SINAMICS G120P and G120P Cabinet pump, fan, compressor converters
Unless explicitly specified otherwise, the following technical specifications are valid for all the following components of the pump, fan, compressor SINAMICS G120P and SINAMICS G120P Cabinet inverters.
SINAMICS G120P
Mechanical specifications
Vibratory load
Storage in accordance with EN 60721?3?1
Inverters and components, frame sizes FSA to FSF
Class 1M2
Deflection: 1.5 mm at 5 ... 9 Hz Acceleration: 0.5 ? g at 9 ... 200 Hz
Inverters and components with frame sizes GX to JX
Class 1M2
Deflection: 1.5 mm at 5 ... 9 Hz Acceleration: 0.5 ? g at 9 ... 200 Hz
SINAMICS G120P Cabinet
Class 1M2
Deflection: 1.5 mm at 5 ... 9 Hz Acceleration: 0.5 ? g at 9 ... 200 Hz
Transport 1) acc. to EN 60721-3-2
Inverters and components, frame sizes FSA to FSC 2)
Class 1M2
Inverters and components, frame sizes FSD to FSF
Class 2M3
Inverters and components with frame sizes GX to JX
Test FC according to EN 60068?2?6
Deflection: ±1.5 mm at 5 ... 9 Hz Acceleration: 0.5 ? g at 9 ... 200 Hz
SINAMICS G120P Cabinet
Class 2M2
Operation acc. to EN 60721?3?3
Inverters and components, frame sizes FSA to FSF
Class 3M1
Inverters and components with frame sizes GX to JX
Test FC according to EN 60068?2?6
Deflection: 0.075 mm at 10 ... 58 Hz Acceleration:10 m/s2 (1 ? g) at 58 ... 200 Hz
SINAMICS G120P Cabinet
Class 3M2
Shock load
Storage in accordance with EN 60721?3?1
Inverters and components, frame sizes FSA to FSF
Class 1M2
Inverters and components, frame sizes GX and JX
Test FC according to EN 60068?2?6
Deflection: ±1.5 mm at 5 ... 9 Hz Acceleration: 0.5 ? g at 9 ... 200 Hz
SINAMICS G120P Cabinet
Class 1M2
Acceleration: 40 m/s2 (4 ? g) at 22 ms
Transport 1) acc. to EN 60721-3-2
Inverters and components, frame sizes FSA to FSC 2)
Class 1M2
Inverters and components, frame sizes FSD to FSF
Class 2M3
Inverters and components with frame sizes GX to JX
Test FC according to EN 60068?2?6
Deflection: ±1.5 mm at 5 ... 9 Hz Acceleration: 0.5 ? g at 9 ... 200 Hz
SINAMICS G120P Cabinet
Class 2M2
Operation acc. to EN 60721?3?3
Inverters and components, frame sizes FSA to FSC
Class 3M2
Inverters and components, frame sizes FSD to FSF
Class 3M1
Inverters and components, frame sizes GX and JX
Test Ea according to EN 60068?2?27
Acceleration: 49 m/s2 (5 ? g) at 30 ms or 147 m/s2 (15 ? g) at 11 ms
SINAMICS G120P Cabinet
Class 3M2
Ambient conditions
Protection class
According to EN 61800?5?1
Class I (with protective conductor system) and class III (PELV)
Touch protection
According to EN 50274 and BGV A3 when used as intended
Permissible ambient and coolant temperature (air) during operation for line-side power components and Power Modules
Low overload (LO)
Frame sizes FSA to FSC: -10 ... +40 °C (14 ... 104 °F) without derating Frame sizes FSD to FSF: 0 ... 40 °C (32 ... 104 °F) without derating
Frame sizes FSA to FSF: >40 ... 60 °C (>104 ... 140 °F) see derating characteristics
Frame sizes GX to JX and SINAMICS G120P Cabinet: 0 ... 40 °C (32 ... 104 °F) without derating >40 ... 50 °C (>104 ... 122 °F) see derating characteristics
High overload (HO)
Frame sizes FSA to FSC: -10 ... +50 °C (14 ... 122 °F) without derating Frame sizes FSD to FSF: 0 ... 50 °C (32 ... 122 °F) without derating >50 ... 60 °C (>122 ... 140 °F) see derating characteristics
Frame sizes GX to JX and SINAMICS G120P Cabinet: 0 ... 40 °C (32 ... 104 °F) without derating >40 ... 50 °C (>104 ... 122 °F) see derating characteristics
Installation altitude
Up to 1000 m (3281 ft) above sea level without derating, > 1000 m (3281 ft) see derating characteristics
Permissible ambient and coolant temperature (air) during operation for Control Units and supplementary system components
With CU230P?2 HVAC/DP with/without blanking cover: -10 ... +60 °C (14 ... 140 °F)
With CU230P?2 PN with/without blanking cover: -10 ... +55 °C (14 ... 131 °F)
With IOP/BOP?2: 0 ... 50 °C (32 ... 122 °F)
Derating of 3 K/1000 m applies to Control Units as of an installation altitude of 1000 m above sea level.
