EBV Energy Valves DN65

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EBV65-024-001  (24Vac/dc)    1440,00 €

EBV65-230-001 (230Vac)         1510,00 €

EBV65-024-101  (24Vac/dc with failsafe function)    1520,00 €

EBV65-230-101 (230Vac with failsafe function)         1590,00 €

Prices are subject to VAT 24% 

Smart Energy Valve, PN16, DN65, flanged connections,  cast iron body and brass plug.
Flow rate max 37 m3/h
Equipped with p/t plugs, pressure sensors  and temperature sensors
Motorized with actuator 24 Vac/dc (EBV65-024-x01)

Motorized with actuator 230 Vac (EBV65-230-x01)
Control signal 0-10 Vdc (default), 2-10 Vdc, 0-5/2-6 Vdc, 5-10/6-10 Vdc e 4-20 mA
Modbus-RTU connectivity, IP54 .

 The smart balancing and control valve EBV system is composed by the following elements:
• smart high resolution actuator able to collect and elaborate all the data coming from sensors and the BMS (via Modbus) in order to properly position the control valve;
• flanged Globe Valve with equal percentage control characteristic equipped with pressure sensor plugs;
• a couple of high resolution pressure sensors able to continuously monitor the valve differential pressure;
• a couple of NTC 10 kOhm temperature sensors with stainless steel cases able to continuously monitor the supply and return fluid temperature.

EBV can be controlled by 2 types of signal:

• Modbus command
• modulating (or proportional) with selectable range of action 0-10Vdc (default), 2-10Vdc, 0-5/2-6Vdc, 5-10/6-10Vdc and 4-20mA. 

EBV smart balancing control valve can offer the followings features :

Position Control

The actuator receive the modulating signal coming from a control loop implemented by the BMS and the valve is positioned from 0% to 100% accordingly to the voltage (0...10 Vdc) or current signal (4...20 mA).

Pressure Independent Control Function

The control signal coming from the BMS (i.e. 0...10 Vdc) has to be considered as the flow rate set point the BMS wants to deliver to the specific coil (Input 0V Flow 0; Input 10V: Flow: Qmax). The positioning algorithm set the valve position considering the valve characteristics and the current differential pressure across the valve. This function allows to control the flow delivered to the coil regardless the pressure fluctuations in the system.

It is possible to set the desired maximum flow rate whose value is included between the values of Qmax and Qmin defined for valve. To do this, the configuration tool is available which can be used both with the Modbus connection and via USB.  By default the value of the maximum desired flow rate is set to the maximum flow rate value. The maximum desired flow rate value corresponds to the maximum command signal (generally 10 V or 100%). For pressure differences below 0.01 bar, the flow rate calculated is 0 l/h and the valve position does not depend on the positioning algorithm, but directly on the control signal set by the BMS.

Heat Transfer Control Function

The control signal coming from the BMS (i.e. 0..10Vdc) has to be considered as the heat transfer setpoint the BMS wants to deliver to the specific coil. The positioning algorithm calculates the position of the valve considering its characteristic curve, the differential pressure across it and the current supply and return temperature. This function allows you to calculate the thermal power transferred from the coil and to control it independently of pressure fluctuations in the systems and other external conditions that could affect the heat transfer process, lowering the overall efficiency. It is possible to set the maximum desired power (Pmax) whose value is between the nominal power values (Pnom) defined for the valve at the various ΔT and shown in the following table. To do this, the configuration tool is available that can be used both with the Modbus connection and via USB. 

Valve body   Cast Iron

Plug    Brass

PN16

Fluid min   -10°C

Fluid max    120°C

Leakage   0,03% Kvs

Valve type    Smart valve

DN  65mm

Connection    Flanged

Fluid   Water

Flow max [m3/h]   37,00

Flow min [m3/h]   12,00

Max Differential Press. [kPa]   800

Min Differential Press. [kPa]   35

Allowable operating pressure   16bar

Connection size   UNI EN 1092-1

Pressure plugs    Yes

Application      HVAC-R

Emergency Return    EBV65-024-101  :  Yes       EBV65-230-101 :  Yes

Communication protocol     Modbus RTU/ASCII

Temperature sensors     Yes

EBV80-024-001  (24Vac/dc)    1560,00 €

EBV80-230-001 (230Vac)         1640,00 €

EBV80-024-101  (24Vac/dc with failsafe function)    1650,00 €

EBV80-230-101 (230Vac with failsafe function)         1720,00 €

Prices are subject to VAT 24% 

Smart Energy Valve, PN16, DN80, flanged connections,  cast iron body and brass plug.
Flow rate max 59 m3/h
Equipped with p/t plugs, pressure sensors  and temperature sensors
Motorized with actuator 24 Vac/dc (EBV80-024-x01)

