德国艾本德Eppendorf移液器和移液器价格

移液器使⽤——基本操作移液枪的发展史移液枪的历史很短暂，从移液枪的雏形出现到现在也仅仅刚过50年⽽已，很年轻。

011958年德国Eppendorf（艾本德）公司发明了第⼀⽀移液枪，是为单道固定量程移液枪021968年芬兰Labsystem（雷勃）发明了多道固定量程移液枪，俗称“芬兰枪”031972年法国Gilson推出了第⼀⽀单道可调量程移液枪，并把它命名为Pipetman041984年美国RAININ（瑞宁）开始让世⼈体会电动移液枪的快感分类和原理排⽓式移液枪（内置活塞）<< 滑动查看下⼀张图⽚ >>这种移液枪需要⼀次性枪头，枪头与液体接触。

排⽓式微量移液枪通过活塞驱动，排出空⽓，由此，垂直运动的⾦属或陶瓷活塞在密闭的筒管中制造出真空。

当活塞向上抽动，压缩后半部⽓体，⽽前⼀半空间则变成了真空。

此时，枪头附近的液体便进⼊了真空部分，随后便可转移或再次排出。

这种移液枪准确度和精密度很⾼，适⽤于常规移液操作。

然⽽，由于其依赖于⽓体的移动、压缩，准确度受环境条件的影响较⼤，特别是温度、⽓压和使⽤者的技术。

因⽽，这种移液枪必须妥善保存和校准，使⽤者也必须经过训练，练习正确和稳定的操作技术。

正置换移液枪（外置活塞）<< 滑动查看下⼀张图⽚ >>这种移液枪与排⽓式移液枪相类似，但是更少⽤，通常⽤于避免污染，或⽤于体积⼩、挥发性或有粘性的物质，⽐如易挥发性有机物、DNA等。

主要的差别在于其⼀次性尖端是⼀个带活塞的微量调节注射枪活塞，由塑料制成，活塞与液体直接接触吸取和排出液体。

移液枪的结构Structure of pipette1.控制按钮2.体积调节旋钮3.吸头脱卸按钮4.体积显⽰窗⼝5.密度调节孔：⽤于移液枪的密度调节，出⼚时贴有ADJ银⾊标签，表明符合出⼚设定6.密度调节窗⼝：移液枪出⼚时，默认设置为“0”7.标记区：可⽤于移液枪的标记8.套筒：⽤于脱卸枪头9.弹性吸嘴：具有伸缩性，优化安装和脱卸枪头的⽤⼒10.枪头：推荐使⽤原装枪头常规操作指南艾本德⼯程师⽰范下⾯是操作的中⽂译解>1. 装枪头移液枪套柄⽤⼒下压，需要时⼩幅度旋转即可。

Eppendorf Reference®可调量程移液器和可调量程移液器价格EppendorfReference®可调量程移液器 标题：Eppendorf Reference®可调量程移液器Eppendorf Reference 系列移液器除具有平滑的活塞、紧凑坚固的设计、操作舒适外，更是移液器精度的象征，其单一的多功能按钮既可进行移液、打出液体、也可进行脱卸吸头操作。

Reference 系列提供从0.1 &micro;l 至2,500&micro;l 范围的9种可调量程的移液器；同时也提供16种固定量程的移液器，其移液量程范围从1 &micro;l 到2,500 &micro;l 。

产品特性 单独的标记 使用附件工具，方便快捷进行维修保养和刻度校准 配有量程调节锁定钮，保证所选择的液体体积固定不变 量程 准确度精确度 0.1-2.5 &micro;l,烟灰色 0.25&micro;l &plusmn;12.0% &le;6.0% 1.25&micro;l &plusmn;2.5% &le;1.5% 2.5&micro;l &plusmn;1.4% &le;0.7% 0.5-10&micro;l, 灰色 ...厂家：上海政泓 市场价格： 优惠价格：百度搜索联系EppendorfBioSpcetrometer®紫外/可见光分光光度计 标题：Eppendorf BioSpcetrometer®紫外/可见光分光光度计全新Eppendorf BioSpectrometer 紫外/可见光分光光度计系列产品，体积小巧，适用于紫外和可见光范围的分光检测。

