cable between the CIM 300 and the booster is connected correctly. Ensure that the booster is switched on and able to communicate on GENIbus.

10. BACnet telegrams

10.1 BACnet MS/TP telegram overview

All BACnet MS/TP telegrams have the following format:

For BACnet MS/TP, the destination address and source address are MAC addresses. See section

3.7 Selecting the BACnet MAC address

A destination address of 255 (0xFF) denotes broadcast. The Length field specifies the length in bytes of the data field which must be between 0 and 501 bytes long.

10.2 Telegram types

The available telegram types are listed below.

Preamble Telegram type Destination Source Length Header CRC Data Data CRC (Pad)

2 bytes: 0x55 0xFF

1 byte 1 byte 1 byte

2 bytes,

MSB first

1 byte

Variable,

[0-501]

bytes

2 bytes,

LSB first

At most

1 byte

0xFF

Type Name Description

00 Token Used to pass network mastership to the destination device. 01 Poll for master Discovers the presence of other master devices on the network. 02 Reply to poll for master Used by a master to indicate a wish to enter the token ring. 03 Test request Used to initiate a loopback test. 04 Test response A reply to a test request telegram. 05 BACnet data, expecting reply Used for data transmission where a reply is expected. 06 BACnet data, not expecting reply Used for data transmission where no reply is expected. 07 Reply postponed Used by master devices to defer sending a BACnet data reply.

11. Grundfos alarm and warning codes

This is a general Grundfos alarm and warning code list.

Code Description Code Description Code Description

1 Leakage current 35

Gas in pump head, deaerating problem

76 Internal communication fault

2 Missing phase 36 Discharge valve leakage 77

Communication fault, twin-head

pump 3 External fault signal 37 Suction valve leakage 78 Fault, speed plug 4 Too many restarts 38 Vent valve defective 79 Functional fault, add-on module 5 Regenerative braking 40 Undervoltage 80 Hardware fault, type 2 6 Mains fault 41 Undervoltage transient 81 Verification error, data area (RAM)

7 Too many hardware shutdowns 42 Cut-in fault (dV/dt) 82

Verification error, code area (ROM,

FLASH)

8 PWM switching frequency reduced 45 Voltage asymmetry 83

Verification error, FE parameter

area (EEPROM) 9 Phase sequence reversal 48 Overload 84 Memory access error

10 Communication fault, pump 49 Overcurrent (i_line, i_dc, i_mo) 85

Verification error, BE parameter

area (EEPROM)

11 Water-in-oil fault (motor oil) 50

Motor protection function, general shutdown (mpf)

88 Sensor fault

Time for service (general service information)

51 Blocked motor/pump 89 Signal fault, (feedback) sensor 1

13 Moisture alarm, analog 52 Motor slip high 90 Signal fault, speed sensor

Electronic DC-link protection activated (ERP)

53 Kipped motor 91 Signal fault, temperature 1 sensor

Communication fault, main system (SCADA)

Motor protection function, 3 sec. limit

92 Calibration fault, (feedback) sensor

16 Other 55

Motor current protection activated (MCP)

93 Signal fault, sensor 2

Performance requirement cannot be met

56 Underload 94 Limit exceeded, sensor 1

18 Commanded alarm standby (trip) 57 Dry running 95 Limit exceeded, sensor 2 19 Diaphragm break (dosing pump) 58 Low flow 96 Setpoint signal outside range 20 Insulation resistance low 59 No flow 97 Signal fault, setpoint input

21 Too many starts per hour 64 Overtemperature 98

Signal fault, input for setpoint

influence

22 Moisture switch alarm, digital 65

Motor temperature 1 (t_m or t_mo or t_mo1)

Signal fault, input for analog

setpoint

23 Smart trim gap alarm 66

Temperature, control electronics (t_e)

104 Software shutdown

24 Vibration 67

Temperature too high, internal frequency converter module (t_m)

105

Electronic rectifier protection

activated (ERP)

25 Setup conflict 68

External temperature/ water temperature (t_w)

106

Electronic inverter protection

activated (EIP)

Load continues even if the motor has been switched off

Thermal relay 1 in motor (e.g. Klixon)

110 Skew load, electrical asymmetry

External motor protector activated (e.g. MP 204)

Thermal relay 2 in motor (e.g. thermistor)

111 Current asymmetry

28 Battery low 71

Motor temperature 2 (Pt100, t_mo2)

112 Cos φ too high

Turbine operation (impellers forced backwards)

72 Hardware fault, type 1 113 Cos φ too low

Change bearings (specific service information)

73 Hardware shutdown (HSD) 120

Auxiliary winding fault

(single-phase motors)

Change varistor(s) (specific service information)

74 Internal supply voltage too high 121

Auxiliary winding current too high

(single-phase motors)

