2904612

QUINT4-PS/1AC/48DC/20 Power supply unit Data sheet 109981_en_00 1 © PHOENIX CONTACT 2022-02-25 Description QUINT POWER power supplies with SFB Technology and preventive function monitoring ensure superior system availability. Technical data (short form) Powerful Mains buffering – – SFB Technology: 6 times the nominal current for 15 ms Power reserves: Static boost of up to 125% (PN) for a sustained period Dynamic boost of up to 200% (PN) for 5 s Robust – – Mains buffering ≥ 20 ms High degree of electrical immunity, thanks to integrated gas discharge tube (6 kV) Preventive – Comprehensive signaling: Analog signal, digital signal, relay contact, LED bar graph Can be ordered pre-configured – Perform configuration online and order 1 or more units Input voltage range 100 V AC ... 240 V AC 15 % ... +10 % typ. 27 ms (120 V AC) typ. 28 ms (230 V AC) Nominal output voltage (UN) 48 V DC Nominal output current (IN) Static Boost (IStat.Boost) Dynamic Boost (IDyn.Boost) Selective Fuse Breaking (ISFB) 20 A 22.5 A 30 A (5 s) 105 A (15 ms) Efficiency typ. 95.2 % (120 V AC) typ. 96.2 % (230 V AC) Setting range of the output voltage (USet) Output power (PN) Output power (PStat. Boost) Output power (PDyn. Boost) Residual ripple MTBF (IEC 61709, SN 29500) Ambient temperature (operation) Dimensions W/H/D Weight 48 V DC ... 56 V DC 960 W 1080 W 1440 W < 50 mVPP > 569000 h (40 °C) -25 °C ... 70 °C -40°C (startup type tested) > 60 °C Derating: 2,5 %/K 120 mm / 130 mm / 140 mm 2.85 kg Long service life – Well over 15 years All technical specifications are nominal values and refer to a room temperature of 25 °C and 70 % relative humidity at 100 m above sea level. QUINT4-PS/1AC/48DC/20 2 Table of contents 2 Table of contents ..................................................................................................................... 2 1 3 4 Description .............................................................................................................................. 1 Ordering data .......................................................................................................................... 3 Technical data ......................................................................................................................... 4 5 Safety and installation notes .................................................................................................. 15 7 Structure of the power supply ................................................................................................ 19 6 8 9 10 11 12 13 High-voltage test (HIPOT) ..................................................................................................... 17 Mounting/removing the power supply .................................................................................... 22 Device connection terminal blocks ........................................................................................ 25 Output characteristic curves .................................................................................................. 27 Configuring the power supply ................................................................................................ 30 Boost currents ....................................................................................................................... 31 SFB Technology .................................................................................................................... 33 14 Signaling................................................................................................................................ 38 16 Derating................................................................................................................................. 48 15 Operating modes ................................................................................................................... 46 109981_en_00 PHOENIX CONTACT 2/51 QUINT4-PS/1AC/48DC/20 3 Ordering data Description Type Item no. Pcs./Pkt. QUINT POWER primary-switched power supply with free QUINT4-PS/1AC/48DC/20 choice of output characteristic curve, SFB (Selective Fuse Breaking) Technology, and NFC interface, input: 1-phase, output: 48 V DC/20 A 2904612 1 Accessories Type Item no. Pcs./Pkt. 2-piece universal wall adapter for securely mounting the device in the event of strong vibrations. The profiles that are screwed onto the side of the device are screwed directly onto the mounting surface. The universal wall adapter is attached on the left/right. UWA 130 2901664 1 Near Field Communication (NFC) programming adapter with USB interface for the wireless configuration of NFCcapable products from PHOENIX CONTACT with software. No separate USB driver is required. TWN4 MIFARE NFC USB ADAPTER 2909681 1 PLT-SEC-T3-230-FM-UT 2907919 5 End clamp, material: Aluminum, color: silver E/AL-NS 35 1201662 10 Versions of the primary-switched QUINT POWER power supply with SFB Technology (selective fuse breaking), which are configured online, can now be ordered in batches of one or more using the following web code: phoenixcontact.net/webcode/#0852 Universal wall adapter for securely mounting the device in UWA 182/52 the event of strong vibrations. The device is screwed directly onto the mounting surface. The universal wall adapter is attached on the top/bottom. Type 2/3 surge protection, consisting of protective plug and base element with screw connection. For singlephase power supply network with integrated status indicator and remote signaling. Nominal voltage: 230 V AC/DC Type 2/3 surge protection, consisting of protective plug and base element with Push-in connection. For singlephase power supply network with integrated status indicator and remote signaling. Nominal voltage: 230 V AC/DC PLT-SEC-T3-230-FM-PT 2938235 2907928 1 5 The range of accessories is being continuously extended. The current range of accessories can be found in the download area for the product. 109981_en_00 PHOENIX CONTACT 3/51 QUINT4-PS/1AC/48DC/20 4 Technical data Input data Unless otherwise stated, all data applies for 25°C ambient temperature, 230 V AC input voltage, and nominal output current (IN). Input voltage range Electric strength, max. Frequency range (fN) 100 V AC ... 240 V AC -15 % ... +10 % 110 V DC ... 250 V DC -18 % ... +40 % 300 V AC 60 s 50 Hz ... 