Climatic ambient conditions
Storage 1) acc. to EN 60721?3?1
Inverters and components, frame sizes FSA to FSF
Temperature -40 ... +70 °C (-40 ... +158 °F) Relative air humidity <95 %, without condensation
Inverters and components, frame sizes GX to JX and SINAMICS G120P Cabinet
Class 1K4 Temperature -25 ... +55 °C (-13 ... +131 °F) Relative air humidity 5 ... 95 %
Transport 1) acc. to EN 60721-3-2
Inverters and components, frame sizes FSA to FSF
Class 2K4 Temperature -40 ... +70 °C (-40 ... +158 °F) Max. air humidity 95 % at 40 °C (104 °F)
Inverters and components, frame sizes GX to JX and SINAMICS G120P Cabinet
Class 2K3 Temperature -25 ... +70 °C (-13 ... +158 °F), -40°C (-40 °F) permissible for 24 h Relative air humidity 5 ... 95 % at 40 °C (104 °F)
Operation acc. to EN 60721?3?3
Inverters and components, frame sizes FSA to FSF
Class 3K3 Condensation, splashwater, and ice formation not permitted (EN 60204, Part 1)
Inverters and components, frame sizes GX to JX and SINAMICS G120P Cabinet
Class 3K3 Temperature 0 ... 40°C (32 ... 104 °F), up to 50 °C (122 °F) with derating Relative air humidity 5 ... 95 % Condensation, splashwater and ice formation are not permitted (EN 60204, Part 1)
Environmental class/harmful chemical substances
Storage 1) acc. to EN 60721?3?1
Class 1C2
Transport 1) acc. to EN 60721-3-2
Class 2C2
Operation acc. to EN 60721?3?3
Class 3C2
Organic/biological influences
Storage 1) acc. to EN 60721?3?1
Class 1B1
Transport 1) acc. to EN 60721-3-2
Class 2B1
Operation acc. to EN 60721?3?3
Class 3B1
Degree of pollution
According to EN 61800?5?1
2
Standards
Compliance with standards
Inverters and components, frame sizes FSA to FSF
UL 3), cUL 4), CE, RCM, SEMI F47
Inverters, frame sizes GX to JX
cULus, CE, RCM, EAC, KC, SEMI F47 5)
SINAMICS G120P Cabinet
CE, RCM, EAC, KC, SEMI F47 5)
CE marking
According to Low Voltage Directive 2014/35/EU, EMC Directive 2014/30/EU
EMC Directive
According to EN 61800-3
PM240: Frame size FSF with integrated line filter class A
The Power Modules maintain the limit values for conducted interference and noise radiation of Category C2 according to EN 61800?3.
PM230: Frame sizes FSA to FSF with integrated line filter class A, degree of protection IP20/UL Open Type and IP55/UL Type 12
The Power Modules comply with Category C2 according to EN 61800?3.
PM230: Frame sizes FSA to FSF with integrated line filter class B, degree of protection IP55/UL Type 12
The Power Modules comply with the limit values for low-frequency line harmonics and conducted interference according to Category C1. They comply with the limit values for field-conducted interference emissions according to Category C2.
PM330: Frame sizes GX to JX
Category C3 6)
PM330: Frame sizes GX to JX with additional line filter class A
Category C2 7)
SINAMICS G120P Cabinet
Category C3 8)
SINAMICS G120P Cabinet with additional line filter class A
Category C2 8)
Deviations from the specified classes are underlined.
1) In transport packaging.
2) In product packaging.
3) For degree of protection IP55/UL Type 12, the UL approval only applies to frame sizes FSA to FSC.
