Description
The Pump 11 Elite Series of syringe pumps expands its capabilities to satisfy your experimental requirements. These compact syringe pumps carry on the tradition as the premiere workhorse infusion pump, offering unparalleled ease of use with a high resolution touch screen with intuitive icon interface.
These innovative syringe pumps have a new mechanism that includes a tight gripping, more secure syringe clamp for syringes ranging from 0.5ul to 60ml (single syringe) and 0.5ul to 10 ml (dual syringe). The Pump 11 Elite Series offers enhanced flow performance with high accuracy and smooth flow from 1.28 pl/min to 88.28 ml/min.
The Pump 11 Elite Infusion Only Models are available in single or dual syringe rack configurations. These pumps have advanced connectivity with a USB serial port for computer control and footswitch connection for stop/start control (footswitch sold separately).
Full Description
The Pump 11 Elite Series of syringe pumps expands its capabilities to satisfy your experimental requirements. These compact syringe pumps carry on the tradition as the premiere workhorse infusion pump, offering unparalleled ease of use with a high resolution touch screen with intuitive icon interface.
These innovative syringe pumps have a new mechanism that includes a tight gripping, more secure syringe clamp for syringes ranging from 0.5ul to 60ml (single syringe) and 0.5ul to 10 ml (dual syringe). The Pump 11 Elite Series offers enhanced flow performance with high accuracy and smooth flow from 1.28 pl/min to 88.28 ml/min.
The Pump 11 Elite Infusion Only Models are available in single or dual syringe rack configurations. These pumps have advanced connectivity with a USB serial port for computer control and footswitch connection for stop/start control (footswitch sold separately).
Since 1901 Harvard Apparatus has been supporting bioresearch fluidics requirements with the culmination being the introduction of the first commercial syringe pump for bioresearch in 1956. Since 1956, over 70,000 satisfied syringe pump users around the world have made Harvard Apparatus syringe pumps the worlds #1 choice.
The Pump 11 Elite Series is a family of accurate, low flow syringe pumps designed for use in applications including: mass spec calibration, drug and nutritional studies, reactor dosing, and electro-spinning.
Easy-to-Use Interface The Pump 11 Elite color LCD touch screen with graphic user interface is divided into three basic areas: Operations Display, Message Area, and Navigation. This configuration allows you to easily move through all menu selections and data entry by gently touching the onscreen buttons with a finger or the tip of a soft, non-sharp object such as a pencil eraser.
The Quick Start infusion screen is the primary “home” for the pumps. From that screen you can access all the commands needed to operate the Pump 11 Elite, as well as access the main system settings.
The Message Area of the touch screen is used to display helpful instructions for the currently displayed screen. It is also used to display error or warning messages to indicate problem conditions in a Method or error conditions during pump operation.
You can control operations directly with the touch screen or remotely from an independent computer or device via the external footswitch interface.
The infusion Only (single and dual syringe models) support infusion operations at user-defined flow rates and with selectable target volume or time values to control the total infusion volume. The Infusion Only models do not include programmable, user-defined methods. (Infusion/Withdrawal Programmable models are also available)
Accessories A full range of accessories are compatible with the Pump 11 Elite including syringe heaters, connectors, tubing, syringes and more.
Specifications
| Specifications | 70-4500 | 70-4501 |
|---|---|---|
| Accuracy | ±0.5% | ±0.5% |
| Classification | Class I | Class I |
| Dimensions Control Box (L x D x H) cm | 9.0 x 7.0 x 6.0 (22.6 x 17.78 x 15.0) | 9.0 x 7.0 x 6.0 (22.6 x 17.78 x 15.0) |
| Display | 4.3″ WQVGA TFT Color Display with Touchpad | 4.3″ WQVGA TFT Color Display with Touchpad |
| Drive Motor | 0.9° Stepper Motor | 0.9° Stepper Motor |
| Environmental Humidity | 20% to 80% RH, non condensing | 20% to 80% RH, non condensing |
| Environmental Operating Temperature English | 40°F to 104°F | 40°F to 104°F |
| Environmental Operating Temperature Metric | 4°C to 40°C | 4°C to 40°C |