Motorized with actuator 230 Vac (EBV80-230-x01)
Control signal 0-10 Vdc (default), 2-10 Vdc, 0-5/2-6 Vdc, 5-10/6-10 Vdc e 4-20 mA
Modbus-RTU connectivity, IP54 .

The smart balancing and control valve EBV system is composed by the following elements:
• smart high resolution actuator able to collect and elaborate all the data coming from sensors and the BMS (via Modbus) in order to properly position the control valve;
• flanged Globe Valve with equal percentage control characteristic equipped with pressure sensor plugs;
• a couple of high resolution pressure sensors able to continuously monitor the valve differential pressure;
• a couple of NTC 10 kOhm temperature sensors with stainless steel cases able to continuously monitor the supply and return fluid temperature.

EBV can be controlled by 2 types of signal:

• Modbus command
• modulating (or proportional) with selectable range of action 0-10Vdc (default), 2-10Vdc, 0-5/2-6Vdc, 5-10/6-10Vdc and 4-20mA. 

EBV smart balancing control valve can offer the followings features :

Position Control

The actuator receive the modulating signal coming from a control loop implemented by the BMS and the valve is positioned from 0% to 100% accordingly to the voltage (0...10 Vdc) or current signal (4...20 mA).

Pressure Independent Control Function

The control signal coming from the BMS (i.e. 0...10 Vdc) has to be considered as the flow rate set point the BMS wants to deliver to the specific coil (Input 0V Flow 0; Input 10V: Flow: Qmax). The positioning algorithm set the valve position considering the valve characteristics and the current differential pressure across the valve. This function allows to control the flow delivered to the coil regardless the pressure fluctuations in the system.

It is possible to set the desired maximum flow rate whose value is included between the values of Qmax and Qmin defined for valve. To do this, the configuration tool is available which can be used both with the Modbus connection and via USB.  By default the value of the maximum desired flow rate is set to the maximum flow rate value. The maximum desired flow rate value corresponds to the maximum command signal (generally 10 V or 100%). For pressure differences below 0.01 bar, the flow rate calculated is 0 l/h and the valve position does not depend on the positioning algorithm, but directly on the control signal set by the BMS.

Heat Transfer Control Function

The control signal coming from the BMS (i.e. 0..10Vdc) has to be considered as the heat transfer setpoint the BMS wants to deliver to the specific coil. The positioning algorithm calculates the position of the valve considering its characteristic curve, the differential pressure across it and the current supply and return temperature. This function allows you to calculate the thermal power transferred from the coil and to control it independently of pressure fluctuations in the systems and other external conditions that could affect the heat transfer process, lowering the overall efficiency. It is possible to set the maximum desired power (Pmax) whose value is between the nominal power values (Pnom) defined for the valve at the various ΔT and shown in the following table. To do this, the configuration tool is available that can be used both with the Modbus connection and via USB. 

Valve body   Cast Iron

Plug    Brass

PN16

Fluid min   -10°C

Fluid max    120°C

Leakage   0,03% Kvs

Valve type    Smart valve

DN  80mm

Connection    Flanged

Fluid   Water

Flow max [m3/h]   59,00

Flow min [m3/h]   25,00

Max Differential Press. [kPa]   800

Min Differential Press. [kPa]   35

Allowable operating pressure   16bar

Connection size   UNI EN 1092-1

Pressure plugs    Yes

Application      HVAC-R

Emergency Return    EBV80-024-101  :  Yes       EBV80-230-101 :  Yes

Communication protocol     Modbus RTU/ASCII

Temperature sensors     Yes

EBV100-024-001  (24Vac/dc)    1840,00 €

EBV100-230-001 (230Vac)         1910,00 €

EBV100-024-101  (24Vac/dc with failsafe function)    1920,00 €

EBV100-230-101 (230Vac with failsafe function)         1990,00 €

Prices are subject to VAT 24% 

Smart Energy Valve, PN16, DN100, flanged connections,  cast iron body and brass plug.
Flow rate max 77m3/h
Equipped with p/t plugs, pressure sensors  and temperature sensors
Motorized with actuator 24 Vac/dc (EBV100-024-x01)

