EE-SX4235A_DS_C_1_1

安徽富信半导体科技有限公司ANHUI FOSAN SEMICONDUCTOR TECHNOLOGY CO.,LTD.2SC2873SOT-89Bipolar Transistor双极型三极管▉Features特点NPN High Speed Switching高速开关Low Saturation Voltage低饱和压降▉Absolute Maximum Ratings最大额定值Characteristic特性参数Symbol符号Rat额定值Unit单位Collector-Base Voltage集电极基极电压V CBO50V Collector-Emitter Voltage集电极发射极电压V CEO50V Emitter-Base Voltage发射极基极电压V EBO5V Collector Current集电极电流I C2000mA Power dissipation耗散功率P C(T a=25℃)500mW Thermal Resistance Junction-Ambient热阻RΘJA250℃/WJunction and Storage TemperatureT J,T stg-55to+150℃结温和储藏温度■Device Marking产品打标H FE70-140(O)120-240(Y)Mark MO MYANHUI FOSAN SEMICONDUCTOR TECHNOLOGY CO.,LTD.2SC2873■ElectricalCharacteristics 电特性(T A =25℃unless otherwise noted 如无特殊说明，温度为25℃)Characteristic 特性参数Symbol 符号Min 最小值Type 典型值Max 最大值Unit 单位Collector-Base Breakdown V oltage集电极基极击穿电压(I C =100µA ，I E =0)BV CBO 50——V Collector-Emitter Breakdown Voltage 集电极发射极击穿电压(I C =1mA ，I B =0)BV CEO 50——V Emitter-Base Breakdown V oltage发射极基极击穿电压(I E =100µA ，I C =0)BV EBO 5——V Collector-Base Leakage Current集电极基极漏电流(V CB =50V ，I E =0)I CBO ——100nA Emitter-Base Leakage Current发射极基极漏电流(V EB =5V ，I C =0)I EBO ——100nADC Current Gain(V CE =2V ，I C =500mA)直流电流增益(V CE =2V ，I C =2000mA)H FE 7020—240Collector-Emitter Saturation Voltage集电极发射极饱和压降(I C =1000mA ，I B =50mA)V CE(sat)——500mV Base-Emitter Saturation V oltage基极发射极饱和压降(I C =1000mA ，I B =50mA)V BE(sat)——1200mV Turn-on Time 开通时间(V CC =50V,I C =700mA,I B1=-I B2=70mA)t on —80—ns Storage Time 贮存时间(V CC =50V,I C =700mA,I B1=-I B2=70mA)t s —750—ns Fall Time 下降时间(V CC =50V,I C =700mA,I B1=-I B2=70mA)t f—40—ns Transition Frequency特征频率(V CE =2V ，I C =500mA)f T —120—MH Z Output Capacitance输出电容(V CB =10V ，I E =0,f=1MH Z )C ob—30—pFANHUI FOSAN SEMICONDUCTOR TECHNOLOGY CO.,LTD.2SC2873■Typical Characteristic Curve典型特性曲线ANHUI FOSAN SEMICONDUCTOR TECHNOLOGY CO.,LTD.2SC2873■Dimension外形封装尺寸。

产品概述：RM9005E 是单通道调光LED 恒流驱动控制芯片，可直接驱动高压LED 灯串，输出电流由外接SENSE 电阻设置，输出电流范围在5mA~80mA，且输出电流恒定在设定值。

芯片系统结构简单，外围元器件极少，线路简单。

应用领域：⏹LED 日光灯管T5/T8/T10…⏹LED 球泡灯/玉米灯/蜡烛灯…⏹其它小功率的LED 照明典型特点：⏹外围电路简单，无需磁性元件⏹支持可控硅调光应用⏹多芯片串联或并联应用⏹芯片可与LED 共用PCB 板⏹LED 电流可外部设定⏹芯片应用线路无EMI 问题⏹内置600V 高压MOS ⏹芯片具有过温调节能力⏹采用ESOP8封装管脚定义：GND 12 S13 GND 4 S25D26NC 7D18NC U49005RM9005E管脚说明：管脚名称管脚描述D1，D2芯片正极GND 芯片负极（接地端）S1，S2芯片电流采样端NC无定义管脚典型应用：C1R1D1-+LED1LED2LEDNR2NLRM9005D 1D 2S1S 2GNDRS2RS1R3图1:典型驱动方案极限参数：符号参数参数范围S1电流采样输入电压-0.3v to7vTJ工作结温范围-40℃to150℃Tc工作温度-40℃to100℃TSTG储存温度范围-55℃to150℃注：极限值是指超出该工作范围，芯片有可能损坏。

推荐工作范围是指在该范围内，器件功能正常，但并不完全保证满足个别性能指标。

电气参数定义了器件在工作范围内并且在保证特定性能指标的测试条件下的直流和交流电参数规范。

对于未给定上下限值的参数，该规范不予保证其精度，但其典型值合理反映了器件性能。

电气参数：(无特别说明情况下，TA=25℃)符号参数条件最小值典型值最大值单位Von1工作电压最小值S1=30mA6--V Von2工作电压最小值S1=30mA7--V VDS1驱动端峰值电压600--V VDS2驱动端峰值电压600--VIS1工作电流环境温度100℃5-80mA IS2工作电流环境温度100℃6-80mA Vref1恒流电压基准25℃-0.6-V Vref2恒流电压基准25℃-0.6-V Idd1静态工作电流Vd=10V-0.3-mA Idd2静态工作电流Vd=10V-0.3-mA OTP过温调节点-130-℃订购信息：订购型号封装形式包装方式卷盘尺寸编带RM9005E ESOP-84000只/盘13寸。

RoboClaw ST 2x45A, 34VDC Dual Channel Brushed DC Motor ControllerData Sheet Version 2.3Feature Overview:• 45 Amps Continuous Per Channel• 60 Amps Peak Per Channel• Screw Terminal Inputs• Channel Bridging Supported• Dual Quadrature Decoding• 9.8 million PPS Decoding• Multimode Interface• TTL Serial• USB Port• Analog Interface• R/C Input Control• Limit, Home and E-Stops• Up to 34VDC Operation• Cooling Fan With Automatic Control• 3.3v Compliant Control Outputs• 5v Tolerant Control Inputs• Programmable Current Limiting• Programmable Voltage Clamping• Closed and Open Loop Operation• Auto Tuning PID Feature• Mixed Control Modes• Data Logging• Diagnostic LEDs• Field Firmware Updates• Regulated 5VDC, 3A User Available Output• Over Voltage and Under Voltage Protection• Easy Tuning, Monitor and Setup with PC utilityDevice OverviewThe RoboClaw is an intelligent, high performance motor controller designed to control dual brushed DC motors. It can be controlled from USB, RC radio, PWM, TTL serial, analog and microcontrollers such as an Arduino or Raspberry Pi.RoboClaw automatically supports 3.3V or 5V