4) Applies to PM230 Power Modules frame sizes FSA to FSC and PM240 Power Modules with integrated line filter class A.
5) SEMI F47 for PM330 Power Modules frame size JX available soon
6) Standard configuration: Devices installed in the control cabinet with EMC-compatible configuration, line reactor uK = 2 %, shielded motor cable (e.g. Protoflex EMC) with max. 100 m cable length. Line harmonics acc. to EN 61000?2?4: Class 3, THD(U) total = 10% for typical line conditions (RSC > 10);THD(I) total: typically 30 ... 45% (15 > RSC > 50).
7) Use in the second environment, for boundary conditions refer to 6).
8)For boundary conditions refer to 6), cabinet is configured accordingly in version A.
Note:
The EMC product standard EN 61800-3 does not apply directly to a frequency inverter but to a PDS (Power Drive System), which comprises the complete circuitry, motor and cables in addition to the inverter. The frequency inverters on their own do not generally require identification according to the EMC Directive.
Compliance with standards
CE marking
The SINAMICS G120P and SINAMICS G120P Cabinet inverters meet the requirements of the Low-Voltage Directive 2014/35/EC.
Low-Voltage Directive
The inverters comply with the following standards listed in the official journal of the EU:
EN 60204 Safety of machinery, electrical equipment of machines
EN 61800?5?1 Electrical power drive systems with variable speed – Part 5?1: Requirements regarding safety – electrical, thermal, and energy requirements
UL listing
Inverters in UL category NMMS certified to UL and cUL, in compliance with UL508C or ULC61800?5?1. UL list numbers E121068 and E192450.
The inverters are suitable for installation in machines. Compliance with the Machinery Directive 2006/42/EC requires a separate certificate of conformity. This must be provided by the plant construction company or the organization marketing the machine.
Functional safety
SINAMICS G120P and SINAMICS G120P Cabinet are not intended for use in installations with functional safety as defined by ISO 13849?1, IEC 61508?x.
EMC Directive
EN 61800?3 Variable-speed electric drives Part 3: EMC product standard including specific test methods
The following explanatory information applies to SINAMICS G120P and SINAMICS G120P Cabinet inverters supplied by Siemens AG:
The EMC product standard EN 61800-3 does not apply directly to an inverter but to a PDS (Power Drive System), which comprises the complete circuitry, motor and cables in addition to the inverter.
Inverters are normally only supplied to experts for installation in machines or systems. An inverter must, therefore, only be considered as a component which, on its own, is not subject to the EMC product standard EN 61800-3. The inverter's operating instructions, however, specifies the conditions regarding compliance with the product standard if the inverter is expanded to become a PDS. For a PDS, the EMC Directive in the EU is complied with by observing the product standard EN 61800-3 for variable-speed electric drive systems. The inverters on their own do not generally require identification according to the EMC Directive.
Different categories C1 to C4 have been defined in accordance with the environment of the PDS at the operating location:
Category C1: Drive systems for rated voltages < 1000 V for use in the first environment
Category C2: Stationary drive systems not connected by means of a plug connector for rated voltages < 1 000 V. When used in the first environment, the system must be installed and commissioned by personnel familiar with EMC requirements. A warning note is required.
Category C3: Drive systems for rated voltages < 1000 V for exclusive use in the second environment. A warning note is required.
Category C4: Drive systems for rated voltages ? 1000 V or for rated currents ? 400 A or for use in complex systems in the second environment. An EMC plan must be created.
The EMC product standard EN 61800?3 also defines limit values for conducted interference and radiated interference for the "second environment" (= industrial power supply systems that do not supply households). These limit values are below the limit values of filter class A to EN 55011. Unfiltered inverters can be used in industrial environments as long as they are part of a system that contains line filters on the higher-level infeed side.
With SINAMICS G120P and SINAMICS G120P Cabinet, Power Drive Systems (PDS) that fulfill the EMC product standard EN 61800-3 can be configured when observing the installation instructions in the product documentation.
A differentiation must be made between the product standards for electrical drive systems (PDS) of the range of standards EN 61800 (of which Part 3 covers EMC topics) and the product standards for the devices/systems/machines, etc. This will probably not result in any changes in the practical use of inverters. Since inverters are always part of a PDS and these are part of a machine, the machine manufacturer must observe various standards depending on their type and environment (e.g. EN 61000?3?2 for line harmonics and EN 55011 for radio interference). The product standard for PDS on its own is, therefore, either insufficient or irrelevant.
