Mean Well PWM-200-36KN 取扱説明書

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PWM-60/120/200KN

PWM Output KNX LED Driver

Instruction Manual

1.Overview

Content

3.Communication Objects

4.Reference ETS-Parameter

1.1 Overview devices

3.1 Summary and Usage

4.2 Handling/basic functions

4.1 General function

4.3 Time functions

4.4 Staircase light

4.6 Absolute Values

4.5 Operating hours & Constant light output (CLO)

4.7 Specific Dimming settings

4.8 Scene function

4.9 Automatic function

4.10 Block function

4.11 PWM Frequency Selection

4.12 Temperature Measurement

4.13 Other useful information

1.2 Usage & possible applications

1.3 Displays and operating elements

1.4 Circuit diagrams

1.5 W iring

1.6 Information at the ETS-Software

1.7 Starting up

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Aug. 2021 Version 2

1.8 Other information ................................................................................................. 2

2.KNX Data Secure

2.1 Start-up with KNX Data Secure

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2

3

2.2 Start-up without KNX Data Secure .......................................................................... 3

2.3 Products That Support KNX Data Secure ................................................................. 3

PWM-60/120/200KN PWM Output LED Driver

Instruction Manual

1.Overview

1.1 Overview devices

The manual refers to the following devices: (Order Code respectively printed in bold type):

‧PWM-60KN: INPUT: 90 ~ 305VAC 47 ~ 63Hz, OUTPUT: 5A, 12V/ 2.5A, 24V

‧PWM-120KN: INPUT: 90 ~ 305VAC 47 ~ 63Hz, OUTPUT: 10A, 12V/ 5A, 24V

‧PWM-200KN: INPUT: 90 ~ 305VAC 47 ~ 63Hz, OUTPUT:15A, 12V/ 8.3A, 24V/5.55A,36V/4.17A,48V

‧Model Encoding

: KNX Bus connection cable

: Programming button

: Programming LED

: AC input cable

: DC output cable

A

B

C

D

E

A

E

BC

1.2 Usage & possible applications

The PWM KN series is a constant voltage mode output LED driver featuring Pulse Width Modulation (PWM) brightness control

and the KNX interface to avoid using the complicated KNX-DALI gateway. There are a large number of options for adjusting the

dimming process, e.g. dim speed, transition time, starting behavior ...... scenes function and different automatic functions

are also available for the KNX interface.

1.3 Displays and operating elements

 











 

 



  

1

1.3.1 PWM-60/120KN

1.3.2 PWM-200KN

tc1 tc2

D

A

E

BC

: KNX Bus connection cable

: Programming button

: Programming LED

: AC input cable

: DC output cable

A

B

C

D

E

2

Selection at the product database:

Manufacturer: MEANWELL Enterprises Co.Ltd.

Product family: Lighting

Product type: LED driver

Product name: addicted to the used type, e.g.: PWM-60KN, LED Driver with KNX interface

Order number: addicted to the used type, e.g.: PWM-60KN

After wiring, the allocation of the physical address and the parameterization of every channel follow:

(1)Connect the interface with the bus, e.g. MEANWELL USB interface KSI-01U.

(2)Switching the power supply.

(3)Set bus power up.

(4)Press the programming button at the device (red programming LED lights).

(5)Loading of the physical address out of the ETS-Software by using the interface (red LED goes out, as well this process

was completed successful).

(6)Loading of the application, with requested parameterization.

(7)If the device is enabled you can test the requested functions (also possible by using the ETS-Software).

1.6 Information at the ETS-Software

1.7 Starting up

‧ Use wires with an adequate cross-section for connection.

‧Use suitable mounting tools to do the wiring and mounting.

•The maximum number of bus devices connected is 256.

‧ The maximum length of a line segment is 350 m, measured along the line between the power supply and the furthest bus device.

‧ The maximum distance between two bus devices cannot exceed 700 m.

‧ The maximum length of a bus line is 1000 m, keeping into account all segments.

NOTE: PWM KN series can be ETS adressing/programming WITHOUT connecting to AC mains

1.8 Other information

ETS download Restart service (e.g. EITT) Bus power up (e.g. AC mains blackout)

Last value is stored into EEPROM of MCU No No Yes

Value in EEPROM of MCU will be updated in the situation below and the unit is in dimming state

2.KNX Data Secure

KNX Data Secure is supported in ETS5 from version 5.5.0. KNX Data Secure signs and encrypts the communication telegram

therefore the KNX Data Secure devices are protected against unauthorized access.

In the ETS Catalog, the KNX Secure products can be clearly recognized by the Secure icon:

As soon as a "KNX-Secure" device is included in the project, the ETS requests a project password. If no password is entered, the

device is without activation of secure mode. However, the password can also be set or changed later in the project overview.