60 Hz -10 % ... +10 % Frequency (fR) for railway power supply systems 16.7 Hz (acc. to EN 50163) Current draw typ. 13.6 A (100 V AC) 5.4 A (240 V AC) 12 A (110 V DC) 5 A (250 V DC) Railway power supply systems can be operated at 16.7 Hz. Use conditions and technical data on request. The specified values for current consumption apply for operation in the static boost (PN x 125%). Discharge current to PE typical Mains buffering Inrush current limitation after 1 ms Inrush current integral (I2t) Input fuse slow-blow, internal < 3.5 mA 1.7 mA (264 V AC, 60 Hz) typ. 27 ms (120 V AC) typ. 28 ms (230 V AC) 12 A < 1 A2s 16 A During the first few microseconds, the current flow into the filter capacitors is excluded. The SCCR value (short-circuit current rating) of the power supply unit corresponds to the SCCR value of the backup fuse (see input protection table). The external backup fuse must be approved for the (AC) supply voltage used and the voltage level. 109981_en_00 PHOENIX CONTACT 4/51 QUINT4-PS/1AC/48DC/20 Input protection , AC/DC ( to be connected externally upstream ) Input current IIn Input protection Characteristics 4A A - 6A - 10 A - 13 A 16 A 20 A Neozed fuse or equivalent Circuit breaker B - C - - - D K gG - - - - - Power switch ≤ 13 x IIn (maximum magnetic tripping) - - - - - -  - - -                     Electric strength of the insulation Housing Input Signaling (+) L N (-) B B A D Output PE + C A Type test (IEC/EN 60950-1) 2.5 kV AC Field test (with gas-filled surge arrester) 0.8 kV AC 1.1 kV DC Production test Field test (gas-filled surge arrester de-contacted) 109981_en_00 2 kV AC 2 kV AC 2.83 kV DC B 4 kV AC C 0.5 kV DC D 0.5 kV DC 2 kV AC 0.5 kV DC 0.5 kV DC 2 kV AC 2.83 kV DC 0.5 kV DC 0.5 kV DC 0.8 kV AC 1.1 kV DC 0.5 kV DC 0.5 kV DC PHOENIX CONTACT 5/51 QUINT4-PS/1AC/48DC/20 Power Factor POWER factor 1,0 ij 0,9 Ĵ 0,8 0,7 ij = UIn: 120 V AC/UOut: 48 V DC Ĵ = UIn: 230 V AC/UOut: 48 V DC 0,6 0,5 10 5 15 20 25 30 IOut [A] Crest factor 120 V AC typ. 1,66 230 V AC typ. 1,63 IIn [A] Input current vs. output current 15,0 ij = UIn: 120 V AC/UOut: 48 V DC 12,0 Ĵ = UIn: 230 V AC/UOut: 48 V DC 9,0 ij 6,0 3,0 0,0 0 Ĵ 5 10 15 20 30 25 IOut [A] Input connection data Connection method Screw connection Conductor cross section, rigid 0.2 mm² ... 6 mm² Conductor cross section flexible, with ferrule with plastic sleeve 0.25 mm² ... 4 mm² Conductor cross section, flexible 0.2 mm² ... 4 mm² Conductor cross section flexible, with ferrule without plastic sleeve 0.25 mm² ... 4 mm² Stripping length 8 mm Conductor cross section AWG 24 ... 10 Tightening torque 0.5 Nm ... 0.6 Nm 109981_en_00 PHOENIX CONTACT 6/51 QUINT4-PS/1AC/48DC/20 Output data Nominal output voltage (UN) Setting range of the output voltage (USet) ( constant capacity ) 48 V DC 48 V DC ... 56 V DC Nominal output current (IN) 20 A Dynamic Boost (IDyn.Boost) 30 A (5 s) Static Boost (IStat.Boost) 22.5 A Selective Fuse Breaking (ISFB) 105 A (15 ms) Control deviation Static load change 10 % ... 90 % < 0.5 % Magnetic circuit breaker tripping A1...A40 / B2...B25 / C1...C13 / Z1...Z16 Control deviation Dynamic load change 10 % ... 90 %, (10 < 1 % Hz) Control deviation change in input voltage ±10 % < 0.25 % No-load proof yes Short-circuit-proof Residual ripple ( with nominal values ) Connection in parallel Connection in series Feedback voltage resistance Protection against overvoltage at the output (OVP) Output connection data Connection method yes < 50 mVPP yes, for redundancy and increased capacity yes ≤ 60 V DC ≤ 60 V DC Screw connection Conductor cross section, rigid 0.5 mm² ... 16 mm² Conductor cross section flexible, with ferrule with plastic sleeve 0.5 mm² ... 16 mm² Conductor cross section, flexible 0.5 mm² ... 16 mm² Conductor cross section flexible, with ferrule without plastic sleeve 0.5 mm² ... 16 mm² Stripping length 10 mm Conductor cross section AWG 20 ... 6 Tightening torque 1.2 Nm ... 1.5 Nm LED signaling POut > 100 % LED lights up yellow, output power > 960 W POut > 75 % LED lights up green, output power > 720 W UOut > 0.9 x USet LED lights up green POut > 50 % UOut < 0.9 x USet 109981_en_00 LED lights up green, output power > 480 W LED flashes green PHOENIX CONTACT 7/51 QUINT4-PS/1AC/48DC/20 Signal contact (configurable) Signal output (configurable) Out 1 Digital Default Signal output (configurable) Out 2 Digital Analog 0 / 24 V DC , , 20 mA 24 V DC , 20 mA ( 24 V DC for UOut > 0.9 x USet ) 0 / 24 V DC , , 20 mA 4 mA ... 20 mA ±5 % (Load ≤400 Ω) Default Relay contact (configurable) 13/14 Function Default Maximum contact load Control input (configurable) Rem Function Default Signal ground SGnd Signal connection data Connection method 24 V DC , 20 mA ( 24 V DC for POut  0.9 USet) 24 V DC 1 A , 30 V AC/DC 0.5 A Output power ON/OFF (SLEEP MODE) Output power ON (>40 kΩ/24 V DC/open bridge between Rem and SGnd) Reference potential for Out1, Out2, and Rem Push-in connection Conductor cross section, rigid 0.2 mm² ... 1 mm² Conductor cross section flexible, with ferrule with plastic sleeve 0.2 mm² ... 0.75 mm² Conductor cross section, flexible 0.2 mm² ... 1.5 mm² Conductor cross section flexible, with ferrule without plastic sleeve 0.2 mm² ... 1.5 mm² Stripping length 8 mm Conductor cross section AWG 24 ... 16 Reliability 230 V AC MTBF (IEC 61709, SN 29500) Life expectancy (electrolytic capacitors) Output current (IOut) 10 A 20 A 20 A 109981_en_00 > 949000 h (25 °C) > 569000 h (40 °C) > 260000 h (60 °C) 120 V AC 230 V AC > 367000 h ( 40 °C ) > 452000 h ( 40 °C ) > 155000 h ( 40 °C ) > 440000 h ( 25 °C ) > 217000 h ( 40 °C ) > 614000 h ( 25 °C ) The expected service life is based on the capacitors used. If the capacitor specification is observed, the specified data will be ensured until the end of the stated service life. For runtimes beyond this time, error-free operation may be reduced. The specified service life of more than 15 years is simply a comparative value. PHOENIX CONTACT 8/51 QUINT4-PS/1AC/48DC/20 Switching frequency Min. PFC stage 50 kHz Main converter stage 45 kHz Auxiliary converter stage Max. 500 kHz 85 kHz General data Degree of protection 107 kHz 200 kHz IP20 Protection class I Side element version Aluminum Dimensions W / H / D (state of delivery) 120 mm / 130 mm / 140 mm Inflammability class in acc. with UL 94 (housing / terminal V0 blocks) Hood version Stainless steel X6Cr17 Weight 2.85 kg Power dissipation Maximum no-load power dissipation Power loss nominal load max. Eta [%] 0.8 kV AC / 1.1 kV DC, the gas-filled surge arrester must be disconnected. The test voltage should rise and fall in ramp form. The relevant rise and fall time of the ramp should be at least two seconds. 6.1 High-voltage dielectric test (dielectric strength test) In order to protect the user, power supplies (as electric components with a direct connection to potentially hazardous voltages) are subject to more stringent safety requirements. For this reason, permanent safe electrical isolation between the hazardous input voltage and the touch-proof output voltage as safety extra-low voltage (SELV) must always be ensured. In order to ensure permanent safe isolation of the AC input circuit and DC output circuit, high-voltage testing is performed as part of the safety approval process (type test) and manufacturing (routine test). 