logic levels, travel limit switches, home switches, emergency stop switches, power supplies, braking systems and contactors. A built-in switching mode BEC supplies 5VDC at up to 3 Amps for powering user devices. In addition power supplies can be utilized by enabling the built in voltage clamping control feature.A wide variety of feedback sensors are supported. This includes quadrature encoders, potentiometers and absoluteencoders which can be easily configured using the available auto tune function. With sensors, two brushed DCmotors can be controlled in closed loop mode allowing precise control over position and speed. With the ability to use potentiometers, servo systems can be created and controlled from any of RoboClaw’s interface modes.For greater control, built-in commands are available for controlling acceleration, deceleration, distance, speed, current sense, voltage limits and more. In addition, RC and analog modes can be configured by user defined settings to control acceleration and deceleration rates.RoboClaw incorporates multiple protection features including temperature, current, over voltage and under voltage limits.The protection features are self monitoring and protect RoboClaw from damage in any operating condition. User definable settings such as maximum current limit, maximum and minimum battery voltages are provided for more refined control.RoboClaw’s regenerative capabilities will charge a supply battery during slow down or breaking. It’s advance circuitry can change direction during full throttle without damage! RoboClaw also incorporates a LiPo cutoff mode to prevent battery damage.Multimode InterfaceRoboClaw’s I/O are voltage protected and can handle up to 5VDC. The I/O only output a high of 3.3V. This allows RoboClaw to be interfaced to 5V or 3V logic easily with no translation circuits required. RoboClaw can be connected directly to a Raspberry Pi or Arduino. All of RoboClaw’s inputs are internally pulled-up to prevent false triggers. Inputs can also be configured using the Motion Studio application.User Regulated Power OutputRoboClaw provides regulated power (BEC) for user devices. A high efficiency switching regulator supplies 5VDC at up to3 Amps. This voltage can be used to power external sensors, encoders, MCUs and other electronics. The regulated userpower is automatically current limited and thermally protected.Main BatteryThe peak operational input voltage depending on the model can be up to 34VDC, 60VDC or 80VDC. The modelsmaximum input voltage can not be exceeded. If the maximum voltage is exceed the motors will be disabled. Fully charged batteries maximum voltage must be taken into account when in use. RoboClaw is a regenerative motor controller. During regeneration, voltages can peak over the maximum rated voltage in which RoboClaw is designed to handle these over voltage spikes by braking the motors.Logic BatteryRoboClaw accepts a logic battery. The logic battery is also known as a backup battery. The user regulated power output (BEC) is by default powered from the main battery, unless a logic battery is detected. The logic battery source is coupled to the main battery through an on board automatic switch. If the main battery voltage drops below the logic battery input level, the logic circuit and user regulated power output will be drawn from the logic battery.SoftwareRoboClaw can be easily configured using the Motion Studio software tool. The Windows based application enables users to quickly configure RoboClaw. The software can be used during run time to monitor and control several operational parameters. Motion studio is available from the website. It can also be found in the Downloads section of the Basicmicro website or listed under the Download tabs on the production page.User ManualThis data sheet only covers model specific information and basic wiring. To properly setup and use RoboClaw refer to the RoboClaw User Manual available for download from .CoolingRoboClaw