Eppendorf电动移液器说明书

移液器使用说明书一、产品介绍移液器是一种常见的实验室设备，用于在实验过程中精确地移动和分配液体。

它广泛应用于生物技术、化学实验、医学研究等领域，是科学研究和实验室操作中不可或缺的工具。

二、产品组成移液器主要由以下几个部分组成：1. 手柄：用于握持和操作移液器。

2. 体积调节器：控制移液器吸取和释放液体的量。

3. 移液器头：连接到体积调节器上，用于吸取和释放液体。

4. 塑料吸头：连接到移液器头，与待转移的液体接触。

三、使用步骤1. 准备工作：a. 将移液器头连接到体积调节器上。

b. 将塑料吸头连接到移液器头上。

c. 根据需要，选择合适的塑料吸头尺寸。

2. 吸取液体：a. 将塑料吸头浸入待转移的液体中。

b. 按下体积调节器上的按钮，吸取适量的液体。

可通过调节体积调节器上的刻度，控制吸取的液体量。

3. 移液：a. 将塑料吸头移至目标容器的液面上方。

b. 按下体积调节器上的按钮，缓慢释放液体。

可通过调节体积调节器上的刻度，控制释放的液体量。

4. 清洗：a. 在每次吸取和释放液体之前，用纯水或适宜的溶液进行清洗。

b. 吸取清洗液并释放数次，以确保移液器头和吸头清洁。

四、注意事项1. 操作时需要保持手部稳定，以避免液体的溅出或浪费。

2. 吸取和释放液体时应缓慢，避免产生气泡或液体溢出。

3. 使用适当大小的塑料吸头，以确保精确的移液。

4. 特定实验要求时，应按照实验操作指导书进行操作。

5. 使用完毕后，及时清洗移液器以防止交叉污染和液体残留。

五、保养与维护1. 使用后，将移液器头和塑料吸头进行拆卸，清洗并晾干。

2. 定期检查移液器的密封性能和工作状态，确保正常使用。

3. 如有损坏或发现故障，应及时更换移液器头或维修设备。

六、安全事项1. 避免与移液器头和塑料吸头的尖端接触，以防刺伤。

2. 在操作过程中，避免将移液器头和塑料吸头直接接触皮肤和眼睛，以防止污染和刺激。

3. 使用化学药品时，需注意安全操作规程，避免直接接触有害物质。

Eppendorf plus 移液枪校准方法1、准备超纯水、万分之一天平（如果校正0.5~2.5ul量程的，至少要十万分之一的天平）、温湿度计、恒温室，还需准备一个小口容器，防止水分挥发。

2、按移液器总量程的100%、50%、10%分别进行第三和第四步。

3、吸头要反复吸取超纯水三次后，吸取固定容积的超纯水，推入放置在天平上的小口容器中，待数据稳定读取天平数值，同时记录温度。

重复10次。

4、将测量的数据用iso8655中的计算公式计算获得对应温度下的体积，取平均值。

5、根据三个测量点的偏差，用移液器专用的校正扳手通过移液器的校正窗进行调整。

6、重复3、4步，直至偏差在ISO8655的要求内为止。

ISO 8655-1-2002活塞式容量测量仪器.第1部分:术语、一般要求和用户使用建议ISO 8655-2-2002 活塞式容量测量仪器.第2部分:活塞式吸量管ISO 8655-6-2002 活塞式容量测量仪器.第6部分:确定测量误差的重量分析法三、校准方法及步骤操作环境：温度应控制在15-30℃，恒定在±0.5℃，相对湿度50%-80%，要保持较高的空气湿度以减少水分蒸发对结果造成的影响。