1.5 W iring

1.4 Circuit diagrams

AC/L(BROWN)

Vo+(RED)

Vo-(BLACK)

KNX-(BLACK)

KNX+(RED)

AC/N(BLUE)

+

-

Any KNX Input Device

LED Strip or constant

voltage LED bulb

PWM-200KN 200W LED Driver with KNX interface

3.Communication Objects

3.1 Summary and Usage

Num Object Function Length DPT Flag Function Area Description

Central Objects:

1 Operation 1 bit State Central Function

This Communication is shown permanently and can

be used to send status of the device to the system at

regular intervals when active.

CRT

(DPT 1.011)

2.1 Start-up with KNX Data Secure

For secure communication, the FDSK (Factory Device Setup Key) is required. If a KNX product supports "KNX Data Secure", the

ETS requires the input of the FDSK. This device-specific key is printed on the device label and can either be entered by keyboard

or read by using a code scanner or the camera from a PC or laptop.

Example of FDSK on device label:

After entering the FDSK, the ETS generates a device-specific tool key. The ETS sends the tool key to the device to be configured via

the bus. The transmission is encrypted and authenticated with the original and previously entered FDSK key.

The device only accepts the tool key for further communication with the ETS. The FDSK key is no longer for further communication

used, unless the device is reset to the factory setting. In this case, all set safety-related data will be deleted.

The ETS generates as many runtime keys as needed for the group communication you want to protect. The ETS sends the runtime

keys to the device to be configured via the bus. Transmission takes place by encrypting and authenticating them via the tool key.

The FDSK is saved in the project and can be viewed in the project overview.

Also, all keys of this project can be exported (backup).

During project planning, it can be defined subsequently which functions/ objects are to communicate securely. All objects with

encrypted communication are identified by the "Secure" icon in the ETS.

2.2 Start-up without KNX Data Secure

Alternatively, the device can also be put into operation without KNX Data Secure. In this case, the device is unsecured and behaves

like any other KNX device without KNX Data Secure function.

To start up the device without KNX Data Secure, select the device in the 'Topology' or 'Devices' section and then set the 'Secure

start up' option in the 'Properties' area of the 'Settings' tab to 'Disabled'.

‧PWM-200KN

2.3 Products That Support KNX Data Secure

MEAN WELL

AFROO4-HWZ3JO

K4YDZN-WTILLR

4OBU7Y-3IVXYR

0162E770F6CE

The icon is:

3

14 Staircase light 1 bit CW Staircase light

This Communication Object is only shown when

Staircase light is active and can be used to switch

the staircase function on.

15 Staircase light

with time 2 byte CW Staircase light

This Communication Object is only shown when

Staircase light is active and can be used to switch

the staircase function on with a certain delay.

16 Prewarning 1 bit CRT Staircase light

This Communication Object is only shown when

Staircase light is active and can be used to show

status of Prewarning. The object will send a signal

when Staircase light enters the period of prewaning

and it will send out a signal again when prewarning

ﬁnished.

Switch

time(0-65535)s

Alarm

(DPT 1.001)

(DPT 7.005)

(DPT 1.005)

Switch

(DPT 1.001)

Automatic 2

Automatic 3

Automatic 4

9 1 bit CW

This Communication Object is only shown after

activating in the parameter settings and can be

used for calling of absolute brightness values with

a 1 Bit command.

10 1 bit CW

11 1 bit

1 bit

CW

12

13

Block I

Block II

Enable

(DPT 1.003)

CW

Normal dimmer/

Staircase light

Normal dimmer

This Communication is shown permanently and

This Communication Object is shown permanently

can be used for blocking this device.

and can be used for an extended

blocking function.

4

1

byte

5 Dim absolutely Percentage

Percentage

Scene number

Scene control

Switch

(DPT 5.001)

(DPT 17.001)

(DPT 18.001)

(DPT 1.001)

CW

CRT

Normal dimmer

This Communication Object is for controlling the main

function Dim absolutely for this , which is device

normally connected to all desired control keys.

6 State Dim

Value

Normal dimmer/

Staircase light

This Communication Object is for showing dimming

value of this device.

7 Scene 1 byte CW

This Communication Object is only shown after

activating in the parameter settings and can be

used for calling scenes.

used for calling scenes and learning a new scene.

8 Automatic 1 1 bit

This Communication Object is only shown after

activating in the parameter settings and can be

used for calling of absolute brightness values with

a 1 Bit command.