will generate heat. The maximum current ratings can only be achieved and maintained with adequate heat dissipation. The motor controller should be mounted so that sufficient airflow is provided. Which will dissipate the heat away from the motor controller during operation. Some models of RoboClaw include a built-in automatic cooling fan controller, which can be used to help maintain continuous currents under extreme conditions.Emergency StopThe motor controller should be wired using an external contactor, relay or high amperage mechanical switch to control the main power input. A second power source should be used to power the logic section in situations where the main power will be under heavy load. Voltage drops can occur from constant full load or high speed direction changes. Voltage drop can cause logic brown outs if only a main battery is used without a logic battery.USBThe motor controllers USB port should be used for configuration and debugging. The USB protocol is not designed for electrically noisy environments. The USB port will likely disconnect and not automatically recover during operation in electrically noisy environments. To recover from a dropped USB port, the motor controllers USB cable may require being unplugged and re-plugged in. The TTL serial control should be the preferred method of control in electrically noisy environments.Firmware UpdatesFirmware updates will be made available to add new features or resolve any technical issue. Before using RoboClaw for the first time it is recommended to update to the latest firmware. Download and install Motion Studio. Refer to the RoboClaw User Manual or Application Notes for additional information on updating the RoboClaw firmware.Hardware Overview:Control InterfaceThe RoboClaw ST uses standard screw terminals (2.54mm) spacing. The table below list the pins and their respectivefunctions. All pins are 5V tolerant and output 3.3V for compatibility with processor such as Raspberry Pi and Arduino. R/C pulse input, Analog and TTL can be generated from any microcontroller such as a Arduino or Raspberry Pi. The R/C Pulse input pins can also be driven by any standard R/C radio receiver . There are several user configurable options available. Toconfigure RoboClaw, install Motion Studio and connect it to an available USB port.Logic Battery (LB IN)The logic circuit of RoboClaw can be powered from a secondary battery wired to LB IN. A logic battery will prevent brownouts when the main battery is low or under heavy load. The positive (+) terminal is located at the board edge and ground (-) is the inside pin closest to the heatsink.Encoder Inputs (1A / 1B / 2A / 2B)The encoders inputs are labeled 1B, 1A, 2B and 2A. 1B and 1A are the inputs for encoder 1. 2B and 2A are the inputs for encoder 2 which also correspond to motor channel 1 and motor channel 2. Quadrature encoder inputs are typically labeled 1A, 1B, 2A and 2B. Quadrature encoders are directional. When connecting encoders make sure the leading channel for the direction of rotation is connected to A. If one encoder is backwards to the other you will have one internal counter counting up and the other counting down. Use Motion Studio to determine the encoders direction relative to the motors rotation. Encoder channels A and B can be swapped in software using Motion Studio to avoid re-wiring the encoder or motor.Control Inputs (S1 / S2 / S3 / S4 /S5)S1, S2, S3, S4 and S5 are configured for standard servo style headers I/O (except on ST models), +5V and GND. S1 and S2 are the control inputs for serial, analog and RC modes. S3 can be used as a flip switch input, when in RC or Analog modes. In serial mode S3, S4 and S5 can be used as emergency stops inputs or as voltage clamping control outputs.When configured as E-Stop inputs, they are active when pulled low. All I/O have internal pull-ups to prevent accidental triggers when left floating. S4 and S5 can be configured as home switch and limit switch inputs. The