建议使用防蒸发装置。

测试应在独立无通风的房间内进行，并配备温度和湿度显示。

所需设备：1、分析天平一台。

确保室内空气流动平缓，应避免天平正对空调出风口。

根据所测试的移液器的容量来选择适合的天平：2、纯水、三蒸水或去离子水，需达到ISO 3696三级水的标准。

3、独立工作间，配备防震、防尘、远离热源、无阳光直射的操作台。

4、温度计、湿度计。

校准操作：为确保校准的准确性，采用三点移液十次，具体步骤如下：1、同温处理，将移液器、吸头、天平、测试用水、操作台等校准用具放置在同一工作间内，至少四小时。

2、在正式操作前，先预洗吸头，吸排测试用水5次。

3、用最大体积、50%最大体积和最小体积（或10%最大体积），各移液10次，记录每次移液的质量。

Eppendorf 成立于1945年2009年，可整支高温高压灭菌的Research plus 手动移液器上市2010年，高精度人性化操作的Xplorer 电动移液器上市1958年，全球第一个气体活塞式移液器专利Eppendorf致力于发展生物科技，不断改善实验室环境提高产品质量，满足人性化需求我们希望把质量可靠的产品、先进的服务理念19852003年，PhysioCare概念移液器上市，有效防止RSI（手部重复劳损）2004年在中国进行直销2003年成立Eppendorf中国代表处移液产品选择指南性 能工作原理自动识别分液管量程范围液体移取液体分装电动马达应 用常规液体操作自动分液吸取上清滴定倍比稀释高温高压灭菌操作易挥发液体强腐蚀液体密度与水有差别的液体气体活塞0.5 µl - 10 ml（单道）0.5 µl - 1,200 µl（多道）●－●●●●－－－下半支－－－气体活塞0.1 µl - 2,500 µl●－－－●－－－－整支－－－气体活塞0.1 µl - 10 ml（单道）0.5 µl - 300 µl（多道）●－－－●－－－－下半支－－－气体活塞0.1 µl - 10 ml（单道）0.5 µl - 300 µl（多道）●－－－●●－－－－整支－－Research移液器Reference移液器Xplorer电动移液器Research plus移液器N E W N E W45外置活塞1 µl - 50 ml●●●－●－－－－－●●●外置活塞1 µl - 50 ml●●●●●●－－－－●●●外置活塞1 µl - 50 ml●●●●●●●●●－●●●内置活塞0.5 - 100 ml●－●－●－－－－●●●●内置活塞0.01 - 999.9 ml●－●●●－－●－－●●●Multipette plus 手动分液器Multipette stream电动分液器Multipette Xstream电动分液器Varispenser plus 瓶口分液器Top Buret 数字滴定仪●获得2009年全球Reddot红点工业设计大奖* 不包含5 ml和10 ml Research plus移液器● 按钮用力小于一支圆珠笔密度调节窗口－　适用不同密度液体Perfect Piston TM系统的高科技材质重量轻－　耐高温、抗腐蚀、坚固耐用－　可整支高温高压灭菌和紫外消毒位置设计合理，便于移液 体积旋钮－　设定体积时转动圈数少独立活塞式设计，每个通道可单独拆卸－　灵活性高－　节省维修成本弹性吸嘴－　伸缩式吸嘴与吸头更匹配订货信息：Eppendorf Research® plus单道可调量程移液器8* EN ISO 8655 Eppendorf订货信息：Eppendorf Research ® plus 固定量程移液器9订货信息：Eppendorf Research ® plus 多道移液器* EN ISO 8655Eppendorf全新 Research plus pack 移液器套装●　套餐：- 3支Eppendorf Research ® plus 移液器 - 适配吸头样品- 1支礼品笔！订货信息：Eppendorf Research ® plus Pack 移液器套装可在/support 网址下载SOP 标准操作手册诠释移液概念的新标准Research®移液器●双按钮操作●下半支可高温高压灭菌●TÜV 认证：人性化，使用友好●耐化学腐蚀●操作更省力●单手操作● 4 位数字体积显示●密封圈免维护10* EN ISO 8655 EppendorfEppendorf Research®订货信息Eppendorf移液器配件下半支可高温高压灭菌●旋转式移液器支架溶液槽诠释移液概念的新标准11订货信息：Eppendorf Research ®可调量程移液器*EN ISO 8655EppendorfepResearch ®3 超值三支套装●　套餐：- 3 支Eppendorf Research ® 移液器 - 3盒适配吸头，吸头盒可重复使用- 3支移液器托架，1支礼品笔！订货信息：Eppendorf Research ®移液器套装可在/support 网址下载SOP 标准操作手册12epReference®3超值三支套装●　套餐：- 3 支Eppendorf Reference®移液器- 3盒适配吸头，吸头盒可重复使用；- 3支移液器托架，1支礼品笔！可在/support网址下载SOP标准操作手册订货信息：Eppendorf Reference®移液器套装适用于病原微生物等危险性样品操作* EN ISO 8655 的不准确度和不精确度的参数仅在使用 Eppendorf 原装吸头的情况下有效。