该系列产品可以记录数据结果，并在200nm 至830nm 进行波长扫描。

此外，BioSpectrometer kinetic 动力学款具备温控比色杯滑盖，可在 +20&deg;C 至 +42&deg;C 范围内进行温度控制。

Eppendorf Research® plus 多道移液器和多道移液器价格Eppendorf Research®plus 多道移液器 标题：Eppendorf Research® plus 多道移液器Eppendorf Research&reg; plus 多道移液器从1961年推出第一支工业化的气体活塞式移液器至今，Eppendorf 公司秉承近50年的生产经验和坚持高品质的执着，不断创新研发，旨在为全球科研临床用户提供最完美的移液器。

Eppendorf Research&reg; plus 终于，Research plus 移液器诞生，为现今移液行业建立了至高标准。

全新Research plus 移液器采用高科技材质结合先进的生产工艺流程，其设计理念符合人体工程学，加上人性化的操作应用，不但精准性高、经久耐用，同时适用于各类实验操作。

Research plus&gt;移液器符合人体工程学设计，重量轻，且操作用力小，可以有效防止手部重复性劳损（RSI ）。

其前端的吸嘴具有伸缩性，不但可使安装和脱卸吸头更加省力，还能保证吸头和移液器之间的气密性。

尤其对于...厂家：上海政泓 市场价格： 优惠价格：百度搜索联系 Eppendorf Resea rch® plus 可调量程移液器 标题：Eppendorf Research® plus 可调量程移液器Eppendorf Research&reg; plus 可调量程移液器 从1961年推出第一支工业化的气体活塞式移液器至今，Eppendorf 公司秉承近50年的生产经验和坚持高品质的执着，不断创新研发，旨在为全球科研临床用户提供最完美的移液器。

终于，Research plus 移液器诞生，为现今移液行业建立了至高标准。

全新Researchplus 移液器采用高科技材质结合先进的生产工艺流程，其设计理念符合人体工程学，加上人性化的操作应用，不但精准性高、经久耐用，同时适用于各类实验操作。

Eppendorf移液枪使用说明操作步骤：1．移液枪的选择：根据实验的需要，选择合试量程的枪。

以满足一次既能吸取所需的体积为准，减少多次操作所造成的误差。

在能满足要求的情况下，尽量选择量程较小的枪。

2．量程的调节：将移液器横置，水平放至自己的眼前，通过调节轮慢慢地将容量值调至预想值，从而避免视觉误差所造成的影响。

在容量设定时，还有一个需要特别注意的地方。

当我们从大值调整到小值时，刚好就行；但从小值调整到大值时，就需要调超三分之一圈后再返回。

3．枪头（吸液嘴）的装配：将移液枪（器）垂直插入枪头中，稍微用力左右微微转动即可使其紧密结合。

如果是多道（如8道或12道）移液枪，则可以将移液枪的第一道对准第一个枪头，然后倾斜地插入，往前后方向摇动即可卡紧。

枪头卡紧的标志是略为超过O型环，并可以看到连接部分形成清晰的密封圈。

4．预洗吸头：在我们安装了新的吸头或增大了容量值以后，应该把需要转移的液体吸取、排放两到三次，这样做是为了让吸头内壁形成一道同质液膜，确保移液工作的精度和准度，使整个移液过程具有极高的重现性。

其次，机溶剂和高挥发液体，会在白套筒室内形成负压，从而产生漏液的情况，这时就需要我们预洗四到六次，让白套筒室内的气体达到饱和，负压就会自动消失。

5．吸液：先将移液器排放按钮按至第一停点，再将吸头垂直浸入液面，浸入的深度为：P2、P10小于或等于1毫米，P20、P100、P200小于或等于2毫米，P1000小于或等于3毫米，P5ML、P10ML小于或等于4毫米（浸入过深的话，液压会对吸液的精确度产生一定的影响，当然，具体的浸入深度还应根据盛放液体的容器大小灵活掌握），平稳松开按钮，切记不能过快。