With respect to the compliance with limits for line supply harmonics, the EMC product standard EN 61800?3 for PDS refers to compliance with the EN 61000?3?2 and EN 61000?3?12 standards. EN 61000?2?4 applies for devices >75 A.
Regardless of the configuration with SINAMICS G120P and SINAMICS G120P Cabinet and its components, the machine construction company (OEM) can also apply other measures to ensure that the machine complies with the EU EMC Directive. The EU EMC Directive is generally fulfilled when the relevant EMC product standards are observed. If they are not available, the generic standards (e.g. DIN EN 61000?x?x) can be used instead. It is important that the conducted and emitted interference at the line supply connection point and outside the machine remain below the relevant limit values. Any suitable technical measures can be applied to ensure this.
SEMI F47
SEMI F47 is an industry standard relating to the immunity to voltage dips. This includes the requirement that industrial equipment must be able to tolerate defined dips or drops of the line supply voltage. As a result, industrial equipment that fulfills this standard is more reliable and productive.
All Power Modules of the SINAMICS G120P product family fulfill the latest standard SEMI F47-0706 1). In the case of a voltage dip, defined in accordance with SEMI F47?0706, these drives either continue to supply a defined output current, or using an automatic restart function, continue to operate as expected.
1) SEMI F47 for PM330 Power Modules frame size JX available soon
EAC approval for Russia/Belarus/Kazakhstan/Armenia
Since February 15, 2013, Russia, Kazakhstan, Belarus and Armenia have been united in the Eurasian EAC customs union. An EAC approval as replacement for the GOST mark is required for all products that are to be sold in Russia.
All devices delivered to the customs union must have these customs certifications.
RCM approval for Australia
The RCM mark is required for marketing Siemens components in Australia. Electronic devices must provide proof of EMC clearance in Australia, similar to the CE marking of conformity laid down by the EMC directive applicable in the EU. The inverters must be marked accordingly. These requirements have been in force since October 1, 1999.
On March 1, 2016, the C-Tick mark was replaced by the RCM mark.
Power Modules
General technical specifications
Power Modules
PM230
PM240
PM330
Cabinet
System operating voltage
380 ... 480 V ±10 % 3 AC
380 ... 480 V 3 AC ±10 %
380 ... 480 V 3 AC ±10 %
500 ... 690 V 3 AC ±10 %
380 ... 480 V 3 AC ±10 %
500 ... 690 V 3 AC ±10 %
Grid requirement Short-circuit power RSC
>100
>25
>100 line reactor recommended
>33 line reactor recommended
>33 1) Line reactors installed as standard
Input frequency
47 ... 63 Hz
47 ... 63 Hz
47 ... 63 Hz
47 ... 63 Hz
Output frequency
Control mode V/f
0 ... 550 Hz
0 ... 550 Hz
0 ... 100 Hz
0 ... 100 Hz
Control type Vector
0 ... 240 Hz
0 ... 240 Hz
0 ... 100 Hz
0 ... 100 Hz
Pulse frequency
4 kHz
Higher pulse frequencies up to 16 kHz, see derating data
75 kW HO: 4 kHz From 90 kW HO: 2 kHz
Higher pulse frequencies up to 16 kHz, see derating data
Self-adjusting up to 4 kHz
Self-adjusting up to 4 kHz
Power factor ?
0.9
0.7 ... 0.85
0.75 ... 0.93
0.75 ... 0.93
Offset factor cos ?
0.95
0.95
0.96
0.96
Efficiency
86 ... 98 %
95 ... 98 %
>98%
>98%
Output voltage, max.
As % of input voltage
95%
95%
97%
97%
Overload capability
Low overload (LO)
Note:
When the overload capability is used, the base-load current IL is not reduced.