6.2 High-voltage dielectric test during the manufacturing process During the manufacturing process for the power supply, a high-voltage test is performed as part of the dielectric test in accordance with the specifications of IEC/UL/EN 61010-1. The high-voltage test is performed with a test voltage of at least 1.5 kV AC / 2.2 kV DC or higher. Routine manufacturing tests are inspected regularly by a certification authority. 109981_en_00 PHOENIX CONTACT 17/51 QUINT4-PS/1AC/48DC/20 Performing high-voltage testing If high-voltage testing of the control cabinet or the power supply as a stand-alone component is planned during final inspection and testing, the following features must be observed. – The power supply wiring must be implemented as shown in the wiring diagram. – The maximum permissible test voltages must not be exceeded. Avoid unnecessary loading or damage to the power supply due to excessive test voltages. For the relevant applicable test voltages and insulation distances, refer to the corresponding table (see technical data: electric strength of the insulation section). Figure 1 Disconnecting the gas discharge tube The built-in gas discharge tube inside the device ensures that the power supply is effectively protected against asymmetrical disturbance variables (e.g., EN 61000-4-5). Each surge voltage test represents a very high load for the power supply. Therefore avoid unnecessary loading or damage to the power supply due to excessive test voltages. If necessary, the gas discharge tube inside the device can be disconnected in order to use higher test voltages. Following successful completion of testing, please reconnect the gas-discharge tube. Figure 2 Disconnect gas discharge tube Potential-related wiring for the high-voltage test QUINT POWER Ord.No.XXXXXXX 1 2.1 + 2.2 + 2.3 – 2.4 Output DC – 13 14 Rem SGnd Out 1 Out 2 t os Bo % 00 Pout 1 > 5% > 70% > 5 OK DC B – 3.1 3.2 3.3 3.4 3.5 3.6 2 HV 3 ó/= Input AC DC N/- L/+ 1.1 1.2 1.3 4 Key No. Designation Color coding 1 2 3 Blue Blue -- Potential levels Potential 1 Potential 1 -- Red Potential 2 109981_en_00 M3 x8 3.3 3.4 3.5 3.6 Signal UOut DC output circuit Signal contacts High-voltage tester AC input circuit A 13 14 m e R d n SG 1 t Ou 2 t Ou 2.5 > 100% Boost > 75% > 50% POut DC OK 4 6.3.2 QUINT POW 6.3.1 To disconnect the gas discharge tube, proceed as follows: 1. Remove power from the unit. 2. Unscrew the Phillips head screw completely and keep the gas discharge tube screw in a safe place. The gasdischarge tube is now disconnected and is no longer functional. 3. Perform the surge voltage test on the power supply. 4. Following successful high-voltage testing, screw the gas discharge tube screw fully back into the power supply. DANGER: Risk of electric shock or damage to the power supply due to using the wrong gas discharge tube screw To connect the gas-filled surge arrester, only use the gas-filled surge arrester screw that was originally installed in the power supply. PHOENIX CONTACT 18/51 QUINT4-PS/1AC/48DC/20 Structure of the power supply 7.2 Figure 4 The fanless convection-cooled power supply can be snapped onto all DIN rails according to EN 60715. 120 Function elements Operating and indication elements 65 1 2 2.1 + 2.3 – 2.4 – UOut 2.5 – Signal 56V 48V 2.2 + 2.3 2.4 13 14 Rem SGnd Out 1 Out 2 3.1 3.2 3.3 3.4 3.5 3.6 3 2.5 UOut 56V Signal 13 14 Rem SGnd Out 1 Out 2 48V 3.1 3.2 3.3 3.4 3.5 3.6 Input AC 100-240V DC 110-250V N/- L/+ 1.1 1.2 1.3 4 Figure 5 Device dimensions (dimensions in mm)  9  2 7 5 6 2 Designation DC output voltage connection terminal blocks Accommodation for cable binders Signaling connection terminal blocks Status and diagnostics indicators Position NFC interface (Near Field Communication) QR code web link AC input voltage connection terminal blocks Gas discharge tube for surge protection (left side of housing) Universal DIN rail adapter (rear of housing) Output voltage button (-) / (+) 109981_en_00   Key   Input AC 100-240V DC 110-250V 5 N/- L/+ 1.1 1.2 1.3 8 9 10 + Output DC 48V 20A Output DC 48V 20A > 100% Boost > 75% P > 50% Out DC OK No. 1 2 3 4 5 6 7 8 + > 100% Boost > 75% > 50% POut DC OK QUINT POWER Ord.No. 2904612 10 2 2.2 2.1 130 Figure 3 Device dimensions (dimensions in mm) Ord.No. 2904612 7.1 Device dimensions QUINT POWER 7 PHOENIX CONTACT 19/51 QUINT4-PS/1AC/48DC/20 7.3 Keep-out areas Nominal output capacity a 0 5 < 50 % ≥ 50 % Figure 6 Spacing [mm] b 40 50 c 20 50 Device dimensions and minimum keep-out areas (in mm) a a Ord.No. 2904612 b 120 2.1 QUINT POWER + 2.2 + 2.3 – 2.4 – Output DC 48V 20A UOut 130 48V 2.5 – Signal 56V 13 14 Rem SGnd Out 1 Out 2 3.1 3.2 3.3 3.4 3.5 3.6 > 100% Boost > 75% > 50% POut DC OK c Input AC 100-240V DC 110-250V N/- L/+ 1.1 1.2 1.3 109981_en_00 PHOENIX CONTACT 20/51 QUINT4-PS/1AC/48DC/20 7.4 Block diagram Figure 7 Block diagram                                   Key Symbol Designation Surge protection (gas discharge tube) Symbol Optocoupler (electrically isolating) Surge protection (varistor) with filter Bridge rectifier Designation Auxiliary converter (electrically isolating) OVP Additional regulatory protection against surge voltage Relay contact and signal contacts Inrush current limitation  active PFC Power factor correction (PFC) Switching transistor and main transmitter (electrically isolating) 109981_en_00 μC NFC Microcontroller Passive NFC interface (Near Field Communication) Secondary rectification and smoothing Output voltage button (-) / (+) Filter Signal/display LEDs (POut, DC OK) PHOENIX CONTACT 21/51 QUINT4-PS/1AC/48DC/20 8 Mounting/removing the power supply 8.1 Mounting the power supply unit 4. Then separate the power supply from the DIN rail (D). Figure 9 D Proceed as follows to mount the power supply: 1. In the normal mounting position the power supply is mounted on the DIN rail from above. Make sure that the universal DIN rail adapter is in the correct position behind the DIN rail (A). 2. Then press the power supply down until the universal DIN rail adapter audibly latches into place (B). 3. Check that the power supply is securely attached to the DIN rail. Figure 8 C A Snapping the power supply onto the DIN rail A Removing the power supply from the DIN rail 8.3 B Retrofitting the universal DIN rail adapter For installation in horizontal terminal boxes it is possible to mount the power supply at a 90° angle to the DIN rail. No additional mounting material is required. Click 8.2 B Removing the power supply unit Proceed as follows to remove the power supply: 1. Take a suitable screwdriver and insert this into the lock hole on the universal DIN rail adapter (A). 