CW Normal dimmer

Normal dimmer

2 Switch On/Off 1

1

bit

Switch CW

This Communication Object is for controlling the main

function Switch On/Oﬀ and normally connected to all

desired control keys.

3 Switch State State Normal dimmer/

Staircase ligh

This Communication is shown permanently and

can be used for showing the switching state On/Oﬀ

of the device.

4 Dim relatively 4 bit Dimming control CW

CRT

This Communication is shown permanently and

allows the controlling of the main function Dim

Absolutely for the device.

(DPT 1.001)

(DPT 1.011)

(DPT 3.007) Normal

Normal

dimmer

Temperature

cancel alarm

Lamp Failure2

24

25

1 bit

CW

CRT

Temperature

alarm auto

cancel

Normal dimmer/

Staircase light

This Communication Object is only shown when

Eliminate Tunit/Tamb Alarm protection via is set at

Lamp Failure2 is active and can be used to show

object and can be used to remove temperature alarm

whether there is an alarm at the output.

enable

(1.003)

Alarm

(DPT 1.005 )

5

19

20

Operating hours

(Counter,in

seconds)

4 bytes

CRT

CW

Operating hours

This Communication Object is only shown when

Counting of operating hours & CLO is active and can

be used to send out the operating time of the device

Operating hours

(Set value, in

seconds)

Operating hours

(Set value, in

hours)

Operating hours

(Counter,in hours)

This Communication Object is only shown when

Counting of operating hours & CLO is active and can be

used to overwrite the operating time the device counted

21

23

Watts report

Temperature

alarm status

4 bytes

1 bit

Power

(DPT 14.056)

alarm

(1.005)

CRT

Power

consumption

feedback

Temperature

Measurement

This Communication Object is only shown when

Power consumption feedback is active and can be

Temperature Alarm protection is actived and can

used to report out power of the device

be used to report alarms

22 Temperature

report 2 bytes CO_RT Temperature

Measurement

The device sends the measured device temperature

value in°C at regular intervals

Time lag(s)

(DPT 13.100)

Time lag(s)

(DPT 13.100)

Counter pulse

(DPT 12.001)

Counter pulse

(DPT 12.001)

DPT_Value_Temp

(DPT 9.001)

4.Reference ETS-Parameter

4.1 General function

The following chart shows the objects that belong to general setting:

The chart shows the dynamic range for this parameter:

ETS ‐text Dynamic range

[default value]

Comment

Startup timeout 2 - 60s

[2s]

All functions run after startup timeout ﬁnished. NOTE: The

timeout starts counting when power-on initialization is done.

So it always takes longer than you expected

Send "Operation" cyclic (0=

not active)

0 - 30,000min

[0]

Sends status signals from the object Operation at

intervals you desire

Number

Name

Length

Usage

1Operation 1 bit Sends status of the device to the system at regular intervals

when active

0Send “operation” cycle(0=not active) min.

2sStartup timeout(Bus)

17 Permanent ON 1 bit Switch

Alarm

(DPT 1.001)

(DPT 1.005)

CW Staircase light

This Communication Object is only shown when

Staircase light is active and can be used to switch

the staircase light permanently on.

18 Lamp Failure1 1 bit CRT

Normal dimmer/

Staircase light

This Communication Object is only shown when

Lamp Failure1 is active and can be used to show

whether there is an alarm at the output.

6

4.2 Handling/basic functions

4.2.1 Switching

4.2.2 Dim relatively

4.2.3 Dim absolutely

2

4

5

3

Switch On/Off

Dim relatively

Dim absolutely

State On/Off

1 bit

4 bit

1 byte

1 bit

Switches 1 Bit switches the channel on or off

Dims the channel continuous up and down

Adjusts a certain brightness level

Shows the switching state of the channel

The basic functions of the dimming actuator are divided in three sections: Switching, dimming relatively and dimming absolutely.

As soon as a channel is activated, the communication functions for the basic functions are standardly shown.

A channel can be switched on or off by the switching command. In addition, there is a state object, which shows the actual

switching state of the output. This object, State On/Off, can be used for visualization. When the actuator shall be switched

by a binary input or a push button, this object must be connected with the state object of the binary input or the push button

for toggling.

The relative dimming allows continuous dimming. So the lights can be dimmed evenly form 0%(0.5%) to 100% or from

100% to minimum light. The relative dimming process can be stopped at every state. The behavior of the dimming process

can be adjusted via additional parameters, Increase:1%/3%/6%/12%/25%/50%/100%/break ; Derease: 1%/3%/6%/12%/

25%/50%/100%/break

A discrete brightness level can be set by the absolute dimming process. By sending an absolute percent value to the 1 Byte

object “Dim absolutely”, the output assumes a certain brightness level.