pins closest to the board edge are the I/0s, center pin is the +5V and the inside pins are ground. Some RC receivers have their own supply and will conflict with the RoboClaw’s 5v logic supply. It may be necessary to remove the +5V pin from the RC receivers cable in those situations.Cooling Fan ControlThe cooling fan control will automatically turn on and off a fan based on RoboClaws temperature. The fan will turn on when the board temperature reaches 45°C and will automatically turn off when the board temperature falls below 35°C.The fan control circuit can power a 5VDC fan at up to 230mA. A wide range of fans can be used. The CFM rating of the fan will determine how effective the fan is at cooling. A tested fan is available from DigiKey under part number:259-1577-ND. However any fan can be used provided it meets the electrical specifications outlined above.Main Battery Screw TerminalsThe main power input can be from 6VDC to 34VDC on a standard RoboClaw and 10.5VDC to 60VDC or 80VDC on an HV (High Voltage) RoboClaw. The connections are marked + and - on the main screw terminal. The plus (+) symbol marks the positive terminal and the negative (-) marks the negative terminal. The main battery wires should be as short as possible.Do not reverse main battery wires or damage will occur.DisconnectThe main battery should include a quick disconnect in case of a run away situation and power needs to be cut. The switch must be rated to handle the maximum current and voltage from the battery. Total current will vary depending on the type of motors used. A common solution would be an inexpensive contactor which can be sourced from sites like Ebay.A power diode rated for approximately 2 to 10 Amps should be placed across the switch/contactor to provide a return tothe battery when power is disconnected. The diode will provide the regenerative power a place to go even if the switch is open.Motor Screw TerminalsThe motor screw terminals are marked with M1A / M1B for channel 1 and M2A / M2B for channel 2. For a typical differential drive robot the wiring of one motor should be reversed from the other. The motor and battery wires should be as short as possible. Long wires can increase the inductance and therefore increase potentially harmful voltage spikes.Control ModesRoboClaw has 4 main functional control modes explained below. Each mode has several configuration options. The modes can be configured using Motion Studio or the built-in buttons. Refer to the RoboClaw User Manual for installation and setup instructions.RCUsing RC mode RoboClaw can be controlled from any hobby RC radio system. RC input mode also allows low powered microcontrollers such as a Basic Stamp to control RoboClaw. Servo pulse inputs are used to control the direction and speed. Very similar to how a regular servo is controlled. Encoders are supported in RC mode, refer to the RoboClaw user manual for setup instructions.AnalogAnalog mode uses an analog signal from 0V to 2V to control the speed and direction of each motor. RoboClaw can be controlled using a potentiometer or filtered PWM from a microcontroller. Analog mode is ideal for interfacing RoboClaw with joystick positioning systems or other non microcontroller interfacing hardware. Encoders are supported in Analog mode, refer to the RoboClaw user manual for setup instructions.Simple SerialIn simple serial mode RoboClaw expects TTL level RS-232 serial data to control direction and speed of each motor.Simple serial is typically used to control RoboClaw from a microcontroller or PC. If using a PC, a MAX232 or an equivalent level converter circuit must be used since RoboClaw only works with TTL level inputs. Simple serial includes a slave select mode which allows multiple RoboClaws to be controlled from a signal RS-232 port (PC or microcontroller). Simple serial is a one way format, RoboClaw can only receive data. Encoders are not supported in Simple Serial mode.Packet SerialIn packet serial mode RoboClaw