Motorized with actuator 230 Vac (EBV100-230-x01)
Control signal 0-10 Vdc (default), 2-10 Vdc, 0-5/2-6 Vdc, 5-10/6-10 Vdc e 4-20 mA
Modbus-RTU connectivity, IP54 .

The smart balancing and control valve EBV system is composed by the following elements:
• smart high resolution actuator able to collect and elaborate all the data coming from sensors and the BMS (via Modbus) in order to properly position the control valve;
• flanged Globe Valve with equual percentage control characteristic equipped with pressure sensor plugs;
• a couple of high resolution pressure sensors able to continuously monitor the valve differential pressure;
• a couple of NTC 10 kOhm temperature sensors with stainless steel cases able to continuously monitor the supply and return fluid temperature.

EBV can be controlled by 2 types of signal:

• Modbus command
• modulating (or proportional) with selectable range of action 0-10Vdc (default), 2-10Vdc, 0-5/2-6Vdc, 5-10/6-10Vdc and 4-20mA. 

EBV smart balancing control valve can offer the followings features :

Position Control

The actuator receive the modulating signal coming from a control loop implemented by the BMS and the valve is positioned from 0% to 100% accordingly to the voltage (0...10 Vdc) or current signal (4...20 mA).

Pressure Independent Control Function

The control signal coming from the BMS (i.e. 0...10 Vdc) has to be considered as the flow rate set point the BMS wants to deliver to the specific coil (Input 0V Flow 0; Input 10V: Flow: Qmax). The positioning algorithm set the valve position considering the valve characteristics and the current differential pressure across the valve. This function allows to control the flow delivered to the coil regardless the pressure fluctuations in the system.

It is possible to set the desired maximum flow rate whose value is included between the values of Qmax and Qmin defined for valve. To do this, the configuration tool is available which can be used both with the Modbus connection and via USB.  By default the value of the maximum desired flow rate is set to the maximum flow rate value. The maximum desired flow rate value corresponds to the maximum command signal (generally 10 V or 100%). For pressure differences below 0.01 bar, the flow rate calculated is 0 l/h and the valve position does not depend on the positioning algorithm, but directly on the control signal set by the BMS.

Heat Transfer Control Function

The control signal coming from the BMS (i.e. 0..10Vdc) has to be considered as the heat transfer setpoint the BMS wants to deliver to the specific coil. The positioning algorithm calculates the position of the valve considering its characteristic curve, the differential pressure across it and the current supply and return temperature. This function allows you to calculate the thermal power transferred from the coil and to control it independently of pressure fluctuations in the systems and other external conditions that could affect the heat transfer process, lowering the overall efficiency. It is possible to set the maximum desired power (Pmax) whose value is between the nominal power values (Pnom) defined for the valve at the various ΔT and shown in the following table. To do this, the configuration tool is available that can be used both with the Modbus connection and via USB. 

Valve body   Cast Iron

Plug    Brass

PN16

Fluid min   -10°C

Fluid max    120°C

Leakage   0,03% Kvs

Valve type    Smart valve

DN  100mm

Connection    Flanged

Fluid   Water

Flow max [m3/h]   77,00

Flow min [m3/h]   45,00

Max Differential Press. [kPa]   800

Min Differential Press. [kPa]   35

Allowable operating pressure   16bar

Connection size   UNI EN 1092-1

Pressure plugs    Yes

Application      HVAC-R

Emergency Return    EBV100-024-101  :  Yes       EBV100-230-101 :  Yes

Communication protocol     Modbus RTU/ASCII

Temperature sensors     Yes

EBV125-024-001  (24Vac/dc)    1840,00 €

EBV125-230-001 (230Vac)         1910,00 €

EBV125-024-101  (24Vac/dc with failsafe function)    1920,00 €

EBV125-230-101 (230Vac with failsafe function)         1990,00 €

Prices are subject to VAT 24% 

Smart Energy Valve, PN16, DN125, flanged connections,  cast iron body and brass plug.
Flow rate max 118 m3/h
Equipped with p/t plugs, pressure sensors  and temperature sensors
Motorized with actuator 24 Vac/dc (EBV125-024-x01)