Number

Name

Length

Usage

The dimming actuator has the opportunities of connecting different time functions. Besides the normal on/off delay, an additional

staircase function with different sub functions is available.

4.3.1 On/ Off delay

The on and off delay allows a delayed switching. The following chart shows this parameter:

The chart shows the dynamic range for this parameter:

ETS-text Dynamic range

[default value]

Comment

On delay/

Off delay

0s – 30,000s

[0s]

Adjustment of the time at which the switch

on/switch off process shall be delayed

By using the On delay and Off delay, switching commands can be delayed. The delay can affect only to the rising edge

(switch on delay) or the falling edge (switch off delay). Furthermore, both functions can be combined. The following

diagram shows the functional principle of both functions, which are activated in this example:

4.3 Time function

0

Off delay s

s

On delay

7

KNX telegram

1 0 1 0

State

ON

t on t ont off t off

OFF

t

Staircase light allows an automatic offswitching of the channel, when the adjusted time runs out. To parameterize this function,

the staircase light must be activated at the corresponding channel:

If the staircase light is activated, the corresponding functions are shown at the same menu and the further parameterization can

be done.

4.4 Staircase light

Staircase light

Duration for staircase light

Prewarning

Extension

Manual switching off

Brightness value during permanent ON

When permanent OFF

not active

Dimm down off

Start time of staircase light

active

90 s

50%

The chart shows the dynamic range for this parameter:

ETS-text Dynamic range

[default value]

Comment

Duration of staircase light 1s -30,000s

[90s]

Duration of the switching process.

Prewarning Activates the prewarning.

Prewarning

duration in [s]

1-30,000

[10s]

Is only shown, when the prewarning is activated.

Value of dimming down 0.5-100%

[20%]

Is only shown, when the prewarning is activated value

of which the channel shall be dimmed down, when

the staircase time ran out .

Extension Activation of a possible extension of the staircase

light .

Manual switching off Activation of Deactivation of the staircase light,

before the whole time ran out .

Brightness value during permanent

ON

0%(OFF)-100%

[50%]

Dimming value at "Permanent ON" mode. Tirggered

when the object Permanent ON is "1".

When permanent OFF ‧Dim down off

‧Start time of staircase

light

Tirggered after the the object Permanent ON is "0".

The channel turns off when the parameter is Dim

down off; the channel continues a new staircase

light when set at Start time of staircase light.

‧not active

‧active

The duration of the staircase light indicates how long the channel shall be switched on after an ON-signal.

After lapse of time, the channel is switched off automatically. Via the parameter “Extension”/ “Manual switching off”, the

staircase function can be modified. The “Manual switching off” allows switching off the channel before the time ran out. The

“Extension” allows an extension of the staircase time, by sending another on telegram, so the time is restarted.

The prewarning function creates a dimming down of the lights after expiration of the staircase time. So the lights are still

switched on, but with another value. The lights stay at this position for the duration of the prewarning. If the staircase

function is activated, the communication object “Switch” is replaced by the communication object “Staircaselight”:

The staircase function has no influence to the relative or absolute dimming.

At the following diagram, the staircase function is shown, with an activated deactivation and extension.

The prewarning is activated with a dim down value of 20%:

14 Staircaselight 1 bit switches the staircase function on

Number

Name Length Usage

User's set value

Manual switching offExtension

KNX telegram

State lights

Staircase lights

Whole time

Prewarning

t

100%

0%

1 1 1 0

8

9

4.5 Operating hours & Constant light output (CLO)

Luminous flux of LEDs reduces over time as the diodes age, Constant Light Output (CLO) function is utilized to continuously

compensate for the drop in luminous flux of the luminaire. This compensation is automatic, requiring no maintenance resource

and the installation does not need to be over installed to compensate for future light depreciation from the diodes. You also can

receive data of how long the luminaire has been operating to organize a replacement before the end of LEDs' service life.

4.5.1 Operating hours

Operating hours can be used to monitor service time of the lumiaire and used to prepare a replacement before the lamp is

over its lifetime so as to maintain a constant level of illumination for the building.