expects TTL level RS-232 serial data to control direction and speed of each motor. Packet serial is typically used to control RoboClaw from a microcontroller or PC. If using a PC a MAX232 or an equivalent level converter circuit must be used since RoboClaw only works with TTL level input. In packet serial mode each RoboClaw is assigned a unique address. There are 8 addresses available. This means up to 8 RoboClaws can be on the same serial port. Encoders are supported in Packet Serial mode, refer to the RoboClaw user manual for setup instructions.USB ControlUSB can be used in any mode. When RoboClaw is in packet serial mode and another device, such as an Arduino, is connected commands from the USB and Arduino will be executed and can potentially override one another. However if RoboClaw is not in packet serial mode, motor movement commands will be overiden by Analog or RC pulse input. USB packet serial commands can then only be used to read status information and set configuration settings.There are several wiring configurations for RoboClaw. Each configuration will have unique wiring requirements to ensure safe and reliable operation. The diagram below illustrates a very basic wiring configuration used in a small motor system where safety concerns are minimal. This is the most basic wiring configuration possible. All uses of RoboClaw should include some kind of main battery shut off switch, even when safety concerns are minimal. Never underestimate a system with movement when an uncontrolled situation arises.In addition, RoboClaw is a regenerative motor controller. If the motors are moved when the system is off, it could cause potential erratic behavior due to the regenerative voltages powering the system. The regenerative voltages can cause problems if a power supply is used for main power. A voltage clamping circuit is recommended to dump the excessive voltages. See the RoboClaw user manual or Application Notes for voltage clamping setup and wiring diagrams.R/C ModeThe below wiring diagram is very basic and for use with R/C mode. R/C mode can be used when pairing RoboClaw with a standard R/C receiver. R/C mode can also be used with a microcontroller and using servo pulses to control RoboClaw. The RoboClaw supplies power to the R/C system. If the R/C receiver used, has its own power the 5V pin on the 3 pin header must be remove otherwise it will interfere with RoboClaw’s BEC.In all system with movement, safety is a concern. This concern is amplified when dealing with higher voltages. The wiring diagram below illustrates a properly wired system. An external main power cut off is required (SW1). The external cut off can consist of a high amperage mechanical switch or a contactor.When the RoboClaw is switched off or a fuse is blown, a high current diode (D1) is required to create a return path to the battery for potential regenerative voltages. In addition a pre-charge resistor (R1) is required to reduce the high inrush currents to charge the on board capacitors. A pre-charge resistor (R1) should be around 1K, 1/2Watt for a 60VDC motor controller which will give a pre-charge time of about 15 seconds. A lower resistances can be used with lower voltages to decrease the pre-charge time.Closed Loop ModeA wide range of sensors are supported for closed loop operation. RoboClaw supports dual quadrature encoders (up to9.8 million PPS), absolute encoders, potentiometers and hall effect sensors. The wiring diagram below is an exampleof closed loop mode using quadrature encoders. Quadrature encoders are directional. RoboClaw’s internal counters will increment for clockwise rotation (CW) and decrement for counter clockwise rotation (CCW). When wiring encoders A andB channels it is important they are wired to match the direction of the motor. If the encoder is wired in reverse it cancause a run away condition. All motor and encoder combinations will need to be tuned (see the RoboClaw user manual).Logic BatteryAn optional