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:*********************************®®。

EPPENDORF PCR仪简易操作说明1、打开仪器的电源开关，仪器显示完软件版本号及型号后，进入主菜单（如下图）。

2、新建、编辑程序1）新建程序：在Main-Menu主菜单下通过光标移动键移动光标到FILES菜单上，按ENTERN 键进入，在FILES子菜单下选择STANDAND按ENTERN确认，即可将STANDARD标准程序调用修改，修改完后可另存为其它程序名（也可选择NEW子菜单建立全新的程序）。

如下图：在上图界面上，移动光标到BLOCK选项上，通过SEL键选择BLOCK（对热模块进入温控）或TUBE（对样品管温控），再将光标移到LID，设置热盖温度为103度。

NOWAIT和AUTO 同BLOCK选项一样的设置过程。

再将光标下移到空格行，按一次SEL键，出现1 T=* *，将光标移到*上设置温度，再将光标后移设置时间，再将光标下移设置下一个温度过程；若要在该步温度下设置温度或时间递增或递减条件，则将光标移动该语句行号的正下方，按再OPTION键，即可设置递增或递减条件；若程序中需要循环语句，则可反复按SEL键直至出现GOTO ** REP **，设置返回到第几步共有多少个循环（目标循环数减1），依此类推设置完整个程序即可。

程序保存：设置完程序后按EXIT键退出程序，仪器将提示是否保存程序，通过SEL键选择YES，再给程序取个名称，先用光标移动键移动原程序名称上，用DELE键逐个删除原名称名称，输入新的程序名称（名称中通过反复按SEL键可输入字母），最后按ENTERN保存程序。

2）编辑程序同上过程。

3）在Main-Menu主菜单下选择DELE按ENTERN进入删除程序界面，用光标移动键选择需要删除的程序，再按ENTERN键即可删除程序。

4）在Main-Menu主菜单下选择START子菜单，通过光标移动键选择需要运行的程序，按START键即可运行该程序。

5）程序运行过程中可按OPTION键显示程序运行时间及结束时间（只显示5秒钟）。

Eppendorf Research 移液器使用手册目录1. 安全警告与应用限制 ...................................................................................... 错误!未定义书签。

. 移液 .......................................................................................................... 错误!未定义书签。

. 养护 ............................................................................................................ 错误!未定义书签。

2 技术参数 .......................................................................................................... 错误!未定义书签。

Research系列，固定量程 .................................................................................. 错误!未定义书签。

Research系列，可调量程 .................................................................................. 错误!未定义书签。

Inaccuracy (Imprecision; CV) ........................................................................ 错误!未定义书签。

Eppendorf Research?移液器使用手册目录1. 安全警告与应用限制 ........................................... 错误 !未定义书签。

. 移液..................................................... 错误 !未定义书签。

. 养护..................................................... 错误 !未定义书签。

2 技术参数..................................................... 错误 !未定义书签。

Research 系列，固定量程 ........................................ 错误 !未定义书签。

Research 系列，可调量程 ........................................ 错误 !未定义书签。

Inaccuracy (Imprecision; CV) ........................ 错误 !未定义书签。

Research 系列，多道，可调量程（8- 和 12- 道） .................... 错误 !未定义书签。

Inaccuracy (Imprecision; CV)................................ 错误 !未定义书签。

3 功能原理..................................................... 错误 !未定义书签。

4. 操作 . ......................................................... 错误 !未定义书签。

. 设定体积 ( 不适用于固定量程移液器 ) ............................. 错误 !未定义书签。

NEW!Eppendorf Research plus移液器使用宝典目 录3351213不同类型液体的移取方式移液器的正确操作错误的操作方式6786Research plus 单道移液器的拆卸方法Research plus 单道移液器下半部分组装锁定环的使用Research plus 多道移液器的拆卸方法Research plus 多道移液器下半部分组装99101010移液器内外部清洁方法移液器的消毒灭菌去除移液器的DNA 污染111112严格的移液器校准环境移液器校准的操作过程移液器的专业校准软件PICASO 14151524气体活塞式移液器(Air-cushion)外置活塞式移液器(Positive-displacement)443Eppendorf 公司始创于 1945 年，总部位于德国汉堡，是全球领先的生物技术公司。