2. Release the lock by lifting the screwdriver (B). 3. Carefully swivel the power supply forward (C) so that the lock slides back into the starting position. Use the Torx screws provided to attach the universal DIN rail adapter to the side of the power supply. 8.3.1 Disassembling the universal DIN rail adapter Proceed as follows to disassemble the universal DIN rail adapter that comes pre-mounted: 1. Remove the screws for the universal DIN rail adapter using a suitable screwdriver (Torx 10). 2. Separate the universal DIN rail adapter from the rear of the power supply. Figure 10 Disassembling the universal DIN rail adapter 8 M3x 109981_en_00 8 M3x PHOENIX CONTACT 22/51 QUINT4-PS/1AC/48DC/20 8.3.2 Mounting the universal DIN rail adapter To mount the universal DIN rail adapter on the left side of the device, proceed as follows: 1. Position the universal DIN rail adapter on the left side of the housing so that the mounting holes are congruent with the hole pattern for the mounting holes. 2. Insert the Torx screws that were removed earlier into the appropriate hole pattern on the universal DIN rail adapter so that the necessary drill holes on the power supply can be accessed. 3. Screw the universal DIN rail adapter onto the power supply. The maximum tightening torque of the Torx screw (Torx® T10) is 0.7 Nm. Figure 11 Mounting the universal DIN rail adapter 8.4.1 Mounting the UWA 182/52 universal wall adapter Proceed as follows to disassemble the universal DIN rail adapter that comes pre-mounted: 1. Remove the screws for the universal DIN rail adapter using a suitable screwdriver (Torx 10). 2. Separate the universal DIN rail adapter from the rear of the power supply. 3. Position the universal wall adapter in such a way that the keyholes or oval tapers face up. The mounting surface for the power supply is the raised section of the universal wall adapter. 4. Place the power supply on the universal wall adapter in the normal mounting position (input voltage connection terminal blocks below). 5. Insert the Torx screws into the appropriate hole pattern on the universal wall adapter so that the necessary mounting holes on the power supply can be accessed. 6. Screw the universal wall adapter onto the power supply. Figure 12 x8 M3 Mounting the UWA 182/52 universal wall adapter x8 M3 M3x 8.4 8 M3x 8 Retrofitting the universal wall adapter The UWA 182/52 universal wall adapter (Item No. 2938235) or UWA 130 universal wall adapter (Item No. 2901664) is used to attach the power supply directly to the mounting surface. The use of universal wall adapters is recommended under extreme ambient conditions, e.g., strong vibrations. Thanks to the tight screw connection between the power supply and the universal wall adapter or the actual mounting surface, an extremely high level of mechanical stability is ensured. The maximum tightening torque of the Torx screw (Torx® T10) is 0.7 Nm. Make sure you use suitable mounting material when attaching to the mounting surface. The power supply is attached to the UWA 182 or UWA 130 universal wall adapter by means of the Torx screws of the universal DIN rail adapter. 109981_en_00 PHOENIX CONTACT 23/51 QUINT4-PS/1AC/48DC/20 8.4.2 Mounting the UWA 130 2-piece universal wall adapter Proceed as follows to disassemble the universal DIN rail adapter that comes pre-mounted: 1. Remove the screws for the universal DIN rail adapter using a suitable screwdriver (Torx 10). 2. Separate the universal DIN rail adapter from the rear of the power supply. 3. Position the universal wall adapter. The mounting surface for the power supply is the raised section of the universal wall adapter. 4. Place the power supply on the universal wall adapter in the normal mounting position (input voltage connection terminal blocks below). 5. Insert the Torx screws into the appropriate hole pattern on the universal wall adapter so that the necessary mounting holes in the side flanges of the power supply can be accessed. 6. Screw the two-piece universal wall adapter onto the power supply. Fix connection wiring to the power supply Two receptacles for the bundled attachment of the connection wiring are integrated in the left and right housing panel. Use cable binders to secure the connection wiring (optional WT-HF 3,6X140 - Item No. 3240744). Proceed as follows to secure the connection wiring: – Wire the power supply with sufficient connection reserve (input terminal blocks, output terminal blocks, signal terminal blocks) – Bundle and set up the connection wiring so that the cooling grilles on the top and bottom of the housing are covered as little as possible. – Thread the cable binders into the necessary receptacles for the cable binders. Figure 14 Lay and align connection wiring Mounting the UWA 130 universal wall adapter QUINT POWER Ord.No.29046xx Figure 13 8.5 2.1 + 2.2 + 2.3 Ou - 2.4 tpu - 2.5 tD C - U Out 13 14 Re m SG nd Ou t1 Ou t2 Sig na l >1 > 7 00% > 55% Boo st 0 D % M3x CO 8 M3x K 8 – 3.1 3.2 3.3 3.4 3.5 3.6 Po ut Secure the connection wiring with the cable binders. Make sure that the connection wiring is attached safely and securely without damaging the connection wiring. QUINT POWER Ord.No.29046xx Figure 15 Secure connection wiring with cable binder 2.1 + 2.2 + 2.3 Ou - 2.4 tpu - 2.5 tD C - U Out 13 14 Re m SG nd Ou t1 Ou t2 Sig na l >1 > 7 00% > 55% Boo st D 0% 3.1 3.2 3.3 3.4 3.5 3.6 C O Po ut K 109981_en_00 PHOENIX CONTACT 24/51 QUINT4-PS/1AC/48DC/20 – – Shorten the excess length of the cable ties. Then check again that the connection wiring is properly secured. Figure 16 Shorten protruding ends of the cable binder 9 Device connection terminal blocks The AC input and DC output terminal blocks on the front of the power supply feature screw connection technology. The signal level is wired without tools by means of Push-in connection technology. QUINT POWER Ord.No.29046xx For the necessary connection parameters for the connection terminal blocks, refer to the technical data section. 