logic battery is supported. Under heavy loads the main power can suffer voltage drops, causing potential logic brown outs which may result in uncontrolled behavior . A separate power source for the motor controllers logic circuit, will remedy potential problems from main power voltage drops. The logic battery maximum input voltage is34VDC with a minimum input voltage of 6VDC. The 5V regulated user output is supplied by the secondary logic battery if supplied. The mAh of the logic battery should be determined based on the load of attached devices powered by the regulated 5V user output.R1D1Bridging ChannelsRoboClaws dual channels can be bridge to run as one channel, effectively doubling its current capability for one motor.Damage will result if RoboClaw is not set to bridged channel mode before wiring. Download and install Motion Studio.Connect the motor controller to the computer using an available USB port. Run Motion Studio and in general settings check the option to combine channels. Then click “Write Settings” in the device menu. When operating in bridged mode the total peak current output is combined from both channels. Each channel will indicate the amount of current being drawn for that channel. The peak current run time is dependant on heat build up. Adequate cooling must be maintained.For more information see the RoboClaw user manual.Bridged Channel WiringWhen bridged channel mode is active the internal driver scheme for the output stage is modified. The output leads must be wired correctly or damage will result. One side of the motor is connected to M1A and M2B. The other side of the motor is then connected to M1B and to M2A.DimensionsNotes:1. Peak current is automatically reduced to the typical current limit as temperature approaches 85°C.2. Current is limited by maximum temperature. Starting at 85°C, the current limit is reduced on a slope with a maximumtemperature of 100°C, which will reduce the current to 0 amps. Current ratings are based on ambient temperature of 25°C.3. RS232 format is 8Bit, No Parity and 1 Stop bit.4. Condensing humidity will damage the motor controller.WarrantyBasicmicro warranties its products against defects in material and workmanship for a period of 1 year. If a defect is discovered, Basicmicro will, at our sole discretion, repair, replace, or refund the purchase price of the product in question.*******************************.Noreturnswillbeacceptedwithouttheproperauthorization.Copyrights and TrademarksCopyright© 2015 by Basicmicro, Inc. All rights reserved. All referenced trademarks mentioned are registered trademarks of their respective holders.DisclaimerBasicmicro cannot be held responsible for any incidental or consequential damages resulting from use of products manufactured or sold by Basicmicro or its distributors. No products from Basicmicro should be used in any medical devices and/or medical situations. No product should be used in any life support situations.ContactsEmail:********************Techsupport:**********************Web: Discussion ListA web based discussion board is maintained at Technical Support*******************************************************************,byopeningasupportticketontheIon Motion Control website or by calling 800-535-9161 during normal operating hours. All email will be answered within 48 hours.。

150W300W逆变器型号（S150-XXX S300-XXX）输入输出完全隔离设计能快速并行启动电容、电感负载三色指示灯显示,输入电压,输出电压,负载水准和故障情形负载控制风扇冷却高级微处理控制系统设计过压/欠压/短路/过载/超温保护说明型号项目S150-112 S150-124 S150-212 S150-224 S300-112 S300-124 S300-212 S300-224 输出功率150W 300W冲击功率200W 400W输入电压12V 24V 12V 24V 12V 24V 12V 24V输入电压范围10.5-15.0 21.0-30.0 10.5-15.0 21.0-30.0 10.5-15.0 21.0-30.0 10.5-15.0 21.0-30.0 输出电压110VAC±5% 230VAC±5% 110VAC±5% 230VAC±5% 频率50/60Hz±3%瞬间效率91% 92% 90% 93% 92% 93% 91% 94% 最大效率86% 87% 85% 88% 87% 88% 86% 89% 满载效率72% 79% 72% 80% 72% 78% 72% 80% 输出电流0.18A 0.15A 0.22A 0.16A 0.26A 0.23A 0.23A 0.15A 输出波形纯正弦波(失真率<4%)可允许的功率因素cosθ-90°~cosθ+90°自动保护过压/欠压/短路/过载/超温保护远程控制外接开关远程控制安规认证UL458 