| Environmental Storage Temperatue English | 14°F to 158°F | 14°F to 158°F |
| Environmental Storage Temperatue Metric | -10°C to 70°C | -10°C to 70°C |
| Flow Rate Maximum | 88.28 ml/min using 60 ml syringe | 31.97 ml/min using 10 ml syringe |
| Flow Rate Minimum | 1.28 pl/min using 0.5 µl syringe | 1.28 pl/min using 0.5 µl syringe |
| I O TTL Connectors | 15 pin D-Sub Connector | 15 pin D-Sub Connector |
| Input Power | 12-30 VDC | 12-30 VDC |
| Installation Category | II | II |
| Max Linear Force | 35 lb @ 100% Force Selection | 35 lb @ 100% Force Selection |
| Mode of Operation | Continuous | Continuous |
| Motor Drive Control | Microprocessor with 1/16 microstepping | Microprocessor with 1/16 microstepping |
| Net Weight English | 4.6 lb | 4.6 lb |
| Net Weight Metric | 2.1 kg | 2.1 kg |
| No of Syringes | 1 | 2 |
| Non Volatile Memory | Storage of all settings | Storage of all settings |
| Number of Microsteps per one rev of Lead Screw | 15,360 | 15,360 |
| Pollution Degree | 1 | 1 |
| Pump Configuration | Standard | Standard |
| Pump Function | Infusion Only | Infusion Only |
| Pusher Travel Rate Maximum | 159.8 mm/min | 159.8 mm/min |
| Pusher Travel Rate Minimum | 0.18 µm/min | 0.18 µm/min |
| RS 232 Connectors | optional RJ-11 | optional RJ-11 |
| Regulatory Certifications | CE, UL, CSA, CB Scheme, EU RoHS | CE, UL, CSA, CB Scheme, EU RoHS |
| Step Rate Maximum | 26 µsec/µstep | 26 µsec/µstep |
| Step Rate Minimum | 27.5 sec/µstep | 27.5 sec/µstep |
| Syringe Size Maximum | 60 ml | 10 ml |
| Syringe Size Minimum | 0.5 µl | 0.5 µl |
| USB Connectors | Type B | Type B |
| Voltage Range | 100-240 VAC, 50/60 Hz | 100-240 VAC, 50/60 Hz |
Journal Articles
Janine Mok, Michael N. Mindrinos, Ronald W. Davis & Mehdi Javanmard (2014 ) Digital microfluidic assay for protein detection PNAS (Proceedings of the National Academy of Sciences)
Ming Li, Xiang Wu, Liying Liu, Xudong Fan Lei & Xu (2013 ) Self-Referencing Optofluidic Ring Resonator Sensor for Highly Sensitive Biomolecular Detection Analytical Chemistry
Tsung-Feng Wu, Zhe Mei, Yu-Hwa Lo (2013 ) Label-free optofluidic cell classifier utilizing support vector machines Sensors & Actuators B: Chemical
Pengfei Song, Weize Zhang, Alexandre Sobolevski, Kristine Bernard, Siegfried Hekimi & Xinyu Liu (2014 ) A Microfluidic Device for Caenorhabditis Elegans Based Chemical Testing Micro and Nano Systems Engineerign and Packaging
Kunqiang Jiang, Annie Xi Lu, Panagiotis Dimitrakopoulos, Don L. DeVoec & Srinivasa R. Raghavan (2015 ) Microfluidic generation of uniform water droplets using gas as the continuous phase Journal of Colloid and Interface Science
Shuqing Gua, Youlan Lu, Yaping Ding, Li Li, Hongsheng Song, Jinhua Wang & Qingsheng Wu (2014 ) A droplet-based microfluidic electrochemical sensor using platinum-black microelectrode and its application in high sensitive glucose sensing Biosensors & Bioelectronics
Malte F. Alf, Matthias T. Wyss, Alfred Buck, Bruno Weber, Roger Schibli & Stefanie D. Krämer (2012 ) Quantification of Brain Glucose Metabolism by 18F-FDG PET with Real-Time Arterial and Image-Derived Input Function in Mice Journal of Nuclear Medicine
Bernhard Unsöld, Nils Teucher, Michael Didié, Samuel Sossalla, Claudius Jacobshagen, Tim Seidler, Wolfgang Schillinger & Gerd Hasenfuß (2015 ) Negative Hemodynamic Effects of Pantoprazole at High Infusion Rates in Mice Cardiovascular Therapeutics
Dong, Shirley (2015 ) The anxiolytic effect of oxytocin is specific to oxytocin receptors in the prelimbic medial prefrontal cortex The Ohio State University: Department of Neuroscience Honors Theses
Timothy M. Alligrant, Elizabeth G. Nettletona & Richard M. Crooks (2012 ) Electrochemical detection of individual DNA hybridization events Lab On A Chip
Klaus Mathwig, Dileep Mampallil, Shuo Kang & Serge G. Lemay (2012 ) Electrical Cross-Correlation Spectroscopy: Measuring Picoliter-per-Minute Flows in Nanochannels Physical Review Letters
Zhe Mei, Sung Hwan Cho, A. Zhang, Jie Dai, Tsung-Feng Wu & Yu-Hwa Lo (2012 ) Counting leukocytes from whole blood using a lab-on-a-chip Coulter counter 2012 Annual International Conference of the IEEE Engineering in Medicine and Biology Society
Eiji Shigetomi, Olan Jackson-Weaver, Robert T. Huckstepp, Thomas J. O’Dell & Baljit S. Khakh (2013 ) TRPA1 Channels Are Regulators of Astrocyte Basal Calcium Levels and Long-Term Potentiation via Constitutive d-Serine Release Journal of Neuroscience
