Description
The PHD ULTRA™ Satellite Pumps are infusion/withdrawal pumps. They are available in three configurations: standard, push/pull and high force (PHD ULTRA™ 4400 Satellite). The Satellite Pumps are combined with stand alone PHD ULTRA™ Pumps to create a Gradient System. Satellite Pumps can only be powered from a stand alone PHD ULTRA™ via RS‐485. They cannot be controlled with a PC (Please see our PHD ULTRA OEM pumps for PC controlled modules). Satellite Pumps include a footswitch input, USB and RS‐485 connectors.
| Specifications | 70-3406 | 70-3408 | 70-3410 |
|---|---|---|---|
| Accuracy | ±0.25% | ±0.25% | ±0.35% |
| Classification | Class I | Class I | Class I |
| Dimensions L x D x H in (cm) | 11.75 x 5.5 x 6.5 in (29.8 x 14.0 x 16.5 cm) | 11.75 x 5.5 x 6.5 in (29.8 x 14.0 x 16.5 cm) | 11.75 x 5.5 x 6.5 in (29.8 x 14.0 x 16.5 cm) |
| Display | N/A | N/A | N/A |
| Drive Motor | 1.8° Stepper Motor | 1.8° Stepper Motor | 1.8° Stepper Motor |
| Environmental Humidity | 20% to 80% RH, non condensing | 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 | 40°F to 104°F |
| Environmental Operating Temperature Metric | 4°C to 40°C | 4°C to 40°C | 4°C to 40°C |
| Environmental Storage Temperatue English | 14°F to 158°F | 14°F to 158°F | 14°F to 158°F |
| Environmental Storage Temperatue Metric | -10°C to 70°C | -10°C to 70°C | -10°C to 70°C |
| Flow Rate Maximum | 215.8 ml/min using a 140 ml syringe | 215.8 ml/min using a 140 ml syringe | 215.8 ml/min using a 140 ml syringe |
| Flow Rate Minimum | 3.06 pl/min using a 0.5 µl syringe | 3.06 pl/min using a 0.5 µl syringe | 3.06 pl/min using a 0.5 µl syringe |
| I/O TTL Connectors | 15 pin D‐sub Connector | 15 pin D‐sub Connector | 15 pin D‐sub Connector |
| Input Power | 50 W, 0.5 A fuse | 50 W, 0.5 A fuse | 50 W, 0.5 A fuse |
| Installation Category | Continuous | Continuous | Continuous |
| Max Linear Force | 75 lbs @ 100% Force Selection | 75 lbs @ 100% Force Selection | 200 lbs @ 100% Force Selection |
| Mode of Operation | ‐10°C to 70°C | ‐10°C to 70°C | ‐10°C to 70°C |
| Motor Drive Control | Microprocessor with 1/16 microstepping | Microprocessor with 1/16 microstepping | Microprocessor with 1/16 microstepping |
| Net Weight English | 11.7 lb | 11.7 lb | 11.7 lb |
| Net Weight Metric | 5.3 kg | 5.3 kg | 5.3 kg |
| No of Syringes | 2 | 4 | 1 |
| Non Volatile Memory | Storage of all settings | Storage of all settings | Storage of all settings |
| Number of Microsteps per one rev of Lead Screw | 12,800 | 12,800 | 6,400 |
| Pollution Degree | 20% to 80% RH, non condensing | 20% to 80% RH, non condensing | 20% to 80% RH, non condensing |
| Pump Configuration | Satellite | Satellite | Satellite |
| Pump Function | Infuse/Withdraw | Push/Pull | Infuse/Withdraw |
| Pusher Travel Rate Maximum | 190.8 mm/min | 190.8 mm/min | 190.8 mm/min |
| Pusher Travel Rate Minimum | 0.18 µm/min | 0.18 µm/min | 0.36 µm/min |
| RS-232 Connectors | N/A | N/A | N/A |
| Rack Type | Standard | Push/Pull | Standard |
| Regulatory Certifications | CE, ETL (UL, CSA), WEEE, EU RoHS and CB Scheme | CE, ETL (UL, CSA), WEEE, EU RoHS and CB Scheme | CE, ETL (UL, CSA), WEEE, EU RoHS and CB Scheme |
| Step Rate Maximum | 26 µsec/µstep | 26 µsec/µstep | 52 µsec/µstep |
| Step Rate Minimum | 27.5 sec/µstep | 27.5 sec/µstep | 27.5 sec/µstep |
| Syringe Size Maximum | 140 ml | 140 ml | 140 ml |
| Syringe Size Minimum | 0.5 µl | 0.5 µl | 0.5 µl |
| USB Connectors | Type B | Type B | Type B |
| Voltage Range | 100-240 VAC, 50/60 Hz | 100-240 VAC, 50/60 Hz | 100-240 VAC, 50/60 Hz |
Journal Articles
Xizhong Cui, PhD; Yvonne Fitz, BS; Yan Li, MD; Ping Qiu, Ph.D; Steve Solomon, Ph D; Mariam Al-Hamad, BS & Peter Q. Eichacker, MD (2013 ) Pilot Investigation Of A Multi-Channel Automated Drug Delivery System For Blood Pressure Regulated Vasopressor Administration In A Rat Model ATS Journals