The chart shows the dynamic range for this parameter:

ETS- text Dynamic range

[default value ]

Comment

Counting of operating hours

in

Hours ‧

‧Seconds

Chooses what unit is used in record

Send counters on

change(per hour)

not active ‧

‧active

Sends out the operating time every hour when active

Send counters cyclically 10min, 20min, 30min, 40min, 50min,

60min, not active

[not active]

Sends out the operating time at intervals you desire

Constant light output(CLO) ‧not active

active‧

Activates the CLO function

The following chart shows the objects for this parameter:

Number Name Length Usage

23

Operating hours(Counter, in

seconds/ hours)

4 bytes Sends the operating time of the driver counted to the

system at regular intervals when active. Unit: seconds

or hours

24

Operating hours(set value, in

seconds/hours)

4 bytes Overwrites the operating time the driver counted. Used

to reset the timer when replacing new LEDs. Unit:

seconds or hours

4.5.2 Constant light output (CLO)

Lumen depreciation is the luminous flux lost over time and it is irreversible. Generally, luminous flux of lamps without CLO

decreases to 80% from 100% after 50,000 hours. In contrast to lamps with CLO, albeit be luminous flux stars at 80%, it can

still mantained at around 80% even the lamps have been servicing for the same period of 50,000 hours. The method of

CLO is that the lumiaire starts its service life at a lower operational current and the current gradually increases over its

service life to compensate for the LED's light depreciation.

NOTE:

The PWM-KN saves the up-to-date operating time information into its MCU flash memory every 10 mins. If there is bus

voltage failure that occurs, the driver will lose the up to date operating time. In case the bus voltage is back to normal, the

operating time data is fetched from its flash memory.

For example 1, The PWM is already operating for 300 minutes. After 9 minutes, the bus voltage is lost and back to normal,

For example 2, The PWM is already operating for 300 minutes. After 11 minutes, the bus voltage is lost and back to normal,

the operating time acquired from the PWM internal flash is then 300 minutes.

the operating time acquired from the PWM internal flash is then 310 minutes.

Counting of operating hours & CLO not active active

Counting of operating hours in

Send counters on change (per hour)

Constant light output (CLO)

Send counters cyclically

hours seconds

not active active

not active

10

The chart shows the dynamic range for this parameter:

ETS- text Dynamic range

[default value ]

Comment

Scheduled division 1 1(x100hours) - 500(x100hours)

[100(x100hours)]

50% - 100%

[80%]

Parameterizes the ﬁrst stage of CLO

Scheduled division 2 1(x100hours) - 500(x100hours)

[150(x100hours)]

50% - 100%

[85%]

Parameterizes the 2nd stage of CLO

Scheduled division 3 1(x100hours) - 500(x100hours)

[200(x100hours)]

50% - 100%

[90%]

Parameterizes the 3rd stage of CLO

Scheduled division 4 1(x100hours) - 500(x100hours)

[300(x100hours)]

50% - 100%

[95%]

Parameterizes the 4th stage of CLO

Scheduled division 5 50% - 100%

[100%]

Parameterizes the ﬁnal stage of CLO

60%

80%

100%

10000 20000 30000 40000 50000

Power input relative to lumen output

Power with CLO

Lumen with CLO

Power without CLO

Lumen without CLO

Time/hrs

Energy saving with CLO

Scheduled division 1

LED module work time before (x100 hours) CLO factor

Scheduled division 2

100 80%

Scheduled division 3

150 85%

Scheduled division 4

200 90%

Scheduled division 5

300 95%

100%

The international standard IEC TM-21-11 deﬁnes the lumen depreciation of LED as follow:

L70: The illumination is reduced to 70% after 50,000 hours of use

L80: The illumination is reduced to 80% after 50,000 hours of use

L90: The illumination is reduced to 90% after 50,000 hours of use

Needing to type CLO curves yourself after having LEDs’ rated lifetime. Please follow the tables below to write a correct curve

for your LEDs.

L70:

Scheduled division 1

LED module work time before (x100 hours) CLO factor

Scheduled division 2

100 70%

Scheduled division 3

200 74%

Scheduled division 4

400 80%

Scheduled division 5

500 92%

100%

PWM-60/120KN:

11

4.6 Absolute Values

The dimming area of the dimming actuator can be restricted by absolute values. Furthermore absolute or saved values can be

called, when the actuator is switched on.

4.6.1 Starting behavior

The function “Starting behavior” defines the turn on behavior of the channel. The function can be parameterized for every

channel individually.

The chart shows the dynamic range for this parameter:

ETS-text Dynamic range

[default value]

Comment

Onvalue setting

Last light value (Memory)

Sub-function: Value of start up

0.5 -100%

[50%]

If this subfunction is chosen, a new sub

function is shown, at which an absolute

value for switching on can be chosen

The channel starts with the last value before

switching off

Starting behavior

Value of start up

On-value setting

Last light value (Memory)

50%

L80:

Scheduled division 1

LED module work time before (x100 hours) CLO factor

Scheduled division 2

100 80%

Scheduled division 3

200 83%

Scheduled division 4

400 87%

Scheduled division 5

500 95%

100%

L90:

Scheduled division 1

LED module work time before (x100 hours) CLO factor

Scheduled division 2

100 90%

Scheduled division 3

200 92%

Scheduled division 4

400 94%

Scheduled division 5

500 98%

100%

Via the parameter “Value of start up”, an absolute value for switching on can be assigned to the channel. The value for

startup contains the whole technical possible area, so form 0.5-100%. But if the dimming area is restricted, the dimming

actuator will be at least switched on with the lowest allowed value and maximum with the highest allowed value;

independent from the chosen Value of startup.

