AL-DUAL-AL-1000
Dual Aladdin Pump System (Two Aladdin AL-1000 SyringeONE Syringe Pumps with sync cable for reciprocating use)
- Overview
- Specifications
- Accessories
- Citations
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Overview
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AL-DUAL-AL-1000 Instruction Manual
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- Includes 2 x AL-1000 pumps and sync cable for reciprocating use
- Each pump accepts syringe sizes: 1-60mL, or 0.5-5 uL
- Programmable, economical, verstaile
- Network, control, and monitor up to 100 pumps with one computer
The Dual System allows the two pumps to communicate with each other through a synchronization cable. The system is flexible and can the pumps casn be configured to operate in:
- Continuous flow (push/pull configuration requires p-dkit optional check valve set)
- Emulsification
- Independently
Each AL-1000 pump offers
- Automatic dispensing of small volumes
- Very precise, reproducible flow rate control
- Displays total volume dispensed in mL or µL units
- Selectable infusion/withdrawal rate units (mL/hr, µL/hr, mL/min, µL/min)
- Infusion rate can be changed while pumping
- Program pump via keypad or from a computer
- Highly controllable – program sequences without a computer (holds up to 41 programming phases)
- Motor stall detection
To meet the demands of a busy lab Aladdin Pumps offer exceptional value providing versatility and reliability for accurately dispensing media down into the nanoliter range.
The Aladdin AL-1000 is a programmable single channel infusion / withdrawal syringe pump. It has a metal casing to provide stability, ensuring less vibration is transferred to the syringes. Setup is easy using the pumps keypad or via a computer with optional PC to pump cable (GN-PC7 or GN-PC25).
The Aladdin AL-1000 can run complex programs with up to 41 pumping phases can be set to change pumping rates; set dispensing volumes; insert pauses; control and respond to external signals; sound the buzzer.
| Channels Per Pump | 1 |
| Type | Infusion / Withdrawal |
| Flow Range | 0.001 µL/hr (0.5 mL syringe) to 3470 mL/hr (140 mL syringe) |
| Dispensing Accuracy | ±1% |
| Syringe Sizes Accepted | 0.5 µL to 60 mL or 140 mL partially filled |
| Linear Force | 35 lb at low speed; 18 lb at maximum speed |
Example Flow Rates
| Syringe Size | Maximum Rate | Minimum Rate |
| 0.5 µL | 25.49 µL/hr | 0.001 µL/hr |
| 1 mL | 52.86 mL/hr | 0.727 µL/hr |
| 3 mL | 223.8 mL/hr | 3.076 µL/hr |
| 5 mL | 372.5 mL/hr | 5.119 µL/hr |
| 10 mL | 607.6 mL/hr | 8.349 µL/hr |
| 20 mL | 966.2 mL/hr | 13.28 µL/hr |
| 30 mL | 1260 mL/hr | 17.32 µL/hr |
| 60 mL | 2120 mL/hr | 29.1 µL/hr |
| 140 mL | 3470 mL/hr | 47.7 µL/hr |
Specifications
| SYRINGE SIZES | 1-60 mL, or 0.5-5µL micro syringes |
| NUMBER OF SYRINGES | 1 |
| MOTOR TYPE | Step Motor, 1/8 to 1/2 step modes |
| STEPS PER REVOLUTIONS | 400 |
| STEPPING (max. min.) | 0.21µm to 0.850µm |
| MOTOR TO DRIVE SCREW RATIO | 15/28 |
| SPEED (max./min.) | 5.1 cm/min / 0.0042 cm/hr |
| PUMPING RATES | 1699 mL/hr with 60 mL syringe, to 0.73µL/hr with 1 mL syringe |
| MAXIMUM FORCE | 35 lb at min. speed, 18 lb at max. speed |
| NUMBER OF PROGRAM PHASES | 41 |
| RS-232 PUMP NETWORK | 100 pumps maximum |
| POWER supply | Wall adapter 12V DC @ 850 mA |
| DIMENSIONS | 22.9 x 14.6 x 11.4 cm (8.75 x 5.75 x 4.5 in.) |
| WEIGHT | 3.2 kg |
Accessories
Citations
Birngruber, T., & Ghosh, A. (2013). Cerebral open flow microperfusion: A new in vivo technique for continuous measurement of substance transport across the intact blood–brain barrier. Clinical and …. Retrieved from https://onlinelibrary.wiley.com/doi/10.1111/1440-1681.12174/full
Ferreira, D., Reis, R., & Azevedo, H. (2013). Peptide-based microcapsules obtained by self-assembly and microfluidics as controlled environments for cell culture. Soft Matter. Retrieved from https://pubs.rsc.org/EN/content/articlehtml/2013/sm/c3sm51189h
Herricks, T., Avril, M., Janes, J., Smith, J., & Rathod, P. (2013). Clonal Variants of Plasmodium falciparum Exhibit a Narrow Range of Rolling Velocities to Host Receptor CD36 under Dynamic Flow Conditions. Eukaryotic cell. Retrieved from https://ec.asm.org/content/12/11/1490.short
Maya, H., Vincent, M., & Nötzli, S. (2013). Increased porosity of electrospun hybrid scaffolds improved bladder tissue regeneration. … Research Part A. Retrieved from https://onlinelibrary.wiley.com/doi/10.1002/jbm.a.34889/full
Tõnurist, K., Thomberg, T., & Jänes, A. (2013). Polymorphic Behavior and Morphology of Electrospun Poly (Vinylidene Fluoride) Separator Materials for Non-Aqueous Electrolyte Based Electric Double Layer. ECS …. Retrieved from https://ecst.ecsdl.org/content/50/45/49.short
Tõnurist, K., Thomberg, T., Jänes, A., & Lust, E. (2013). Specific Performance of Electrical Double–Layer Capacitors Based on Different Separator Materials and Non–Aqueous Electrolytes. ECS Transactions. Retrieved from https://ecst.ecsdl.org/content/50/43/181.short
Zander, N., & Orlicki, J. (2013). Electrospun polycaprolactone scaffolds with tailored porosity using two approaches for enhanced cellular infiltration. Journal of Materials …. Retrieved from https://link.springer.com/article/10.1007/s10856-012-4771-7
Zhang, J., Jiang, D., & Peng, H. (2014). A pressurized filtration technique for fabricating carbon nanotube buckypaper: Structure, mechanical and conductive properties. Microporous and Mesoporous Materials. Retrieved from https://www.sciencedirect.com/science/article/pii/S1387181113005192
Zhang, J., Jiang, D., Peng, H., & Qin, F. (2013). Enhanced mechanical and electrical properties of carbon nanotube buckypaper by in situ cross-linking. Carbon. Retrieved from https://www.sciencedirect.com/science/article/pii/S000862231300568X
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