移液之前，要保证移液器、枪头和液体处于相同温度。

吸取液体时，移液器保持竖直状态。

用大拇指将按钮按下至第一停点，然后慢慢松开按钮回原点。

6．放液：放液时，吸头紧贴容器壁，先将排放按钮按至第一停点，略作停顿以后，再按至第二停点，最后松开按钮。

Piston-stroke pipettes with an air cushion are subject to the effects of temperature, air pressure and air humidity. Such effects are kept to a minimum by constructive measures which are designed to ensure that dispensingaccuracy is not significantly affected. Liquids whose physical properties differ significantly from those of water, or temperature differences between the pipette, the pipette tip and the dispensed liquid may also lead to incorrect dispensing volumes. These factors make it necessary to be able to readjust the devices for different physical conditions. Thanks to its numerous adjustment possibilities the new electronic pipette Xplorer from Eppendorf allows for easy compensation of such physical effects.The electronic Eppendorf Xplorer® pipette – Versatile adjustmentUserguideKornelia Ewald, Eppendorf AG, Hamburg, GermanySince piston-stroke pipettes are mainly used for pipetting of aqueous solutions, they are adjusted with distilled water as a test medium. Depending on the density of theparticular liquid the air volume over the liquid expands in different ways. Consequently, other liquid volumes may, under certain circumstances, be aspirated into the tip when dispensing non-aqueous solutions. Liquids with ahigh vapor pressure, such as organic solvents, can also not be dispensed with the level of accuracy specified for distilled water. The air pressure, which is dependent on the height of the location above sea level, is a further factor to be considered during dispensing operations with air cushion pipettes.Solutions whose physical data is very different from water with regard to their density, viscosity, surface tension and/ or vapor pressure may lead to incorrect dispensing volumes. This makes it necessary to readjust piston-stroke pipettes with an air cushion to account for this. If the density of an aqueous solution changes by approximately 10 %, for example, because of the salt concentration, the volume will change by approximately 0.2 %. This statement does only apply if other relevant properties of the liquid do not change at the same time.Another reason for changing the factory settings canbe, for example, the altitude of the location at which the pipette is used. If the pipette is used at an extremely high altitude, it must be adjusted to the ambient air pressure. At 1000 meters above sea level, the volume error of a 100 µL pipette is about -0.3 %. In addition, when using pipette tips that significantly differ from standard tips in their geometry, changing the adjustment can also improve dispensing accuracy.In contrast to performing calibration which involves determining the measured random (precision) and systematic (accuracy) errors from the nominal value and which does not require any alterations that will permanently change the dispensing system, performing an adjustment will change the device for all subsequent dispensing operations. Changes made to the adjustment do not affect dispensing precision. Precision can only be improved by exchanging parts. Precision is also considerably affected by handling errors.The actual volume of a pipette can be checked by weighing as follows:If the set volume corresponds to the actual volume, no correction is necessary.If there is a difference between the actual volume andthe set volume, make sure to check the following factors before readjusting a pipette:Is there any liquid dripping from the tip?Is the pipette tip fitted leak-proof?Is the tip cone undamaged?Are the piston and the cylinder leak-proof?Does the temperature of the pipetted liquid correspond to the temperature of the device and the ambient air?Is the weighing location free from drafts?Does the work method and pipetting speed permit complete aspiration and dispensing of the liquid?Has the correct value for “Density liquids at weighing temperature” been used for the calculation of the actual volume?Is the pipette volume setting correct?Is the balance sufficiently sensitive (balance resolution 0.001 mg) for very small volumes (< 10 µL)?Were original epT.I.P.S. pipette tips used with the correct volume (see technical data) as test tips?The factory setting of the Eppendorf Xplorer may onlybe changed after all of the above listed points have been thoroughly checked and the pipette volume setting is still different from the measured volume.The Eppendorf Xplorer offers several individual adjustment options which can be used as an alternative to adjusting the pipette, depending on the application.The following adjustment options are available for selection:Liquid type ethanol 75 % or glycerol 50 %When this adjustment option is selected, the factory setting is changed by an internal factor which considers the density of the ethanol or the glycerol. This means that the substance can be dispensed with greater accuracy (smaller systematic error) with the Xplorer pipette.epT.I.P.S. longThis enables the pipette to be adjusted to the different lengths of a pipette tip, such as, epT.I.P.S. 1200 µL elongated or epT.I.P.S. 10 mL L. When this adjustment option is selected, the tip geometry of the longer tip is considered in the internal volume calculation. This means that the technical data of the original tip (test tip) is reached. This function can also be used when the Xplorer pipette is not used with its test tip, e.g., when using the 300 µL epT.I.P.S. for the pipette size 5–100 µL. When using the following tips dispensing accuracy can be increased with this function:Eppendorf Xplorer 10 µL (medium gray):epT.I.P.S. long 20 µL L (light gray tray)Eppendorf Xplorer 100 µL (yellow):epT.I.P.S. 300 µL (orange tray)Eppendorf Xplorer 1000 µl (blue):epT.I.P.S. long 1250 µl L (dark green tray)Eppendorf Xplorer 1200 µL (green, 8-channels):epT.I.P.S. long 1250 µL L (dark green tray)Eppendorf Xplorer 10 mL (turquoise):epT.I.P.S. long 10 mL L Geographic altitudeThe mean air pressure of a location depends on its height above sea level. When testing a piston-stroke pipetteit is thus important to take fluctuations in pressure into account. At higher altitudes with a drop in air pressure the aspiration volume of a piston-stroke pipette is reduced. The Xplorer pipette’s stroke is corrected taking into account the air pressure at the respective altitude. This can be easily accomplished using the “Geographic altitude” adjustment function that allows the altitude to be adjusted in increments of 250 m (820 ft). The maximum altitude that can be selected is 5000 m.The adjustment options Liquid Type, epT.I.P.S. long and Geographic Altitude can be combined with each other.Another possibility of readjusting the Xplorer is to use the “Individual adjustment” function. With this option, the gradient or axis intercept is changed taking into account the exact density of the solution to be dispensed. 