32 Overvoltage 75 Internal supply voltage too low 122

Auxiliary winding current too low

(single-phase motors)

Code Description Code Description Code Description

123

Start capacitor, low (single-phase motors)

183

Signal fault, extra temperature sensor

216 Pilot pump alarm

124

Run capacitor, low (single phase motors)

184 Signal fault, general-purpose sensor 217 Alarm, general-purpose sensor high

144

Motor temperature 3 (Pt100, t_mo3)

185 Unknown sensor type 218 Alarm, general-purpose sensor low

145

Bearing temperature high (Pt100), in general or top bearing

186 Signal fault, power meter sensor 219 Pressure relief not adequate

146

Bearing temperature high (Pt100), middle bearing

187 Signal fault, energy meter 220 Fault, motor contactor feedback

147

Bearing temperature high (Pt100), bottom bearing

188 Signal fault, user-defined sensor 221 Fault, mixer contactor feedback

148

Motor bearing temperature high (Pt100) in drive end (DE)

190

Sensor limit 1 exceeded (e.g. alarm level in WW application)

222 Time for service, mixer

149

Motor bearing temperature high (Pt100) in non-drive end (NDE)

191

Sensor limit 2 exceeded (e.g. high level in WW application)

223

Maximum number of mixer starts per hour exceeded

152

Communication fault, add-on module

192

Sensor limit 3 exceeded (e.g. overflow level in WW application)

224

Pump fault (due to auxiliary component or general fault)

153 Fault, analog output 193 Sensor limit 4 exceeded 225

Communication fault, pump

module 154 Communication fault, display 194 Sensor limit 5 exceeded 226 Communication fault, I/O module 155 Inrush fault 195 Sensor limit 6 exceeded 227 Combi event

156

Communication fault, internal frequency converter module

196 Operation with reduced efficiency 228 Not used

157 Real-time clock out of order 197 Operation with reduced pressure 229 Not used

158 Hardware circuit measurement fault 198

Operation with increased power consumption

230 Network alarm

159

CIM fault (Communication Interface Module)

199

Process out of range (monitoring/ estimation/calculation/control)

231

Ethernet: No IP address from DHCP

server

160 GSM modem, SIM card fault 200 Application alarm 232

Ethernet: Auto-disabled due to

misuse 168 Signal fault, pressure sensor 201 External sensor input high 233 Ethernet: IP address conflict 169 Signal fault, flow sensor 202 External sensor input low 236 Pump 1 fault

170

Signal fault, water-in-oil (WIO) sensor

203 Alarm on all pumps 237 Pump 2 fault

171 Signal fault, moisture sensor 204 Inconsistency between sensors 238 Pump 3 fault

172

Signal fault, atmospheric pressure sensor

205

Level float switch sequence inconsistency

239 Pump 4 fault

173

Signal fault, rotor position sensor (Hall sensor)

206 Water shortage, level 1 240

Lubricate bearings (specific service

information) 174 Signal fault, rotor origo sensor 207 Water leakage 241 Motor phase failure

175

Signal fault, temperature 2 sensor (t_mo2)

208 Cavitation 242

Automatic motor model

recognition failed

176

Signal fault, temperature 3 sensor (t_mo3)

209 Non-return valve fault 243

Motor relay has been forced

(manually operated/commanded) 177 Signal fault, Smart trim gap sensor 210 Overpressure 244 Fault, On/Off/Auto switch 178 Signal fault, vibration sensor 211 Underpressure 245 Pump continuous runtime too long

179

Signal fault, bearing temperature sensor (Pt100), general or top bearing

212

Diaphragm tank precharge pressure out of range

246

User-defined relay has been forced

(manually operated/commanded)

180

Signal fault, bearing temperature sensor (Pt100), middle bearing

213 VFD not ready 247

Power-on notice (device/system has

been switched off)

181

Signal fault, PTC sensor (short-circuited)

214 Water shortage, level 2 248 Fault, battery/UPS

182

Signal fault, bearing temperature sensor (Pt100), bottom bearing

215 Soft pressure build-up timeout

12. BACnet MAC address

If the MAC address switches are set to an invalid MAC address value, a MAC address of 0 will be used.