The parameter “Last light value“, also called memory function, causes a switching on of the actuator with the value before

the last switching off. So the actuator saves the last value. If, for example, the channel is dimmed to 50% and switched off

by switch object afterwards, the channel will be switched on with 50% again.

PWM-200KN:

Rated LED lifetime of L70/L80/L90 can be selected via the ETS. Once selected, all relevant values are ﬁlled in CLO curves

automatically.

hours seconds

no active active

L70

L80

L90

General setting

Block function

Operating hours

Constant light output(CLO)

Counting of operating hours in

Constant light output(CLO)

Send counters on change(per hour)

Send counters cyclically

Select the lifetime of connected LED load

no active

no active active

12

4.6.2 Dimming area

Via the parameters “maximum light” and “minimum light”, the dimming area can be restricted.

The chart shows the dynamic range for this parameter:

If the technical possible dimming area (0.5-100%) shall be restricted to a lower area, you have to set values for the

minimum light above 0.5% and for the maximum light under 100%. This restriction of the dimming area is possible for every

channel. If the dimming area is restricted, the channel will only move in the adjusted restriction. This setting has also

effects to the other parameter: If, for example, the channel is restricted to a maximum of 85% and the value of startup is

chosen as 100%, the channel will switch on with the maximum of 85%. An excess of the maximum value is no longer

possible. The restriction of a dimming area is useful when certain values must not be reached, because of technical

reasons, for example preservation of the life span or the avoidance of flickering at lower dim values (especially at Energy

saver).

ETS-text Dynamic range

[default value]

Comment

Maximum light

Minimum light

1-100%

[100%]

0.5-99%

[1%]

Highest, maximum allowed light value

Lowest, minimum allowed light value

4.7 Specific Dimming settings

The dimming behavior and SoftStart/Stop can be adapted individually via the functions below.

Example: Minimum light = 25%, maximum light = 85%, Value for startup= 100%

‧On telegram

‧15% telegram

‧95% telegram

‧50% telegram

‧Off telegram

adjusted light value 85%

adjusted light value 50%

adjusted light value 85%

adjusted light value 25%

adjusted light value 0% (Off)

→

100%

Technical

realizable

Dimming area

Parameterized

Dimming area

maximum

value=85%

minimum

value=25%

0%

1%

100%

Minimum light

Maximum light

Dim speed for relative dimming

Off via relative dimming

ON via relative dimming

Dim speed for absolute dimming (0=Jump)

On speed

Off speed

not active

active

5

s

2s

13

4.7.1 Dimming speed

The dimming speed allows parameterizing the duration of the dimming process individually.

The chart shows the dynamic range for this parameter:

ETS-text Dynamic range

[default value]

Comment

Dimming speed for relative dimming 1 120s -

[5s]

Deﬁnes the time for all relative dim processes

related to relative dimming process of 100%.

If a time of 10s is adjusted, the relative

dimming from 0% to 100% and vice versa

would last 10s. So the relative dimming from

0% to 50% would last 5s.

Dimming speed for absolute

dimming (0=Jump)

0-120s

[5s]

Deﬁnes the time for all absolute dimming

processes related to an absolute dimming

process of 100%. If a time of 10s is adjusted,

the absolute dimming from 0% to 100% and

vice versa would last 10s. So the absolute

dimming from 0% to 50% would last 5s.

ON via relative dimming

To maintain the output at OFF condition or

turn on the output when dimming value is

greater than the minimum level.

On speed

Off speed

0-240s

[2s]

The Off Speed realizes a Soft Stop function.

At an On Speed of 2s, the LED drivers will be

Speed of 2s, the LED drivers will be dimmed

dimmed up to 100% in 2s when switching on.

down to 0% in 2s when switching off.

4.7.2 Send dimming value after change

To visualize the dimming value, for example via a display, the following communication object must be activated:

ETS-text Dynamic range

[default value]

Comment

Send dim value after change ‧not active

active ‧

Activates the status object for the

dimming process

6State dimm value 1 byte Sends the actual dimming value in %

The communication object for the actual dimming value is shown continuous, but sends only the actual dimming value,

when the parameter “Send dimming value after change” is activated.

