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SPLG180

SPLG180

Legato 180 Dual Syringe I/W Programmable



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  • Overview
  • Specifications
  • Accessories
  • Citations
  • Related Products

Overview

SPLG180

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Features:

  • Holds one or two syringes from 0.5ul to 10ml
  • High resolution color touch screen
  • Unparalled ease of use
  • Touch pad "lock" feature
  • LED light on front panel
  • Full metal chassis
  • Built in syringe table
  • Up to 30 lbs linear force
  • Advanced microstepping techniques
  • Built in RS485 interface
  • USB port
  • I/O & TTL interface
  • Continuous mode of operation
  • Spill dam
  • Programmable

The SPLG180 Pico pump has infusion and withdrawal capabilities with accurate deliveries of picoliter, nanoliter, microliter and milliliter flow. It is especially designed to hold microliter syringes ranging from 0.5ul to 10ml.
 
The Pico pump will operate continuously in “rate” mode or accurately dispense a specific amount of fluid in “volume” mode. The microstepping pump delivers very smooth and constant flow over the entire flow range. The Pico pump feature non-volatile memory. The pump remembers its last syringe size, flow rate and configuration settings.

Dual syringe infuse/withdraw optimized for low flow with program options for 2 programs. 50 steps each. Accomodates syringes 0.5ul to 10ml. User definable flow rates with selectable target volume or time values to control the total infusion volume.

Examples of flowrates

Syringe Diameter Minimum Maximum
0.5 µl 0.103 mm 0.540 pl/min 596.20 nl/min
1 µl 0.146 mm 1.140 pl/min 1.193 µl/min
2 µl 0.206 mm 2.280 pl/min 2.385 µl/min
5 µl 0.343 mm 6.360 pl/min 6.612 µl/min
10 µl 0.485 mm 12.720 pl/min 13.220 µl/min
25 µl 0.729 mm 28.740 pl/min 29.870 µl/min
50 µl 1.03 mm 57.360 pl/min 59.620 µl/min
100 µl 1.457 mm 114.800 pl/min 119.300 µl/min
250 µl 2.304 mm 287.200 pl/min 298.300 µl/min
500 µl 3.256 mm 573.700 pl/min 595.800 µl/min
1000 µl 4.608 mm 1.149 nl/min 1.193 ml/min
1 ml 4.699 mm 1.195 nl/min 1.241 ml/min
3 ml 8.585 mm 3.988 nl/min 4.142 ml/min
5 ml 11.989 mm 7.778 nl/min 8.078 ml/min
10 ml 14.427 mm 11.260 nl/min 11.700 ml/min

Specifications

Specifications
Accuracy:

± 0.35%

Reproducibility

± 0.05%

Syringes (Min/Max)

0.5 ul to 10ml

Flow Rate:

Minimum (0.5 ul syringe): 0.58 pl/min

Maximum (10ml syringe): 11.70 ml/min

Display

4.3 WQVGA TFT Color Display with Touchpad

Non-Volatile Memory

Stores all Settings

Connectors:

RS485 - IEEE-1394 6 pos

USB - Type B

I/O & TTL - 15 pin D-Sub Connector

Linear Force (Max)

13.6 kg (30 lbs) @ 100% Force Selection

Drive Motor

0.9 Stepper Motor

Motor Drive Control

Microprocessor with 1/16 microstepping

Number of Microsteps
per one rev.of Lead Screw

20,480

Step Revolution

0.031 um/ustep

Step Rate - Minimum

27.5 sec/ustep

Step Rate - Maximum

26 usec/ustep

Pusher Travel Rate - Minimum

0.02 um/min

Pusher Travel Rate - Maximum

71.55 mm/min

Power

100-240 VAC: 50/60 Hz, 50 W, 0.5 A fuse

Dimensions

22.6 x 19.05 x 15 cm (9 x 7.5 x 5 in)

Weight

2.66 kg (5.9 lbs)

Operating Temperature

4 degree C to 40 degree C (40 degree F to 104 degree F)

Storage Temperature

-10 degree C to 70 degree C (14 degree F to 158 degree F)

Humidity

20% to 80% RH non condensing

Mode of Operation

Continuous

Classification

Class 1

Pollution Degree

1

Installation Category

11

Regulatory Certification

CE, UL, CSA, CB Scheme, EU RoHS

Accessories

Citations

Gunaratne, K., & Prabhakaran, V. (2015). Design and performance of a high-flux electrospray ionization source for ion soft landing. Analyst. Retrieved from https://pubs.rsc.org/en/content/articlehtml/2015/an/c5an00220f

Horvath, C., Arratia, C., & Cordero, M. (2015). Measurement of the dispersion relation of a convectively unstable capillary jet under confinement. Physics of Fluids (1994-Present). Retrieved from https://scitation.aip.org/content/aip/journal/pof2/27/11/10.1063/1.4935699

Khalili, A. A., & Ahmad, M. (2016). A Microfluidic Device for Hydrodynamic Trapping and Manipulation Platform of a Single Biological Cell. Applied Sciences. Retrieved from https://www.mdpi.com/2076-3417/6/2/40/htm

Kidd, R., Noell, A., & Kazarians, G. (2015). Ion Chromatography-on-a-Chip for Water Quality Analysis. Retrieved from https://ttu-ir.tdl.org/ttu-ir/handle/2346/64414

Kim, J., & Szinte, J. (2016). 17β-Estradiol and Agonism of G-protein-Coupled Estrogen Receptor Enhance Hippocampal Memory via Different Cell-Signaling Mechanisms. The Journal of  …. Retrieved from https://www.jneurosci.org/content/36/11/3309.short

Lin, Y., & Peng, P. (2015). Semiconductor sensor embedded microfluidic chip for protein biomarker detection using a bead-based immunoassay combined with deoxyribonucleic acid strand. Analytica Chimica Acta. Retrieved from https://www.sciencedirect.com/science/article/pii/S0003267015002937

Shen, Z., Coupier, G., Kaoui, B., & Polack, B. (2016). Inversion of hematocrit partition at microfluidic bifurcations. Microvascular  …. Retrieved from https://www.sciencedirect.com/science/article/pii/S0026286215300479

Xue, P., Wu, Y., Guo, J., & Kang, Y. (2015). Highly efficient capture and harvest of circulating tumor cells on a microfluidic chip integrated with herringbone and micropost arrays. Biomedical Microdevices. Retrieved from https://link.springer.com/article/10.1007/s10544-015-9945-x

Xue, P., Wu, Y., Menon, N., & Kang, Y. (2015). Microfluidic synthesis of monodisperse PEGDA microbeads for sustained release of 5-fluorouracil. Microfluidics and Nanofluidics. Retrieved from https://link.springer.com/article/10.1007/s10404-014-1436-5

Yoshida, K., & Onoe, H. (2015). Self-assembled hydrogel microspring for soft actuator. Micro Electro Mechanical Systems (MEMS …. Retrieved from https://ieeexplore.ieee.org/xpls/abs_all.jsp?arnumber=7050877

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