Motorized with actuator 230 Vac (EBV125-230-x01)
Control signal 0-10 Vdc (default), 2-10 Vdc, 0-5/2-6 Vdc, 5-10/6-10 Vdc e 4-20 mA
Modbus-RTU connectivity, IP54 .

The smart balancing and control valve EBV system is composed by the following elements:
• smart high resolution actuator able to collect and elaborate all the data coming from sensors and the BMS (via Modbus) in order to properly position the control valve;
• flanged Globe Valve with equual percentage control characteristic equipped with pressure sensor plugs;
• a couple of high resolution pressure sensors able to continuously monitor the valve differential pressure;
• a couple of NTC 10 kOhm temperature sensors with stainless steel cases able to continuously monitor the supply and return fluid temperature.

EBV can be controlled by 2 types of signal:

• Modbus command
• modulating (or proportional) with selectable range of action 0-10Vdc (default), 2-10Vdc, 0-5/2-6Vdc, 5-10/6-10Vdc and 4-20mA. 

EBV smart balancing control valve can offer the followings features :

Position Control

The actuator receive the modulating signal coming from a control loop implemented by the BMS and the valve is positioned from 0% to 100% accordingly to the voltage (0...10 Vdc) or current signal (4...20 mA).

Pressure Independent Control Function

The control signal coming from the BMS (i.e. 0...10 Vdc) has to be considered as the flow rate set point the BMS wants to deliver to the specific coil (Input 0V Flow 0; Input 10V: Flow: Qmax). The positioning algorithm set the valve position considering the valve characteristics and the current differential pressure across the valve. This function allows to control the flow delivered to the coil regardless the pressure fluctuations in the system.

It is possible to set the desired maximum flow rate whose value is included between the values of Qmax and Qmin defined for valve. To do this, the configuration tool is available which can be used both with the Modbus connection and via USB.  By default the value of the maximum desired flow rate is set to the maximum flow rate value. The maximum desired flow rate value corresponds to the maximum command signal (generally 10 V or 100%). For pressure differences below 0.01 bar, the flow rate calculated is 0 l/h and the valve position does not depend on the positioning algorithm, but directly on the control signal set by the BMS.

Heat Transfer Control Function

The control signal coming from the BMS (i.e. 0..10Vdc) has to be considered as the heat transfer setpoint the BMS wants to deliver to the specific coil. The positioning algorithm calculates the position of the valve considering its characteristic curve, the differential pressure across it and the current supply and return temperature. This function allows you to calculate the thermal power transferred from the coil and to control it independently of pressure fluctuations in the systems and other external conditions that could affect the heat transfer process, lowering the overall efficiency. It is possible to set the maximum desired power (Pmax) whose value is between the nominal power values (Pnom) defined for the valve at the various ΔT and shown in the following table. To do this, the configuration tool is available that can be used both with the Modbus connection and via USB. 

Valve body   Cast Iron

Plug    Brass

PN16

Fluid min   -10°C

Fluid max    120°C

Leakage   0,03% Kvs

Valve type    Smart valve

DN  125mm

Connection    Flanged

Fluid   Water

Flow max [m3/h]   118,00

Flow min [m3/h]   61,00

Max Differential Press. [kPa]   800

Min Differential Press. [kPa]   35

Allowable operating pressure   16bar

Connection size   UNI EN 1092-1

Pressure plugs    Yes

Application      HVAC-R

Emergency Return    EBV125-024-101  :  Yes       EBV125-230-101 :  Yes

Communication protocol     Modbus RTU/ASCII

Temperature sensors     Yes

EBV150-024-001  (24Vac/dc)    2340,00 €

EBV150-230-001 (230Vac)         2410,00 €

EBV150-024-101  (24Vac/dc with failsafe function)    2430,00 €

EBV150-230-101 (230Vac with failsafe function)         2500,00 €

Prices are subject to VAT 24% 

Smart Energy Valve, PN16, DN150, flanged connections,  cast iron body and brass plug.
Flow rate max 177 m3/h
Equipped with p/t plugs, pressure sensors  and temperature sensors
Motorized with actuator 24 Vac/dc (EBV150-024-x01)