1-point, 2-point or 3-point adjustment are available for selection. To create the weighing results, the use of a fine balance with a high resolution is required. Dispensing volumes below 10 µL require a balance with a resolution of 0.001 mg. The arithmetic operations required for performing the correction are automatically performed by the Xplorer pipette during the 1-3-point adjustment, so that the user does not have to carry out any complicated calculations.In this example the factory piston-stroke setting is increased by a factor (Fig.1). Strictly speaking, thecorrection only applies to the testing volume, but it is used for the entire volume range. The correction is different to that for a mechanical pipette.A correction with a factor results in a smaller stroke correction for a small volume than for a large volume.In the case of a mechanical pipette the stroke can only be changed by a fixed volume (Fig. 2). This volume change applies to the entire measurement range of the mechanical pipette. The existing adjustment is changed in parallel by a fixed amount.Fig. 1: Example for the piston-stroke correction of a 1-point adjustmentmax.Piston stroke of XplorerVolume display of Xplorermin.25 %50 %75 %max.– Factory setting– –1-point adjustmentFig. 2: Example for the change of the piston stroke of a mechanical pipettePiston stroke of manual pipetteDigital volume display of manual pipettemax.min. max.– Factory setting– – Manual pipette; change by a fixed amount for all volumesFig. 3:Example for a 2-point adjustmentmax.Piston stroke of XplorerVolume display of Xplorermin. 25 % 50 % 75 % max.– Factory setting– – 2-point adjustment at 25 % and 50 %1-point adjustmentAfter you input the density, the selected volume and the corresponding weighing result, the Xplorer determines a correction factor. The factor is only valid for the selected volume and the selected work technique (speed, prewetting, wall dispensing method, etc.).2-point adjustmentAfter you input the density, two different volumes and the corresponding weighing results, the Xplorer determines a correction factor. The factor applies to the volume range between the tested volumes and only for the selected work technique. However, the factor is also used here for the entire volume range, that is, also below and above the two measuring points (Fig. 3).3-point adjustmentAfter you input the density, three different volumes and the corresponding weighing results, the Xplorer determines two correction factors. The factors are correct frommeasuring point to measuring point in the selected volume regions and only for the selected work technique. However, the respective factor is also used below and above the first or third measuring point (Fig.4).Fig. 4:Example for a 3-point adjustmentmax.Piston stroke of XplorerVolume display of Xplorermin. 25 % 50 % 75 % max.– Factory setting– – 3-point adjustment at 25 %, 50 % and 75 %Today, it is expected that pipettes should not only offer ease of use and precision. Other features, such as simple volume adjustment, have become standard requirementsfor such devices. The electronic pipette Eppendorf Xplorer meets such requirements in every respect, making it ideally suited as an instrument for daily use in the lab.In contrast to 1-point and 2-point adjustment, 3-point adjustment is more accurate. If three significantly different volumes are used for calculating the two correction factors, the corrected volume range is considerably larger and thus also more precise. However, 3-point adjustment is more time-consuming.It is necessary to carry out a gravimetric test for eachXplorer pipette whose factory setting has been changed by one of the above-mentioned adjustment options.This is the only way of ensuring that the selected adjustment meets the required measurement errors.To ensure that other users are informed of the changed adjustment, each Xplorer pipette that has been changed by the adjustment must be additionally marked by a clearly visible label indicating the type of change made.The precise work technique relating to the individual adjustment options is described in the adjustment instructions of the Eppendorf Xplorer (see Xplorer Adjustment Instructions).Factory settingsA pipette that has been readjusted can be reset to the original settings using the “Reset to Factory Settings” adjustment option at any time.e p p e n d o rf ®, E p p e n d o r f X p l o r e r ® a n d e p T .I .P .S .® a r e r eg i s t e r e d t r a d e m a r k s o f E p p e n d o r f A G . A l l r i gh t s r e s e r v e d ,i n c l u d i n g g r a p h i c s a n d i m a g e s . C o p y r i g h t © 2010 b y E p p e n d o r f A G .O r d e r N o . A U 036 W W 020/G B 2/W E B /1210/N E U HYour local distributor: /worldwideEppendorfAG·22331Hamburg·Germany·Tel:+494053801-0·Fax:+494053801-556·E-mail:***********************Eppendorf North America, Inc. · 102 Motor Parkway · Hauppauge, N.Y. 11788-5178 · USATel:+15163347500·Tollfreephone:+1800-645-3050·Fax:+15163347506·E-mail:******************Application Support Europe: Tel: +49 1803 666 789 (Preis je nach Tarif im Ausland; 9 ct/min aus dem dt. Festnetz; Mobilfunkhöchstpreis 42 ct/min)E-mail:*********************NorthAmerica:Tel:+18006453050·E-mail:**********************AsiaPacific:Tel:+60380236869·E-mail:*********************************®®。