Number

Name

Length Usage

Off via relative dimming ‧not active

‧not active

‧active

To maintain the output at the minimum level

or turn off the output when dimming value is

lower than the minimum level.

ETS-text Dynamic range

[default value]

Comment

Dimming curve ‧L inear

‧Log

‧ DALI

Selection of linear or logarithmic dimming

signal

4.7.3 Dimming curve

The actuator provides both linear and logarithmic dimming curves for selection. In a linear dimming curve, the signal sent

to the drivers is linear, increasing in a steady rate. In contrast to logarithmic - the signal to the drivers changes slower at

deeper dimming levels and faster at the brighter end.

Send dim value after change not active at dim end

Dimming curve DALI

14

4.8 Scene function

OUTPUT OF LED DRIVER (%)

When functions of different groups (e.g. light, heating and shutter) shall be changed simultaneously with only one keystroke, it is

practical to use the scene function. By calling a scene, you can switch the lights to a specific value, drive the shutter to an

absolute position, switch the heating to the day mode and switch the power supply of the sockets on. The telegrams of these

functions can have as well different formats as different values with different meaning (e.g. “1” for switch the lights off and open

the shutters). If there were no scene function, you would have to send a single telegram for every actuator to get the same

function.

The scene function of the switch actuator enables you to connect the channels of the switch actuator to a scene control. For that,

you have to assign the value to the appropriated space (scene A-H). It is possible to program up to 8 scenes per switching

output. When you activate the scene function at the switching output, a new sub menu for the scenes appears at the left

selection menu. There are settings to activate single scenes, set values and scene numbers and switch the learn scene function

on/off at this sub menu.

Scenes are activated by receiving their scene numbers at the communication object for the scenes. If the “Learn scene” function

of the scenes is activated, the current value of the channel will be saved at the called scene number.

The communication objects of the scenes have always the length of 1 byte.

The following illustration shows the setting options at the ETS Software for activating the scene function:

7Scene 1 byte Call of the scene

The scene function can only be activated for the normal switching mode. If the staircase light function is activated, the

scene function cannot be activated for this channel.

The following chart shows the communication object for calling a scene:

Number Name Length Usage

For calling a certain scene, you have to send the value for the scene to the communication object.

The value of the scene number is always one number less than the adjusted scene number. For calling scene 1, you have

to send a “0”. So the scene numbers have the numbers from 1 to 64, but the values for the scenes only from 0 to 63.

If you want to call scenes by a binary input or another KNX device, you have to set the same number at the calling device as

at the receiving device. The calling device, e.g. a binary input, sends automatically the right value for calling the scene.

4.8.1 Submenu scene

If a scene is activated, a new submenu will appear at the left selection menu. At this submenu, the further parameterization

can be done. For every channel are up to 8 storage options available. These 8 presets have numbers A-H. One of the 64

scene numbers can be assigned to each scene. The following illustration shows the setting options at the submenu for the

scenes (Channel X: Scene) for the scenes A-H:

Scenes not active active

0

10

20

30

40

50

60

70

80

90

100

0 20 40 60 80 100

DIMMING COMMAND

Log DALI Linear

ETS-text Dynamic range

[default value] Comment

Learn scene

Scene A[H]

Activation of the depending scene

Scene Nr. A[H] 164-Adjusts the number for calling a

scene

Light value scene A[H] Off, 0.5%-100%

[Off]

Adjusts the light value for a scene

call

Transition time to new brightness 1-240s

[10]

The time taken from the privuous setting to

this new scene

The following chart shows the dynamic range for an activated scene function:

‧not active

active ‧

‧not active

active ‧

[A:1; B:2; … H:8]

Ad jus ts wh eth er th e le arn in g/s av in g

function shall be enabled for the scenes of

this channel or not. For instance: Light

value of the Scene A is 20%, this Light

value can be adjusted according to user's

preference afterwards, say 35%, and the

new value is able to be saved via DPT

18. 001 sce ne c ont rol by o the r KN X

devices, such as a smart home control

panel.

not active: learn scene function is disabled

and object value follows DPT 17.001

scene number.

active: learn scene function is enabled and

object value follows DPT 18.001 scene

control.

At the submenu for the scenes, a reaction can be assigned for the call of each scene. This reaction includes an absolute

light value (0-100%) for this channel. Every channel can react to 8 different scenes. By sending of the pickup value of the

relevant scene, the scene is called and the channel adjusts its parameterized values. The individual parameterization is

also watched at calling the scene.

If the channel shall dim to 50% at the call of the scene A and the channel has a parameterized switch on delay of 5s, the

channel will be switched on after this 5s and be dimmed to the 50% in compliance to the adjusted dimming speed.