BACnet address

SW6 SW7

BACnet address

SW6 SW7

BACnet address

SW6 SW7

000 5133 10266 101 5234 10367 202 5335 10468 303 5436 10569 4 0 4 55 3 7 106 6 A 5 0 5 56 3 8 107 6 B 6 0 6 57 3 9 108 6 C 7 0 7 58 3 A 109 6 D 8 0 8 59 3 B 110 6 E

9 0 9 60 3 C 111 6 F 10 0 A 61 3 D 112 7 0 11 0 B 62 3 E 113 7 1 12 0 C 63 3 F 114 7 2 13 0 D 64 4 0 115 7 3 14 0 E 65 4 1 116 7 4 15 0 F 66 4 2 117 7 5 16 1 0 67 4 3 118 7 6 17 1 1 68 4 4 119 7 7 18 1 2 69 4 5 120 7 8 19 1 3 70 4 6 121 7 9 20 1 4 71 4 7 122 7 A 21 1 5 72 4 8 123 7 B 22 1 6 73 4 9 124 7 C 23 1 7 74 4 A 125 7 D 24 1 8 75 4 B 126 7 E 25 1 9 76 4 C 127 7 F 26 1 A 77 4 D 27 1 B 78 4 E 28 1 C 79 4 F 29 1 D 80 5 0 30 1 E 81 5 1 31 1 F 82 5 2 32 2 0 83 5 3 33 2 1 84 5 4 34 2 2 85 5 5 35 2 3 86 5 6 36 2 4 87 5 7 37 2 5 88 5 8 38 2 6 89 5 9 39 2 7 90 5 A 40 2 8 91 5 B 41 2 9 92 5 C 42 2 A 93 5 D 43 2 B 94 5 E 44 2 C 95 5 F 45 2 D 96 6 0 46 2 E 97 6 1 47 2 F 98 6 2 48 3 0 99 6 3 49 3 1 100 6 4 50 3 2 101 6 5

Subject to alterations.

Argentina

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Denmark

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Greece

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Ireland

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Italy

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Japan

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Korea

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Latvia

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Malaysia

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Netherlands

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New Zealand

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Norway

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Poland

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Portugal

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România

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Russia

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Serbia

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GRUNDFOS (Singapore) Pte. Ltd. 24 Tuas West Road Jurong Town Singapore 638381 Phone: +65-6865 1222 Telefax: +65-6861 8402

Slovenia

GRUNDFOS PUMPEN VERTRIEB Ges.m.b.H., Podružnica Ljubljana Šlandrova 8b, SI-1231 Ljubljana-Črnuče Phone: +386 1 568 0610 Telefax: +386 1 568 0619 E-mail: slovenia@grundfos.si

Spain

Bombas GRUNDFOS España S.A. Camino de la Fuentecilla, s/n E-28110 Algete (Madrid) Tel.: +34-91-848 8800 Telefax: +34-91-628 0465

Sweden

GRUNDFOS AB Box 333 (Lunnagårdsgatan 6) 431 24 Mölndal Tel.: +46(0)771-32 23 00 Telefax: +46(0)31-331 94 60

Switzerland

GRUNDFOS Pumpen AG Bruggacherstrasse 10 CH-8117 Fällanden/ZH Tel.: +41-1-806 8111 Telefax: +41-1-806 8115

Taiwan

GRUNDFOS Pumps (Taiwan) Ltd. 7 Floor, 219 Min-Chuan Road Taichung, Taiwan, R.O.C. Phone: +886-4-2305 0868 Telefax: +886-4-2305 0878

Thailand

GRUNDFOS (Thailand) Ltd. 92 Chaloem Phrakiat Rama 9 Road, Dokmai, Pravej, Bangkok 10250 Phone: +66-2-725 8999 Telefax: +66-2-725 8998

Turkey

GRUNDFOS POMPA San. ve Tic. Ltd. Sti. Gebze Organize Sanayi Bölgesi

Ihsan dede Caddesi,

2. yol 200. Sokak No. 204

41490 Gebze/ Kocaeli Phone: +90 - 262-679 7979 Telefax: +90 - 262-679 7905

E-mail: satis@grundfos.com

Ukraine

ТОВ ГРУНДФОС УКРАЇНА 01010 Київ, Вул. Московська 8б, Тел.:(+38 044) 390 40 50 Фах.: (+38 044) 390 40 59 E-mail: ukraine@grundfos.com

United Arab Emirates

GRUNDFOS Gulf Distribution P.O. Box 16768 Jebel Ali Free Zone Dubai Phone: +971-4- 8815 166 Telefax: +971-4-8815 136

United Kingdom

GRUNDFOS Pumps Ltd. Grovebury Road Leighton Buzzard/Beds. LU7 8TL Phone: +44-1525-850000 Telefax: +44-1525-850011

U.S.A.

GRUNDFOS Pumps Corporation 17100 West 118th Terrace Olathe, Kansas 66061 Phone: +1-913-227-3400 Telefax: +1-913-227-3500

Usbekistan

Представительство ГРУНДФОС в Ташкенте 700000 Ташкент ул.Усмана Носира 1-й тупик 5 Телефон: (3712) 55-68-15 Факс: (3712) 53-36-35

Addresses revised 15.06.2009

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