Amber L. Alhadeff , Matthew R. Hayes , Harvey J. Grill (2014 ) Leptin receptor signaling in the lateral parabrachial nucleus contributes to the control of food intake American Journal of Physiology
Vivek Sharma, Simon J. Haward, James Serdy, Bavand Keshavarz, Asa Soderlund, Phil Threlfall-Holmes & Gareth H. McKinley (2015 ) The rheology of aqueous solutions of ethyl hydroxy-ethyl cellulose (EHEC) and its hydrophobically modified analogue (hmEHEC): extensional flow response in capillary break-up, jetti Royal Society of Chemistry
Amber L. Alhadeff, Laura E. Rupprecht, and Matthew R. Hayes (2011 ) GLP-1 Neurons in the Nucleus of the Solitary Tract Project Directly to the Ventral Tegmental Area and Nucleus Accumbens to Control for Food Intake Endocrine Society
Ryan W. Mutharda & Scott L. Diamond (2013 ) Side view thrombosis microfluidic device with controllable wall shear rate and transthrombus pressure gradient Lab On A Chip
G. L. Scaglione, S. Lancellotti1, M. Papi1, M. De Spirito, A. Maiorana, L. Baronciani, M. T. Pagliari, A. Arcovito, E. Di Stasio, F. Peyvandi, R. De Cristofaro (2013 ) The type 2B p.R1306W natural mutation of von Willebrand factor dramatically enhances the multimer sensitivity to shear stress The Journal of Thrombosis and Haemostasis
Youri Gendelb, Oana Davidb & Matthias Wesslinga (2013 ) Microtubes made of carbon nanotubes Science Direct
Jidong Wang, Wenwen Chen, Jiashu Sun, Chao Liu, Qifang Yin, Lu Zhang, Yunlei Xianyu, Xinghua Shi, Guoqing Hu & Xingyu Jiang (2014 ) A microfluidic tubing method and its application for controlled synthesis of polymeric nanoparticles Lab On A Chip
J. D. Welsh, T. V. Colace, R. W. Muthard, T. J. Stalker, L. F. Brass & S. L. Diamond (2012 ) Platelet-targeting sensor reveals thrombin gradients within blood clots forming in microfluidic assays and in mouse The Journal of Thrombosis and Haemostasis
Dominika Ogończyk, Mateusz Gocyla, Marcin Opallo (2014 ) Electrochemical response of catalytic nanoparticles in Flow Injection Analysis system Science Direct
James O. Hardin, Thomas J. Ober, Alexander D. Valentine & Jennifer A. Lewis (2015 ) Microfluidic Printheads for Multimaterial 3D Printing of Viscoelastic Inks Advanced Materials
Nan Li, Miguel F. Diaz, Pamela L. Wenzel Ph.D. (2014 ) Application of Fluid Mechanical Force to Embryonic Sources of Hemogenic Endothelium and Hematopoietic Stem Cells Methods in Molecular Biology
Wahyudionoa, Kanako Murakamia, Siti Machmudahb, Mitsuru Sasakia & Motonobu Gotob (2011 ) Production of nanofibers by electrospinning under pressurized CO2 High Pressure Research: An International Journal
Iulia – Rodica Damian, Nicoleta Octavia Tănase, Ștefan – Mugur Simionescu, Mona Mihăilescu (2015 ) Vortex Rings – Experiments and Numerical Simulations Mathematical Modelling in Civil Engineering
C. Liua, J.D. Yeagera & K.J. Ramosa (2015 ) Bonding energy of Sylgard on fused quartz: an experimental investigation Philosophical Magazine
Stephen G. Newman , Kyoungmi Lee , Jianghuai Cai , Lu Yang , William H. Green , and Klavs F. Jensen (2014 ) Continuous Thermal Oxidation of Alkenes with Nitrous Oxide in a Packed Bed Reactor Industrial & Engineering Chemisrty Research
Jinyoung Baekm Dr. Peter M. Allen, Prof. Moungi G. Bawendi & Prof. Klavs F. Jensen (2010 ) Investigation of Indium Phosphide Nanocrystal Synthesis Using a High-Temperature and High-Pressure Continuous Flow Microreactor Angwandte Chemie
I. R. G. Ogilvie, V. J. Siebe, M. C. Mowlem, and H. Morgan (2011 ) Temporal Optimization of Microfluidic Colorimetric Sensors by Use of Multiplexed Stop-Flow Architecture Analytical Chemistry
Isabella Pallotta, Ph.D., Michael Lovett, Ph.D., David L. Kaplan, Ph.D. & Alessandra Balduini, M.D. (2011 ) Three-Dimensional System for the In Vitro Study of Megakaryocytes and Functional Platelet Production Using Silk-Based Vascular Tubes Tissue Engineering
Laurent Pellegatti and Stephen L. Buchwald (2012 ) Continuous-Flow Preparation and Use of β-Chloro Enals Using the Vilsmeier Reagent Organic Process Research & Development