EN60950EN50081-1:1992EN50082-1:1992EN55022B:1994 电磁干扰FCC Class BEN61000-4-2:1995EN61000-4-3:1996ENV50204:1995工作环境温度0℃~40℃内储温度范围-30℃to70℃冷却负载控制风扇冷却尺寸237*155*72mm/9.33*6.10*2.83英寸重量 3.5公斤/7.7磅型号（S600-XXX）纯正弦波输出(失真率<3%)输出频率、开关选择:50/60hz输入输出完全隔离设计高效率设计88~94%适应于容性、感性负载三色指示灯显示,输入电压,输出电压,负载水准和故障情形适应于冲击性负载负载控制风扇冷却高级微处理控制系统设计過壓/欠壓/短路/過載/超溫保護说明型号型号型号型号型号型号项目S600-112 S600-124 S600-148 S600-212 S600-224 S600-248 输出功率600W最大输出功率680W冲击功率800W输入电压12VDC 24VDC 48VDC 12VDC 24VDC 48VDC 输出电压100/110/120VAC+-3% 220/230/240VAC+-3% 频率50/60HZ+/-0.05%满载效率87% 90% 92% 90% 93% 94% 输出电流0.87A 0.43A 0.23A 0.83A 0.43A 0.22A 输出波形纯正弦波（失真率<3%）输出电压范围100/110/120Vrms-10%+4% 220/230/240Vrms-10%+4%输入电压范围10.5-15 21.0-30 42.0-60 10.5-15 21.0-30 42.0-60 电压，负载指示LED 红色/橙色/绿色自动保护超载，过压，欠压，超温，短路，低电池等报警保护安规认证UL458 EN60950EN50081-1:1992EN50082-1:1992EN55022B:1994EN61000-4-2:1995EN61000-4-3:1996 电磁干扰FCC Class BENV50204:1995 e-Marke13-020866 工作环境温度0~50℃℃内储温度范围-30to70℃℃冷却自动控制制冷风扇尺寸295(L)*180(W)*72(H)mm /11.61(L)*7.09(W)*2.83(H)英寸重量 2.7kgs./5.4Lbs.型号（S1500-XXX）纯正弦波输出（失真率<2%）输入输出完全隔离设计RS-232C远端电脑监控设计输入电压，负载LED指示状态自动控制制冷风扇采用微处理器控制系统设计过压/欠压/短路/过载/超温保护输出电压，频率开关选择说明型号型号型号型号型号型号项目S1500-112 S1500-124 S1500-148 S1500-212 S1500-224 S1500-248 输出功率1500W冲击功率2000W输入电压12VDC 24VDC 48VDC 12VDC 24VDC 48VDC 输出电压100/110/115/120V+—3% 200/220/230/240V+-3%频率50/60HZ+/-0.05%输出电流25A 11A满载效率85% 87% 88% 86% 89% 90% 空载损耗 1.5W Saving Mode≦输出波形纯正弦波（失真率<3%）输出电压范围100/110/115/120Vrms-10%+4% 200/220/230/240Vrms-10%+4%输入电压范围10.0-16.0 20.0-32.0 42.0-62.0 10.0-16.0 20.0-32.0 42.0-62.0 自动保护超载，过压，欠压，超温，短路，低电池等报警保护省电模式恢复时间5秒面版控制端口RS-232C远端控制器任意选择安规认证UL458 EN60950EN50081-1:1992EN50082-1:1992EN55022B:1994EN61000-4-2:1995EN61000-4-3:1996 电磁干扰FCC Class BENV50204:1995e-Marke13-020932工作环境温度0~40℃℃内储温度范围-30to70℃冷却自动控制制冷风扇尺寸390(L)*275(W)*105(H}mm/15.4(L)*10.8(W)*4.1(H)Inch 重量7.0kgs/15.5lbs.型号（SK700）纯正弦波输出(失真率<3%)输出频率、开关选择:50/60Hz输入输出完全隔离设计高效率设计89-95%适应于容性、感性负载三色指示灯显示,输入电压,输出电压,负载水准和故障情形负载控制风扇冷却高级微处理控制系统设计过压/欠压/短路/过载/超温保护说明型号型号型号型号型号型号项目SK700-112 SK700-124 SK700-148 SK700-212 SK700-224 SK700-248输出功率700W最大输出功率800W冲击功率1200W输入电压12VDC 24VDC 48VDC 12VDC 24VDC 48VDC 输出电压100/110/120VAC+-3% 220/230/240VAC+-3%频率50/60HZ+/-0.05%输出波形纯正弦波（失真率<3%）满载效率89% 91% 92% 91% 93% 94% 无负载直流损耗 1.25A 0.64A 0.31A 1.20A 0.60A 0.28A 待机直流损耗0.25A 0.15A 0.08A 0.25A 0.15A 0.08A输入电压范围10.5-15 21.0-30 42.0-60 10.5-15 21.0-30 42.0-6电压，负载指示LED 红色/橙色/绿色故障指示LED 红色自动保护超载，过压，欠压，超温，短路，低电池等报警保护安规认证UL458 EN60950EN50081-1:1992EN50082-1:1992EN55022B:1994EN61000-4-2:1995EN61000-4-3:1996 电磁干扰FCC Class BENV50204:1995 e-Mark e13-02 0866工作环境温度-10℃~50℃内储温度范围-30℃to70℃冷却负载控制冷却风扇（65℃开，45℃关）尺寸295(L)*180(W)*72(H)mm /11.61(L)*7.09(W)*2.83(H)英寸型号（SK1000）纯正弦波输出(失真率<3%)输出频率、开关选择:50/60Hz输入输出完全隔离设计高效率设计89-95%适应于容性、感性负载三色指示灯显示,输入电压,输出电压,负载水准和故障情形负载控制风扇冷却高级微处理控制系统设计过压/欠压/短路/过载/超温保护说明型号型号型号型号型号型号项目SK1000-112 SK1000-124 SK1000-148 SK1000-212 SK1000-224 SK100 0-248输出功率1000W最大输出功率1150W冲击功率2000W输入电压12VDC 24VDC 48VDC 12VDC 24VDC 48VDC 输出电压100/110/120VAC+-3% 220/230/240VAC+-3%频率50/60HZ+/-0.05%输出波形纯正弦波（失真率<3%）满载效率89% 92% 93% 91% 94% 95% 无负载直流损耗 1.43A 0.75A 0.38A 1.25A 0.65A 0.38A 待机直流损耗0.25A 0.15A 0.09A 0.25A 0.15A 0.09A输入电压范围10.5-15 21.0-30 42.0-60 10.5-15 21.0-30 42.0-6电压，负载指示LED 红色/橙色/绿色故障指示LED 红色自动保护超载，过压，欠压，超温，短路，低电池等报警保护安规认证UL458 EN60950EN50081-1:1992EN50082-1:1992EN55022B:1994EN61000-4-2:1995EN61000-4-3:1996 电磁干扰FCC Class BENV50204:1995 e-Mark e13-02 0866工作环境温度-10℃~50℃内储温度范围-30℃to70℃冷却负载控制冷却风扇（65℃开，45℃关）尺寸383(L)*182(W)*88(H)mm /15.08(L)*7.17(W)*3.46(H)英寸型号（SK1500）纯正弦波输出(失真率<3%)输出频率、开关选择:50/60Hz输入输出完全隔离设计高效率设计89-95%适应于容性、感性负载三色指示灯显示,输入电压,输出电压,负载水准和故障情形负载控制风扇冷却高级微处理控制系统设计过压/欠压/短路/过载/超温保护说明型号型号型号型号型号型号项目SK1500-112 SK1500-124 SK1500-148 SK1500-212 SK1500-224 SK150 0-248输出功率1500W最大输出功率1725W冲击功率3000W输入电压12VDC 24VDC 48VDC 12VDC 24VDC 48VDC 输出电压100/110/120VAC+-3% 220/230/240VAC+-3%频率50/60HZ+/-0.05%输出波形纯正弦波（失真率<3%）满载效率88% 91% 92% 90% 93% 94% 无负载直流损耗 1.45A 0.75A 0.40A 1.40A 0.70A 0.40A 待机直流损耗0.28A 0.15A 0.09A 0.28A 0.15A 0.09A输入电压范围10.5-15 21.0-30 42.0-60 10.5-15 21.0-30 42.0-6电压，负载指示LED 红色/橙色/绿色故障指示LED 