9.1 2.1 + 2.2 + 2.3 Ou - 2.4 tpu - 2.5 tD C - U Out 13 14 Re m SG nd Ou t1 Ou t2 Sig na l >1 > 7 00% > 55% Boo st D 0% 3.1 3.2 3.3 3.4 3.5 3.6 C O Po ut K NOTE: Mechanical damage to the connection wiring caused by friction In extreme ambient conditions, e.g., strong vibrations, protect the connection wiring against mechanical damage using additional insulation material. The additional insulation material for protecting the connection wiring is limited to the area where the cable binders are attached. Input The power supply is operated on single-phase AC systems or two outer conductors of three-phase systems. The power supply is connected on the primary side via the INPUT L/N/  connection terminal blocks. The power supply is approved for connection to TN, TT, and IT power grids with a maximum phase-to-phase voltage of 240 V AC. Figure 17 Network types TN-S TN-C L N PE N L L PEN N L + ̐ + ̐ L1 L2 L3 N PE N L L1 L2 L3 PEN N L + ̐ TT + ̐ iT L N L PEN N L N L + ̐ + ̐ L1 L2 L3 L1 L2 L3 N N L 109981_en_00 + ̐ N L + ̐ PHOENIX CONTACT 25/51 QUINT4-PS/1AC/48DC/20 9.2 Protection of the primary side Installation of the device must correspond to EN 61010 regulations. It must be possible to switch off the device using a suitable disconnecting device outside the power supply. The line protection on the primary side is suitable for this (see technical data section). DANGER: Hazardous voltage An all-pos. fuse must be present for operation on two outer conductors of a three-phase system. Protection for AC supply Figure 18 Pin assignment for AC supply voltage 9.3 Output By default, the power supply is pre-set to a nominal output voltage of 48 V DC. The output voltage is adjusted via the two arrow keys (-) and (+) on the front of the power supply. When you press the arrow key once briefly, the output voltage is reduced (-) or increased (+) by 3 mV. When you press the arrow key for longer, the voltage is adjusted in 100 mV increments. 9.4 Protection of the secondary side The power supply is electronically short-circuit-proof and no-load-proof. In the event of an error, the output voltage is limited Input AC 100...240 V L If sufficiently long connecting cables are used, fuse protection does not have to be provided for each individual load. L N PE N PE N/- L/+ If each load is protected separately with its own protective device, the selective shutdown in the event of a fault enables the system to remain operational. Protection for DC supply Figure 19 Pin assignment for DC supply voltage Input DC 110...250 V + + - - PE N/- L/+ DC applications require upstream installation of a fuse that is permitted for the operating voltage. 109981_en_00 PHOENIX CONTACT 26/51 QUINT4-PS/1AC/48DC/20 10 Output characteristic curves This section describes the various output characteristic curves together with their areas of application for customization to your specific application. The U/I Advanced characteristic curve is set by default. M Application Normal load Your benefits Reliable power supply System extension + - Loads with high inrush Energy storage charging current A stable 24 V, even in the No over-dimensioned power supply unit event of a sustained required overload Fast charging Selective tripping of fuses Keeps temperatures low in the event of faults Short circuit, non-fused Parallel loads continue working Low thermal stress in the even of faults Enables configuration without fuse Characteristics - U/I Advanced - Smart HICCUP - FUSE MODE Symbol - - - Designation Suitable for the application - 109981_en_00 Not suitable for the application PHOENIX CONTACT 27/51 QUINT4-PS/1AC/48DC/20 U/I Advanced output characteristic curve The preset U/I Advanced output characteristic curve is optimized for the following applications: – For selective tripping of standard circuit breakers (SFB technology). The power supply supplies up to 6 times the nominal current for 15 ms. Loads connected in parallel continue working. – When supplying loads with high switch-on currents, such as motors. The dynamic boost of the power supply supplies up to 200% of the nominal power for 5 s. This ensures that sufficient reserve energy is available; overdimensioning of the power supply is not necessary. – For system extension. With the static boost, up to 125% of the nominal output power is available for a sustained period (up to 40°C). – For fast energy storage charging (e.g., of batteries) to supply a wide range of loads. The power supply operates in the nominal operating range. Energy supply to the load is ensured.   Figure 20 10.2 Smart HICCUP output characteristic curve The SMART HICCUP output characteristic curve keeps the thermal load of the connecting cables at a low level in the event of a sustained overload. If loads are not protected or are protected in a way that is not permitted, the loads are supplied for 2 s. The DC output of the power supply is then switched off for 8 s. This procedure is repeated until the cause of the overload has been remedied. The Smart HICCUP output characteristic curve is optimized for the following applications: – If only a low short-circuit current is permitted. – If following an overload or short circuit the output voltage should be made available again automatically. Figure 21   10.1 Smart HICCUP output characteristic curve     U/I Advanced output characteristic curve                                         109981_en_00  PHOENIX CONTACT 28/51 QUINT4-PS/1AC/48DC/20 10.3 FUSE MODE output characteristic curve In the event of an overload (e.g., short circuit), the power supply switches off the DC output permanently. The value of the switch-off threshold and the time period for which it may be exceeded can be freely selected. The power supply is restarted via the remote contact. As an option, the power supply can be switched on by switching the supply voltage on the primary side off and on. Selecting the FUSE MODE output characteristic curve sets the following default values. – tFuse = 100 ms – IFuse = IN FUSE MODE output characteristic curve IOut [A] Figure 22 IFuse 0 tFuse t [s] 109981_en_00 PHOENIX CONTACT 29/51 QUINT4-PS/1AC/48DC/20 Configuring the power supply With the fourth generation of the QUINT POWER power supply, it is now possible for the first time to adapt the behavior of the power supply. In addition to setting the output voltage and selecting the output characteristic curves, you can configure signal outputs Out 1, Out 2, and floating signal contact 13/14, for example. Configuration of the remote input for controlling the power supply or specification of signal options and signal thresholds also extend the range of possible applications. The power supply is configured via the device's internal NFC (near field communication) interface. This is located behind the QR code on the front. 11.2 To configure the power supply, proceed as follows: – Before you can configure the power supply, it should either be disconnected from the supply voltage or switched to SLEEP MODE. – To switch the power supply to SLEEP MODE, use one of the external circuits. The following connection versions are possible between the Rem (remote input) and SGnd (signal ground) connection terminal blocks. Figure 23 In order to configure the power supply via the NFC interface, the following hardware and software requirements must be met: – PC or notebook (as of Windows 7, Microsoft.Net Framework 4.5, USB 2.0 interface, 50 MB hard disk capacity, QUINT POWER software). – Programming adapter: TWN4 MIFARE NFC USB ADAPTER (Item No. 2909681) is plugged into the USB interface. – Programming software: the QUINT POWER software has been successfully installed.        –            Hold the USB-PROG-ADAPTER in front of the mounted power supply such that the NFC antenna symbol is over the QR code. Figure 24 Configuration of the power supply QUINT POWER Ord.No.29046xx Configuration with PC software SLEEP MODE connection versions   The power supply behaves like a passive NFC tag. An auxiliary power source is required in order to supply the power supply with configuration data. 11.1 Configuring the power supply 13 14 Rem nd SG 1 t Ou 2 t Ou l na 3.1 3.2 3.3 3.4 3.5 3.6 ost Bo % t 00 > 15% Pou > 70% > 5 OK DC x8 CONN DAT M3 Sig UOut NFC 11 – In the programming interface of the QUINT POWER software, press the [Read] button. The current device and configuration data for the power supply is read and displayed. If a connection cannot be established between the USB-PROG-ADAPTER and the power supply, more detailed information can be found in the user manual for the QUINT POWER software. For information regarding the configuration of the power supply, such as selecting the characteristic curve and output parameters, refer to the user manual for the QUINT POWER software. 109981_en_00 PHOENIX CONTACT 30/51 QUINT4-PS/1AC/48DC/20 Configuration with NFC-capable mobile terminal device The QUINT POWER app enables you to conveniently configure the power supply using a mobile terminal device, such as a smartphone. In order to configure the power supply via the NFC interface, the following hardware and software requirements must be met: – NFC-capable mobile terminal device with Android operating system as of Version 4.1.x (Jelly Bean) – QUINT POWER app (Google Play Store) For information regarding the configuration of the power supply, such as selecting the characteristic curve and output parameters, please refer to the QUINT POWER app. 11.4 Boost currents The power supply provides the static boost (IStat. Boost) for a sustained load supply or the time-limited dynamic boost (IDyn. Boost). 12.1 Static Boost For system expansion purposes, the sustained static boost (IStat. Boost) supports the load supply with up to 112% of the nominal current of the power supply. The static boost is available at an ambient temperature of up to 40°C. Figure 25    11.3 12 Performance characteristic in static boost             Ordering a configured power supply Customer-specified QUINT POWER power supplies are ordered as a KMAT item (configurable material) and are configured during the production process in the factory. The power supply is therefore supplied ready to connect for your specific application. You can type in the the web code phoenixcontact.net/webcode/#0852 to configure and order your power supply.      12.2 Dynamic Boost Dynamic boost (IDyn. Boost) delivers up to 150 % of the power supply nominal current to supply high loads. This temporary power supply to the load lasts a maximum of 5 s at an ambient temperature of up to 60 °C. The energy supplied adaptively for the load supply and the recovery time (tPause) are calculated based on the specific load situation using algorithms (see recovery time tables). IOut [A] Figure 26 IDyn.Boost IBase Load Basic curve of the dynamic boost process tDyn.Boost tDyn.Boost tPause t [s] 109981_en_00 PHOENIX CONTACT 31/51 QUINT4-PS/1AC/48DC/20 If a current that is lower than the maximum available dynamic boost current (IDyn. Boost) is required for the same period, the recovery time may (tPause) decrease. 12.2.1 Recovery times at an ambient temperature of 40 °C Required recovery times at ≤ 40°C tDyn. Boost [s] IBase Load IDyn. Boost [A] [A] 1 2 3 4 5 0 30 1,3 2,5 3,8 5,1 6,4 5 30 1,3 2,7 4,0 5,4 6,7 10 30 1,5 2,9 4,4 5,9 7,4 15 30 1,7 3,5 5,2 7,0 8,7 20 30 2,8 5,6 8,4 11,2 14,0 22,5 30 7,0 14,0 20,9 27,9 34,9 At an output current (IBase Load) of 10 A, the dynamic output current (IDyn. Boost) of 30 A increases for 2 s (tDyn. Boost). After a recovery time (tPause) of 2.9 s, the dynamic boost is available once again. Figure 29 Example recovery time for ≤ 40°C  tDyn. Boost [s] IBase Load IDyn. Boost [A] [A] 1 2 3 4 5 0 30 1,3 2,5 3,8 5,1 6,4 5 30 1,3 2,7 4,0 5,4 6,7 10 30 1,5 2,9 4,4 5,9 7,4 15 30 1,7 3,5 5,2 7,0 8,7 20 30 2,8 5,6 8,4 11,2 14,0 22,5 30 7,0 14,0 20,9 27,9 34,9 tPause [s] Figure 27 12.2.3 Example: Determining the recovery time (tPause) tPause [s] Use the following tables to determine the required recovery time (tPause) at the maximum dynamic boost current (IDyn. Boost) based on the following values: – IBase Load – Duration of the boost current (tDyn. Boost) – Ambient temperature (40 °C or 60 °C) 12.2.2 Recovery times at an ambient temperature of 60 °C Required recovery times at ≤ 60°C tDyn. Boost [s] IBase Load IDyn. Boost [A] [A] 1 2 3 4 5 0 30 1,6 3,3 5,0 6,7 8,3 5 30 1,8 3,6 5,4 7,2 9,1 10 30 2,1 4,3 6,4 8,5 10,6 15 30 2,6 4,3 7,9 10,6 13,2 20 30 11,0 22,1 33,1 44,2 55,2 109981_en_00 tPause [s] Figure 28 PHOENIX CONTACT 32/51 QUINT4-PS/1AC/48DC/20 13 SFB Technology 13.3 SFB Technology (selective fuse breaking) can be used to quickly and reliably trip miniature circuit breakers and fuses connected on the secondary side. In the event of a short circuit on the secondary side, the power supply supplies up to 6 times the nominal current for 15 ms. The faulty current path is switched off selectively. Loads that are connected in parallel are still supplied with energy. Operation of these system parts is ensured. In order to always enable the reliable tripping of circuit breakers and fuses, certain framework conditions must be observed (see SFB configuration section). Observe the following framework conditions for determining the maximum distance between the power supply and load: – The performance class of the power supply – The cross section of the connecting cable – The tripping characteristic of the fuse component Figure 31 Schematic diagram of the maximum cable length Power supply unit + + - - Load l The U/I Advanced output characteristic curve supports SFB Technology. 13.1 SFB configuration Tripping circuit breakers The circuit breaker is tripped by the high SFB current of the power supply, typically within 3 to 5 ms. As a result, voltage dips at loads that are connected in parallel are avoided. I [A] Figure 30 SFB pulse trips circuit breakers 6x IN typ. 3 - 5 ms IN 0 13.2 t [s] Tripping a fuse Fuses are tripped by melting the predetermined breaking point inside the fuse capsule. The tripping characteristic of the fuse is described by the melting integral (I²t). A high current is crucial in order to achieve a very short tripping time. 109981_en_00 PHOENIX CONTACT 33/51 QUINT4-PS/1AC/48DC/20 13.4 Maximum distance between the power supply and load The distances given in the table are worst-case values and therefore cover the entire tolerance range for the magnetic tripping of circuit breakers. The possible distances are often greater in practice. 