公司长期与《Nature 》、《Science 》杂志合作，分别设立欧洲青年科学家成就奖和全球神经生物学奖，旨在为生命科学领域发掘和培养更多的人才。

1958 年，Eppendorf 拥有了全球第一支活塞式移液器的专利，并以创新的技术和卓越的品质，成为高品质实验室仪器的代名词。

作为全球发展的重点战略，Eppendorf 于2003年在中国香港和上海成立艾本德中国有限公司，全面实现直接销售和维修服务。

公司秉承 “质量，创新和服务” 的宗旨，为中国客户提供符合国际标准、高品质和人性化的产品，并提供一系列优质的服务。

2007年美国New Brunswick Scientific （NBS ）公司成为Eppendorf 大家庭中的一员，拓展了Eppendorf 在细胞应用领域的产品线。

NBS 公司以生产细胞培养、检测和储存的高品质仪器而闻名于世，在科研及商业领域广泛应用，范围涵盖生物医药、环境、食品和化妆品行业。

现在，我们将一如既往地履行承诺，为您提供优质的产品和客户服务。

二、1958年，Eppendorf 公司发明了世界上第一支微量加样器，并于1961年成功申请气体活塞式移液器专利。

eppendorf concentra说明书
1、离心机一定要放置在坚固、平稳、平整的水平台面或地板上，不能晃动。

2、先打开离心机样品仓盖子，检查是否存在异常，如有异常，先排除异常。

盖好盖子，接通电源。

设定一个基础转速和离心时间，转速可以设定为最大，时间设定为5分钟。

开启电源进行空转测试。

3、空转测试正常后，关闭电源。

打开样品仓。

将载有样品的试管对称放置在样品仓试管孔里。

4、注意放置样品试管时，一定要将同体积同质量的试管放置在对称位置。

如果质量不完全相同的，也要尽量将质量相近的、相差最小的放置在对称位置。

如果出现单一的样品，没有对称放置物品时，可以用相同或相近密度的液体代替装入离心管，放在对称位置，来完成离心工作。

通常用水代替。

5、样品离心参数的设定。

分离血液样品的离心转速可以设定在3500-4000转每分钟。

时间设定为5分钟。

其他如药液、浸膏这类的需要先尝试。

一般来说，样品的不溶物质与液体比重相差越大，越容易分离。

转速和时间都可以低和少。

相反，就是高和多了。

以分离血液样本为例，设定转速为4000转每分钟，离心时间为5分钟。

开启电源进行离心。

6、离心结束，关闭电源，打开样品仓盖子。

7、取出样品仓里面的样品，观察离心效果，如果效果达不到要
求，继续设定参数或增加时间或增加转速等进行调整，再次进行离心，直到满意为止。

样品达到离心效果后取出来必须竖直放在离心试管架上。

电动移液器的操作流程说明
电动移液器是一种电驱动的液体分配器，它通过电动驱动使吸头和皮头之间的活塞进行上下运动，从而实现液体的准确分配。

相对于手动移液器，电动移液器使用起来更为方便和精准，且可以自动化完成—定量的液体分配任务，广泛用于分子生物学、微生物学、医学和化学分析等领域。

电动移液器根据其容量大小和功能特点可分为多通道自动移液器、单通道电动移液器、多通道手动控制电动移液器等。

电动移液器的操作流程主要包括以下几个步骤：
（1）电源接通与开机
（2）选择相应的移液头和容积
（3）吸取液体
（4）移液
（5）清洗移液头
（6）关闭电源
使用完毕，可以将其竖直挂在移液枪架上，但要小心别掉下来。

当电动移液器枪头里有液体时，切勿将电动移液器水平放置或倒置，以免液体倒流腐蚀活塞弹簧。

如不使用，要把移液枪的量程调至大值的刻度，使弹簧处于松弛状态以保护弹簧。