FSA to FSC: 1.5 ? base-load current IL (i. e. 150 % overload) for 3 s plus 1.1 ? base-load current IL (i. e. 110 % overload) for 57 s within a cycle time of 300 s
FSD to FSF: 1.1 ? base-load current IL (i.e. 110 % overload) for 60 s within a cycle time of 300 s
90 kW (LO): 1.5 ? base-load current IL (i. e. 150 % overload) for 3 s plus 1.1 ? base-load current IL (i. e. 110 % overload) for 57 s within a cycle time of 300 s
110 kW and higher (LO): 1.5 ? base-load current IL (i. e. 150 % overload) for 1 s plus 1.1 ? base-load current IL (i. e. 110 % overload) for 59 s within a cycle time of 300 s
1.35 ? base-load current IL (i.e. 135% overload) for 3 s or1.1 ? base-load current IL (i.e. 110% overload) for 60 s within a cycle time of 300 s
1.35 ? base-load current IL (i.e. 135% overload) for 3 s or1.1 ? base-load current IL (i.e. 110% overload) for 60 s within a cycle time of 300 s
High overload (HO)
Note:
When the overload capability is used, the base-load current IH is not reduced.
FSA to FSC: 2 ? base-load current IH (i. e. 200 % overload) for 3 s plus 1.5 ? base-load current IH (i. e. 150 % overload) for 57 s within a cycle time of 300 s
FSD to FSF: 1.5 ? base-load current IH (i.e. 150 % overload) for 60 s within a cycle time of 300 s
75 kW (HO): 2 ? base-load current IH (i. e. 200 % overload) for 3 s plus 1.5 ? base-load current IH (i. e. 150 % overload) for 57 s within a cycle time of 300 s
90 kW and higher (HO): 1.6 ? base-load current IH (i. e. 160 % overload) for 3 s plus 1.36 ? base-load current IH (i. e. 136 % overload) for 57 s within a cycle time of 300 s
1.5 ? base-load current IH (i. e. 150 % overload) for 60 s within a cycle time of 300 s
1.5 ? base-load current IH (i. e. 150 % overload) for 60 s within a cycle time of 300 s
Possible braking methods
IP55/UL Type 12: DC braking
IP20 standard / IP20 Push Through: DC braking
DC braking
Dynamic braking with integrated braking module
DC braking
Dynamic braking with optional Braking Module
DC braking
Dynamic braking with optional Braking Module
Overvoltage category acc. to IEC 61800?5?1
III
III
Supply circuits: III Non-supply circuits: II
III
Degree of protection
IP55/UL Type 12 (with BOP?2 or blanking cover)
IP54/UL Type 12 (with IOP)
IP20 (Standard or Push Through)
IP20
IP20
Standard: IP20
Optional: IP21, IP23, IP43 and IP54
Cooling
Power units with increased air cooling using integrated fans
Internal ventilation, power units with increased air cooling by built-in fans
Internal ventilation, power units with increased air cooling by built-in fans
Internal ventilation, power units with increased air cooling by built-in fans
Protection functions
Undervoltage
Overvoltage
Overcurrent/overload
Overtemperature
Ground fault
Short-circuit
Stall protection
Motor blocking protection
Motor overtemperature
Parameter locking
Short-Circuit Current Rating SCCR
acc. to UL
(Short-Circuit Current Rating) 2)
Degree of protection IP55 frame sizes FSA to FSC: 40 kA
Degree of protection IP55 frame sizes FSD to FSF and degree of protection IP20: 65 kA
65 kA
100 kA 3)
–
Rated short-circuit current
acc. to IEC 3)
–
–
100 kA 3)
65 kA 3)
1) Does not apply in conjunction with option L01.
2) Applies to industrial control panel installations according to NEC Article 409 or UL 508A/508C.
3) In combination with the fuses specified in section Recommended line-side power components.
skener.ru
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 23
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 23
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Àðìàòóðà DENDOR
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 23
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Äàò÷èêè è èçìåðèòåëè
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 23
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Ðåãóëÿòîðû è ðåãèñòðàòîðû
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 23
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Ïíåâìàòè÷åñêîå îáîðóäîâàíèå
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 23
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Êðàíû è Êëàïàíû
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 23
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Èçìåðèòåëüíûå ïðèáîðû
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 23
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Ñèñòåìû áåñïðîâîäíîãî óïðàâëåíèÿ «óìíûé äîì»
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 23
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Áåñêîíòàêòíûå âûêëþ÷àòåëè Êîíå÷íûå âûêëþ÷àòåëè Îïòè÷åñêèå äàò÷èêè Ýíêîäåðû
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 23
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
SKW-FS - Óñòàíîâêà óìÿã÷åíèÿ
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 23
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
Deprecated: Function eregi() is deprecated in /home/h101150-2/siemens71.ru/docs/kip/kip.php on line 30
SKW-FK - Óñòàíîâêà îáåçæåëåçèâàíèÿ