13.4.1 Thermomagnetic device circuit breaker, type: Phoenix Contact CB TM1 SFB Maximum distance l [m] with device circuit breaker     Phoenix Contact CB TM1 1A SFB P CB TM1 2A SFB P CB TM1 3A SFB P CB TM1 4A SFB P CB TM1 5A SFB P CB TM1 6A SFB P CB TM1 8A SFB P CB TM1 10A SFB P CB TM1 12A SFB P CB TM1 16A SFB P Conductor cross section A [mm²] AWG 0.75 19 77 44 30 23 16 11 6 4 3 1 1.0 18 75% POut > 50% DC OK 1 2 3 4 5 Key No. 1 2 3 4 5 6 7 8 9 109981_en_00 Position of signaling elements UOut 56V The current device status of the power supply is signaled using four LED status indicators. The function of each LED status indicator is assigned to a fixed event. The signal outputs are configured on the software side using the QUINT POWER software or the QUINT POWER app. Upon delivery, the power supply is pre-allocated a default configuration for the signal outputs. Location and function of the signaling elements Signaling elements 13/14 floating switch contact (N/O contact) Rem, remote input (switch power supply off and on) SGnd, signal ground (reference potential for signals Out 1, Out 2) Out 1 (digital output, function depends on the signal option set) Out 2 (digital or analog output, function depends on the signal option set) LED status indicator DC OK LED on: UOut > 90% x USet LED flashing: UOut 50 % (output power >480 W) LED status indicator POut >75 % (output power >720 W) LED status indicator POut >100 %, boost mode (output power >960 W) PHOENIX CONTACT 38/51 QUINT4-PS/1AC/48DC/20 14.1.1 Floating signal contact In the default configuration, the floating switch contact opens to indicate that the set output voltage has been undershot by more than 10 % (UOut  75%  LED lights up green in addition to the > 50%  LED. If the required output power is then greater than the nominal device power, the power supply operates in boost mode. In boost mode, the > 100% LED additionally lights up yellow.    109981_en_00            Four LED status indicators are integrated in the front of the power supply, which indicate the current device state.   External wiring versions with PNP and NPN output   14.5       Figure 38     When using a PLC output, select the following external circuit version to switch the power supply to SLEEP MODE.   PHOENIX CONTACT 42/51 QUINT4-PS/1AC/48DC/20 14.6 U/I Advanced characteristic curve signaling The following table shows the standard assignment for signaling for the U/I Advanced characteristic curves which is set by default. Figure 39 Signal image for U/I Advanced LED: POut >100 % yellow Signal Out 2: POut < PN Default Normal operation BOOST Overload operation POut < PN POut > PN UOut < 0.9 x USet Active High Active Low Active Low closed closed open Active High Active High Active Low LED: POut > 75 % LED: POut > 50 % green LED: DC OK Relay: 13/14, DC OK Default Signal Out 1: DC OK LED off 14.7 LED on LED flashing Smart HICCUP characteristic curve signaling The following table shows the standard assignment for signaling for the Smart HICCUP characteristic curve. Figure 40 Signal image for Smart HICCUP LED: POut >100 % Signal Out 2: POut < PN Normal operation BOOST Overload operation POut < PN POut > PN UOut < 0.9 x USet Active High Active Low Active Low Yellow Default LED: POut > 75 % LED: POut > 50 % Green LED: DC OK Closed Relay: 13/14, DC OK Closed Open Default Signal Out 1: DC OK Active High LED off 109981_en_00 LED on Active High Active Low LED flashing PHOENIX CONTACT 43/51 QUINT4-PS/1AC/48DC/20 14.8 FUSE MODE characteristic curve signaling The following table shows the standard assignment for signaling for the FUSE MODE characteristic curve. Figure 41 Signal image for FUSE MODE LED: POut >100 % Yellow Signal Out 2: POut < PN Default Normal operation BOOST POut < PN POut > PN Active High Active Low Active Low Closed Closed Open Active High Active High Active Low FUSE MODE I > IFuse for t > tFuse LED: POut > 75 % LED: POut > 50 % Green LED: DC OK Relay: 13/14, DC OK Default Signal Out 1: DC OK LED off 14.9 LED on LED flashing SLEEP MODE signaling In SLEEP MODE, all LEDs are off, all signals are low, and the relay switching contact is open. 109981_en_00 PHOENIX CONTACT 44/51 QUINT4-PS/1AC/48DC/20 14.10 Special immunity for the signal level 14.10.1 Surge protection for the high-voltage area at the power plant Surge protection (Phoenix Contact Item No.: 2907925 or comparable protection) must be implemented for power plant applications when using signal connection types t (telecommunications area), h (high voltage area) or f (field) in accordance with IEC/EN 61850-3 or signal connection types 3 (process area) and 4 (high voltage area) in accordance with EN 61000-6-5. When using the digital signals, a relay (Phoenix Contact Item No.: 2900299 or a comparable relay) can be implemented. 14.10.2 Surge protection for signals in railway applications Surge protection (Phoenix Contact Item No.: 2907925 or comparable protection) must be implemented for railway applications when using signals in accordance with EN 62236-4 and EN 50121-4. When using the digital signals, a relay (Phoenix Contact Item No.: 2900299 or a comparable relay) can be implemented. 14.10.3 Surge protection for devices in use in safety-related systems Surge protection (Phoenix Contact Item No.: 2907925 or comparable protection) must be implemented for railway applications when using signals in accordance with EN 61000-6-7 for devices provided to perform functions in safety-related systems (functional safety) in industrial settings. When using the digital signals, a relay (Phoenix Contact Item No.: 2900299 or a comparable relay) can be implemented. Figure 42   Schematic diagram, signal wiring with TRABTECH surge protection  !          " " " " " "#                    Figure 43   Schematic diagram, signal wiring with relay module  !                