红色自动保护超载，过压，欠压，超温，短路，低电池等报警保护安规认证UL458 EN60950EN50081-1:1992EN50082-1:1992EN55022B:1994EN61000-4-2:1995EN61000-4-3:1996 电磁干扰FCC Class BENV50204:1995 e-Mark e13-02 0866工作环境温度-10℃~50℃内储温度范围-30℃to70℃冷却负载控制冷却风扇（65℃开，45℃关）尺寸415(L)*191(W)*88(H)mm /16.34(L)*7.52(W)*3.46(H)英寸型号（SK2000）纯正弦波输出(失真率<3%)输出频率、开关选择:50/60Hz输入输出完全隔离设计高效率设计89-95%适应于容性、感性负载三色指示灯显示,输入电压,输出电压,负载水准和故障情形负载控制风扇冷却高级微处理控制系统设计过压/欠压/短路/过载/超温保护说明型号型号型号型号型号型号项目SK2000-112 SK2000-124 SK2000-148 SK2000-212 SK2000-224 SK2000 -248输出功率2000W最大输出功率2300W冲击功率4000W输入电压12VDC 24VDC 48VDC 12VDC 24VDC 48VDC 输出电压100/110/120VAC+-3% 220/230/240VAC+-3% 频率50/60HZ+/-0.05%输出波形纯正弦波（失真率<3%）满载效率89% 92% 93% 91% 94% 95% 无负载直流损耗 2.8A 1.5A 0.7A 2.8A 1.5A 0.7A 待机直流损耗0.50A 0.30A 0.16A 0.50A 0.25A 0.12A输入电压范围10.5-15 21.0-30 42.0-60 10.5-15 21.0-30 42.0-6电压，负载指示LED 红色/橙色/绿色故障指示LED 红色自动保护超载，过压，欠压，超温，短路，低电池等报警保护安规认证UL458 EN60950EN50081-1:1992EN50082-1:1992EN55022B:1994EN61000-4-2:1995EN61000-4-3:1996 电磁干扰FCC Class BENV50204:1995 e-Mark e13-02 0866工作环境温度-10℃~50℃内储温度范围-30℃to70℃冷却负载控制冷却风扇（65℃开，45℃关）尺寸422(L)*208(W)*160(H)mm /16.6(L)*8.18(W)*6.30(H)英寸型号（SK3000）纯正弦波输出(失真率<3%)输出频率、开关选择:50/60Hz输入输出完全隔离设计高效率设计89-95%适应于容性、感性负载三色指示灯显示,输入电压,输出电压,负载水准和故障情形负载控制风扇冷却高级微处理控制系统设计过压/欠压/短路/过载/超温保护说明型号型号型号型号型号型号项目SK3000-112 SK3000-124 SK3000-148 SK3000-212 SK3000-224 SK300 0-248输出功率3000W最大输出功率3450W冲击功率6000W输入电压12VDC 24VDC 48VDC 12VDC 24VDC 48VDC 输出电压100/110/120VAC+-3% 220/230/240VAC+-3%频率50/60HZ+/-0.05%输出波形纯正弦波（失真率<3%）满载效率88% 91% 92% 90% 93% 94% 无负载直流损耗 2.8A 1.5A 0.7A 2.8A 1.5A 0.7A 待机直流损耗0.55A 0.35A 0.19A 0.55A 0.35A 0.19A输入电压范围10.5-15 21.0-30 42.0-60 10.5-15 21.0-30 42.0-6电压，负载指示LED 红色/橙色/绿色故障指示LED 红色自动保护超载，过压，欠压，超温，短路，低电池等报警保护安规认证UL458 EN60950EN50081-1:1992EN50082-1:1992EN55022B:1994EN61000-4-2:1995EN61000-4-3:1996 电磁干扰FCC Class BENV50204:1995 e-Mark e13-02 0866工作环境温度-10℃~50℃内储温度范围-30℃to70℃冷却负载控制冷却风扇（65℃开，45℃关）尺寸452(L)*208(W)*166(H)mm /17.8(L)*8.18(W)*6.53(H)英寸型号（ST600-2XX□）内置10A转换开关交流电源转换灵敏适应于容性、感性负载交流电源插座和接线式双模式选择过压/欠压/短路/过载/超温保护说明型号项目ST600-212 ST600-224 输出功率600W最大输出功率680W冲击功率800W输入电压12V 24V输出电压范围、频率200/220/240V±3% 50/60Hz+/-0.05% 满载效率90.0% 93.0% 输出电流0.87A 0.43A 输出波形纯正弦波(失真率<3%)可允许的功率因素cosθ-90°~cosθ+90°输入电压范围10.5-15VDC 21.0-30VDC 电压、负载指示LED 红色/橙色/绿色电源状态LED 红色/绿色自动保护超载、过压、欠压、超温、短路、低电池等报警保护熔断电流7Amp转换开关10Amp转换时间4~8msec安规认证EN60950EN50081-1:1992EN50082-1:1992EN61000-4-3:1996 电磁干扰EN61000-4-2:1995EN55022B:1994ENV50204:1995远程控制CR-8同步交流转换工作环境温度0℃-40℃℃℃内储温度范围-30to70冷却负载控制风扇冷却尺寸11.42L*7.05W*3.15H英寸重量 3.3公斤/6.6磅正弦波逆变器安全认证机种名称安规认证编码型号:S150-*** S300-***安规认证* Meet UL458 EN60950EMC（电磁兼容）认证** FCC Class B EN50081-1:1992EN50082-1:1992EN55022B:1994EN61000-4-2:1995EN61000-4-3:1996ENV50204:1995型号:S600-*** S1500-***安规认证UL458 EN60950 EMC（电磁兼容）认证FCC Class B EN50081-1:1992e-MarkEN50082-1:1992e13-020866EN55022B:1994EN61000-4-2:1995EN61000-4-3:1996ENV50204:1995MODEL:S1000-***安规认证UL458 EN60950 EMC（电磁兼容）认证FCC Class B EN50081-1:199e-MarkEN50082-1:1992 e13-020866EN55022B:1994EN61000-4-2:1995EN61000-4-3:1996ENV50204:1995MODEL:ST600-2**EMC（电磁兼容）认证FCC Class B EN60950EN50081-1:1992EN55022B:1994EN61000-4-3:1996EN50082-1:1992EN61000-4-2:1995ENV50204:199511。

温度湿度气体2015价格表德国标准 东方精神壓力照度及位移思默康自动化设备(上海)有限公司价格生效期始于2014年10月15日1.0版TRW1-Series (T)TRW2-Series (T)0…10V / 4…20mANTC / PT / NiTPS1-Series (T)0…10V / 4…20mANTC / PT / NiTOW1-Series (T)TOW2-Series (T)TDE1-Series (T_av)TDE2-Series (T_av)风管温度防凍开关TDE2-Series (T_fp)通用温度有源传感器TUU1-Series (T)0…10V / 4…20mA通用温度无源传感器TUU2-Series (T)HPS2-Series (H_cs) HPS2-Series (H_lg)GDI1-Series (VOC)0…10V湿度:0..10V温度:0..10V可选 NTC ; PT ; NiPDE1- Series (dP_r) PDI1- Series (V&T) PDE2- Series (dP) PPE1- Series ( PPE2- Series (LRC1-Series(L)10V / 4…20mA CRC8-series (L&M)照度:0...10V人体活动:ON/OFF MRW2-Series(M)asia pacific照度及位移传感器温度湿度气体壓力照度及位移价格生效期始于2014年10月15日价格表其他配件德国标准 东方精神asia pacific配件asia pacific安装套件思默康自動化設備(上海)有限公司上海市閔行區莘庄工業區春東路479號C-1廠房2樓電話: (+8621) 5176 0211傳真: (+8621) 5176 0213泰慕康传感器科技有限公司香港新界荃灣168德士古道德豐工業中心2座13/樓10-11室電話: (+852) 3468 8636傳真: (+852) 3621 0002网站: / 邮箱: info@ asia pacific声明该价格表中,对技术信息都进行了简化,并保持随时更新。