Motorized with actuator 230 Vac (EBV150-230-x01)
Control signal 0-10 Vdc (default), 2-10 Vdc, 0-5/2-6 Vdc, 5-10/6-10 Vdc e 4-20 mA
Modbus-RTU connectivity, IP54 .

The smart balancing and control valve EBV system is composed by the following elements:
• smart high resolution actuator able to collect and elaborate all the data coming from sensors and the BMS (via Modbus) in order to properly position the control valve;
• flanged Globe Valve with equual percentage control characteristic equipped with pressure sensor plugs;
• a couple of high resolution pressure sensors able to continuously monitor the valve differential pressure;
• a couple of NTC 10 kOhm temperature sensors with stainless steel cases able to continuously monitor the supply and return fluid temperature.

EBV can be controlled by 2 types of signal:

• Modbus command
• modulating (or proportional) with selectable range of action 0-10Vdc (default), 2-10Vdc, 0-5/2-6Vdc, 5-10/6-10Vdc and 4-20mA. 

EBV smart balancing control valve can offer the followings features :

Position Control

The actuator receive the modulating signal coming from a control loop implemented by the BMS and the valve is positioned from 0% to 100% accordingly to the voltage (0...10 Vdc) or current signal (4...20 mA).

Pressure Independent Control Function

The control signal coming from the BMS (i.e. 0...10 Vdc) has to be considered as the flow rate set point the BMS wants to deliver to the specific coil (Input 0V Flow 0; Input 10V: Flow: Qmax). The positioning algorithm set the valve position considering the valve characteristics and the current differential pressure across the valve. This function allows to control the flow delivered to the coil regardless the pressure fluctuations in the system.

It is possible to set the desired maximum flow rate whose value is included between the values of Qmax and Qmin defined for valve. To do this, the configuration tool is available which can be used both with the Modbus connection and via USB.  By default the value of the maximum desired flow rate is set to the maximum flow rate value. The maximum desired flow rate value corresponds to the maximum command signal (generally 10 V or 100%). For pressure differences below 0.01 bar, the flow rate calculated is 0 l/h and the valve position does not depend on the positioning algorithm, but directly on the control signal set by the BMS.

Heat Transfer Control Function

The control signal coming from the BMS (i.e. 0..10Vdc) has to be considered as the heat transfer setpoint the BMS wants to deliver to the specific coil. The positioning algorithm calculates the position of the valve considering its characteristic curve, the differential pressure across it and the current supply and return temperature. This function allows you to calculate the thermal power transferred from the coil and to control it independently of pressure fluctuations in the systems and other external conditions that could affect the heat transfer process, lowering the overall efficiency. It is possible to set the maximum desired power (Pmax) whose value is between the nominal power values (Pnom) defined for the valve at the various ΔT and shown in the following table. To do this, the configuration tool is available that can be used both with the Modbus connection and via USB. 

Valve body   Cast Iron

Plug    Brass

PN16

Fluid min   -10°C

Fluid max    120°C

Leakage   0,03% Kvs

Valve type    Smart valve

DN  150mm

Connection    Flanged

Fluid   Water

Flow max [m3/h]   177,00

Flow min [m3/h]   80,00

Max Differential Press. [kPa]   800

Min Differential Press. [kPa]   35

Allowable operating pressure   16bar

Connection size   UNI EN 1092-1

Pressure plugs    Yes

Application      HVAC-R

Emergency Return    EBV150-024-101  :  Yes       EBV150-230-101 :  Yes

Communication protocol     Modbus RTU/ASCII

Temperature sensors     Yes