109981_en_00 " " " " " "#                 PHOENIX CONTACT 45/51 QUINT4-PS/1AC/48DC/20 15 Operating modes 15.1 Series operation 15.2 To double the output voltage, connect two power supplies in series. Only use power supplies with the same performance class and configuration for series operation. If two 48 V DC power supplies are connected in series, an output voltage of 96 V DC is available to supply the loads. Figure 44 Parallel operation You can connect several power supplies in parallel in order to increase the power or to supply the loads redundantly. Figure 45 Schematic diagram in parallel operation IN IN + ̐ + ̐ Schematic diagrams in series operation + + - - + ̐ + +48 V - +96 V -96 V + + - - -48 V + - + ̐ Ǟ = IN Observe the following points when carrying out parallel connection: 1. Use power supplies of the same type and performance class 2. Setting the same output voltages 3. Using the same cable cross sections for wiring 4. Using the same cable lengths for the DC convergence point 5. Operating power supplies in the same temperature environment 6. When three or more power supplies are connected in parallel, each output must be protected (e.g., with circuit breakers, fuses or decoupling modules) We recommend the configuration "parallel operation" for a parallel connection. For more detailed information on the operating mode for parallel operation, refer to the user manual for the QUINT POWER software or the QUINT POWER app. 109981_en_00 PHOENIX CONTACT 46/51 QUINT4-PS/1AC/48DC/20 15.2.1 Redundancy operation Redundant circuits are suitable for supplying systems and system parts which place particularly high demands on operational reliability. If energy is to be supplied to the load with 1+1 redundancy, two power supplies of the same type and performance class must be used. In the event of an error, it must be ensured that one of the power supplies is able to provide the total required power for the load. This means that in redundancy mode, two 20 A power supplies supply a load with a nominal current of 20 A, for example. During normal operation of the power supplies, each power supply therefore supplies 10 A. 15.2.2 Increased power When n power supplies are connected in parallel, the output current is increased to n x IN. Parallel connection for increased power is used when extending existing systems. If the individual power supply does not cover the current consumption of the most powerful load, parallel connection of power supplies is recommended. When three or more power supplies are connected in parallel, each output must be protected separately, e.g., by a circuit breaker, fuse or decoupling module such as QUINT ORING, QUINT S-ORING or QUINT DIODE. Always use cables with the same cross sections and lengths when wiring the power supplies on the DC output side. Redundancy modules can be used to fully decouple two power supplies from one another and to ensure the supply. Optimum decoupling can be achieved with the QUINT DIODE redundancy module. Figure 46 Figure 47 IN IN + ̐ + ̐ + ̐ IN + – Schematic diagram, redundant operation with QUINT DIODE IN Schematic diagram of increased performance + – + – + – + ̐ IǞ= 2 x IN Ǟ = IN Certain specifications apply in redundancy operation with regard to the configuration of the keepout areas. In redundancy operation, the power supplies are operated with maximum half the nominal power. The keepout areas are therefore reduced. Using the signaling settings, you can monitor whether both power supplies are being operated with ≤ half the nominal load. In the case of system extension, an overload is prevented if one of the power supplies fails. 109981_en_00 PHOENIX CONTACT 47/51 QUINT4-PS/1AC/48DC/20 Derating 16.3 The QUINT POWER power supply runs in nominal operation without any limitations. For operation outside the nominal range, the following points should be observed depending on the type of use. 16.1 Ambient temperature When operating the power supply at an ambient temperature of > 60 °C, a power derating of 2.5 %/K should be observed. Up to an ambient temperature of 40 °C, the power supply can take power from the static boost for a sustained period. In the 40 °C to 60 °C temperature range, the power supply can output more than the nominal power for a sustained period.    Figure 48 Output power depending on the ambient temperature  Installation height The power supply can be operated at an installation height of up to 2000 m without any limitations. Different data applies for installation locations above 2000 m due to the differing air pressure and the reduced convection cooling associated with this (see technical data section). The data provided is based on the results of pressure chamber testing performed by an accredited test laboratory. Figure 49 POut [%] 16 Output power depending on the installation height 175 ĵ 150 125 Ĵ 100 75  25 0 ij ij = PN 100 % ç 60 °C Ĵ = PStat.112 % ç 40 °C ĵ = PDyn. 150 % ç 60 °C 50 0 1000 2000 3000 4000       5000 H [m]          16.2 Input voltage UIn < 100 V AC < 110 V DC < 115 V AC < 110 V DC 109981_en_00 Derating 1 %/V TA IOut ≤ 60 °C IN ≤ 40 °C IStat. Boost UOut 48 V DC PHOENIX CONTACT 48/51 QUINT4-PS/1AC/48DC/20 16.4 Position-dependent derating The fanless convection-cooled power supply can be snapped onto all DIN rails according to EN 60715. The power supply should be mounted horizontally for heat dissipation reasons (AC connection terminal blocks facing downward). Please observe the derating for any mounting other than the normal mounting position. Reduce the output power based on the prevailing ambient temperature. The recommended output power for different mounting positions and ambient temperatures can be found in the characteristic curves below. Exceeding these values will reduce the service life of the power supply. '()*+, -#%)%$.&//  0 2 16.4.1 Normal mounting position            ! " #    $                % %$ % % % %&                         012   Pout [%] 16.4.2 Rotated mounting position 90° Z-axis 175 ĵ 150 Ĵ 125 100 75 M 3x 8 50 25 INT UOut Signal 13 3.1 14 3.2 Rem 3.3 SGnd 3.4 Out 1 3.5 Out 2 3.6 > 100% Boost > 75% P out > 50% DC OK Y QU POW ER Ord .No. 2904 6xx ij = PN 100 % Ĵ = PStat.112 % ĵ = PDyn. 150 % 0 -25 0 10 20 ij 30 40 50 60 70 80 ă [°C] Z X 109981_en_00 PHOENIX CONTACT 49/51 QUINT4-PS/1AC/48DC/20 & 02 16.4.3 Rotated mounting position 180° Z-axis          %!   %    !!  "#   &  $    %  ' ( )* + &   &    % % %% % / +. ),- &                          01#2   Pout [%] 16.4.4 Rotated mounting position 270° Z-axis 175 ĵ 150 Ĵ 125 100 3.1 3.2 3.3 3.4 3.5 3.6 50 > 100% Boost > 75% > 50% Pout DC OK OW E o.2 9 x 6x 04 UOut 13 14 Rem SGnd Out 1 Out 2 INT P rd.N RO Y QU Signal 75 25 ij = PN 100 % Ĵ = PStat.112 % ĵ = PDyn. 150 % 0 -25 0 10 20 ij 30 40 50 60 70 80 ă [°C] Z X 109981_en_00 PHOENIX CONTACT 50/51 QUINT4-PS/1AC/48DC/20 '  ()  *    + ,   - ! ) ! . " // 16.4.5 Rotated mounting position 90° X-axis   #$ " !  !  ! !  !  0 2  &  % !                                                           012    Pout [%] 16.4.6 Rotated mounting position 270° X-axis 175 ĵ 150 Ĵ 125 100 75 50 25 ij = PN 100 % Ĵ = PStat.112 % ĵ = PDyn. 150 % 0 -25 0 10 20 ij 30 Y 40 50 60 70 80 ă [°C] Z X 109981_en_00 PHOENIX CONTACT GmbH & Co. KG • 32823 Blomberg • Germany phoenixcontact.com 51/51