To watch at the programming is that if two or more channels shall react to the same scene number, the communication

objects for the scenes of these channels have to be connected to the same group address. By sending of the pickup value

for the scenes, all channels will be called. It is practical to divide the group addresses by scenes at the programming. If a

channel shall react now to 8 scenes, the communication object has to be connected to 8 different group addresses.

15

Learn scene

Scene D

Scene E

Scene F

Scene G

Scene H

Scene C

Scene B

Scene A

Scene number

Light value

Transition time to new brightness

not active

active

10 s

1

off

16

ETS-text Dynamic range

[default value]

Comment

Automatic function 1[4] –

Exposure value

Off, 0.5%-100%

[Off]

Defines the exposure value for an

automatic call. Setting only activates

when the corresponding object is 1

Every automatic function can be assigned an absolute exposure value. The call of the automatic function is done by an 1

bit object.

4.10 Block function

Block function can be parameterized for every channel. Via the Block function, the behavior of the channel for calling the

blocking objects can be assigned.

4.9.1 Submenu automatic function

The further parameterization can be done at the submenu of the automatic function.

Automatic function 1-Exposure value

Behavior at BlockⅠ=value "1"

Behavior at BlockⅡ=value "1"

Behavior at BlockⅠ=value "0"

Behavior at BlockⅡ=value "0"

Automatic function 2-Exposure value

Light value

Invert BlockⅠinput

Invert BlockⅡinput

Release time for BlockⅠ(value "1" to

"0") (0 min=not active)

Release time for BlockⅡ(value "1" to

"0") (0 min=not active)

Automatic function 3-Exposure value

Automatic function 4-Exposure value

30% light

Light value

off

100% light

off

not active

active

0

min

Number

Name

Length Usage

8 Automatic 1 1 bit Calling of the automatic value 1

9 Automatic 2 1 bit Calling of the automatic value 2

10 Automatic 3 1 bit Calling of the automatic value 3

11 Automatic 4 1 bit Calling of the automatic value 4

4.9 Automatic function

An automatic function can be activated for every channel. The automatic function allows calling up to 4 absolute exposure

values for every channel. Calling can be done via a 1 bit commands.

For further setting options, the automatic function of a channel must be activated.

By activation the automatic function a submenu for further parameterization is shown. Furthermore, the following communication

objects are shown:

Automatic function not active active

17

Behavior at Block II = Value 1

Behavior at Block II = Value 0

Defines the action for activation of

the second blocking object

Off, no change, Light value

(0.5% - 100% )

[Light value]

InvertBlock II input If active, inverter singals recived from the

Block II Object, that is 1→0; 0→1

Release time for Block II (value "1" to “0" )

(0 min = not active)

0-600min

[0min]

Release the channel from "Behavior

at Block II = Value 1"after

countdown and enter "Block II =Value 0"

‧not active

active ‧

4.10.1 Blocking objects

Block I Object, that is 1→0; 0→1

For both blocking objects an action for activation as well as deactivation can be defined

ETS-text Dynamic range

[default value] Comment

Behavior at Block I = Value 1 Off, no change, Light value

Off, no change, Light value

(0.5% - 100% )

[Light value]

Deﬁnes the action for activation of

the ﬁrst blocking object

Behavior at Block I = Value 0 Deﬁnes the action for deactivation

of the ﬁrst blocking object

InvertBlock I input If active, inverter singals recived from the

Release time for Block I (value "1" to “0" )

(0 min = not active)

0-600min

[0min]

Release the channel from "Behavior

at Block I = Value 1" after

countdown and enter "Block I = Value 0"

‧not active

active ‧

By using the blocking objects, the channel can be blocked for further usage. Additional, the channel can perform an

adjusted function, as dimming to a certain value, switch the channel of or stay in its current state, when it is blocked. The

same actions can be performed by the channel, when it is unblocked.

It is important to be aware that the channel cannot be operated when it is blocked. Furthermore the manual usage is

blocked during a blocking process. All telegrams, which are sent to the corresponding channel during a blocking process,

have no effect for the channel.

If both blocking processes are activated, the first one is of prime importance. But if you activate the second blocking

process during the first blocking process, the second blocking process will get active when the first one is deactivated. The

action for the deactivation of the first blocking process will not be performed, but the channel calls the adjusted settings for

the second blocking process.

Priority from the highest to the lowest is BlockⅠ > BlockⅡ > Permanent ON > On/Off & Dimming output.

Number

Name

Length Usage

12 Activation/Deactivation of the ﬁrst blocking

process

13 Activation/Deactivation of the second blocking

process

1 bitBlockⅠ

1 bitBlock Ⅱ

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