移液枪国标移液枪，又称打液枪、吸液器，是一种常用于实验室中的仪器设备。

它由一个管柄、软管、吸头和活塞组成，通常用于移取或吸取一定体积的液体样品。

移液枪的国际标准主要有Eppendorf和Gilson两种。

Eppendorf移液枪是由德国的Eppendorf公司生产的，该公司是全球领先的生命科学和生物技术仪器设备制造商之一、Eppendorf移液枪是一种手动操作的移液器，可用于吸取和排放微量液体。

它根据移液量的不同分为不同型号的移液枪，常用的型号有0.1-2.5ul、2-20ul、20-200ul和100-1000ul。

Gilson移液枪是由法国的Gilson公司生产的，该公司是全球著名的实验室仪器设备制造商之一、Gilson移液枪采用先进的液压系统，可实现精准和可靠的移液操作。

它根据移液量的不同分为不同型号的移液枪，常用的型号有0.2-2ul、0.5-10ul、2-20ul、10-100ul、20-200ul、100-1000ul和500-5000ul等。

无论是Eppendorf移液枪还是Gilson移液枪，它们都具有以下共同特点：1.精确度高：移液枪采用先进的设计和技术，能够实现精确的液体吸取和排放，保证实验的准确性和可靠性。

2.操作简便：移液枪的操作非常简单，只需要通过按压活塞和转动旋钮等动作即可完成吸取和排放液体样品的操作。

3.可重复使用：移液枪的吸头可以反复更换，且易于清洗和消毒，使其能够重复使用，提高实验效率和经济效益。

4.安全性好：移液枪的设计考虑到了操作人员的安全性，采用了防滴设计，防止液滴的溅射和污染，保护实验人员和实验环境的安全。

总之，移液枪是实验室中常用的一种仪器设备，它的国际标准主要有Eppendorf和Gilson两种。

无论是Eppendorf移液枪还是Gilson移液枪，它们都具有精确度高、操作简便、可重复使用和安全性好等特点。

使用移液枪进行液体样品的吸取和排放操作，能够提高实验的准确性和可靠性，提高实验效率和经济效益。