DIY日记0-30V可调线性稳压电源

做个电源，LT1083芯⽚，0~30V可调线形电源这次制作，⽤到的元件，除了数字电压表头和数字电流表头是买的，其他都是⽤的拆机元件外壳⽤了⼀个报废的电脑电源外壳，变压器也是旧的，不过功率够⼤主要调压芯⽚⽤了1083三端调压，最⼤输出到7.5A，不过平常⽤不到那么⼤的电流⽬前，还在制作外壳，机壳内部布局阶段这个⼤家伙，就是这次⽤的变压器了输出电压1083加上散热⽚的样⼦，其他部分元件还没有进⾏焊接整流桥这个三段开关，⽤来选择变压器输出电压先⽐划⼀下这个⼤家伙，放在机壳内部的样⼦制作过程也是没有什么详细计划，因为机壳就那么⼩，需要把不少东西塞进去，只能是慢慢摸索，交流电电源输⼊部分处理⼀下，加了⼀个保险管卡⼦把电源风扇安装在外部，保护⽹也在外边装进去变压器，已经占去⼀多半的空间了，其他元件，就是要好好找⽣存空间了原来板⼦上有个电线插头，可以利⽤⼀下处理以后的效果找的⼩散热⽚，给整流桥和7807稳压器散热，7V电压⽤来驱动风扇，和给两个数字表头供电安装的⼤致效果，开始把7V电压完全独⽴了，独⽴的整流桥，独⽴的7807稳压芯⽚，结果发现，7V电压和主电压的负极之间还有电压差，如果两个负极直接相连，还有微弱电流，最后还是放弃7V独⽴整流了，直接冲主变压器取电给1083主调压芯⽚，增加⼀下散热⽚这⾥⽤的⽀撑柱⼦，是电脑主板上拆的电压调节开关的位置找个⽩塑料遮挡⼀下，稍微美观了⼀些找了个⼩电位器，作为电压微调就地取材，找了⼀个固定的位置内部空间狭⼩，安排散热⽚，电路板，要费不少时间最后感觉这个位置，挺合适的散热⽚通过铁柱⼦和外壳固定另外还找了⼀个开关，安装在前⾯板上，后⾯还有⼀个开关，不过不够⽅便最后的效果内部接线测试过程中，发现7V供电的新⽚，⽐较热，原因是当使⽤⾼电压档位的时候，很⼤的电压加在稳压芯⽚7807上⾯，造成功耗过⼤，考虑给7807芯⽚多增加⼀点散热⽚，由于空间限制，在电脑主板上找了⼀个北桥散热⽚，厚度刚好，就是有点宽了，要裁下⼀块要增加的散热⽚稳压芯⽚，移动到旁边，给散热⽚腾格地⽅裁开了打孔，进⾏安装试验正式安装前，加上导热胶安装以后的效果厚度刚好不影响外壳最后进⾏电压调整，调节可变电阻，让电压变化范围正好落在30V以内，因为我这个4位的电压表，最⾼显⽰30.00V,超过以后显⽰1,变压器的输出能⼒35V，实际上很少⽤到30V以上的电压最⾼电压30V最低电压0.13V, 应该是0.00V就完美了，可能是我的元件问题，稍有差别精确调出来12.00V，纹丝不动⾃制电源和买来的合⼀个影LT1083稳压电源制作好了。

用W317制作输出电压为0V-30V连续可调的稳压电源
用W317制作输出电压为 0V - 30V 连续可调的稳压电源
用W317制作的稳压器，由于受集成块内电其电路的限制,最低输出电压为1．25V。

而附图所示电路则可以使电压从0V开始调整。

该电路和W317基本应用电路的不同之处是增加了—组负压辅助电源。

稳压管DW正极对地电压为—1．25V，调压电位器W的下端没有接在地端，而是接在稳压管正极，稳压电源的输出电压仍然从三端稳压器的输出端与地之间获得。

这样当W的阻值调到零时，R1上的1．25V电压刚好和DW上的-1．25V相抵消，从而使输出电压为OV。

该电路可以从0V起调，输出电压可达30V以上。

W317 稳压集成电路：
LM317 稳压集成电路：。

网络高等教育专科生毕业大作业题目：0~30V简易可调式直流稳压电源的设计学习中心：新疆伊犁经贸培训中心层次：高中起点专科专业电气工程及其自动化年级： 2009 年秋季学号： 0914********学生：李平指导教师：白俊完成日期： 2011 年 8 月 17 日摘要本文详细介绍了30V简易直流稳压电源计的发展现状，发展中所面临的问题。

随着时代的发展，数字电子技术已经普及到我们生活，工作，科研，各个领域，本文将介绍一种直流稳压电源，同时分析了数字技术和模拟技术相互转换的概念。

同时也详尽的介绍了此次设计中最重要的组成部件单片机的概念、工作原理及设备总体结构，其中包括MCS-51的发展历程，选型依据。

设计了一种基于单片机MCS-51的自动装箱机，介绍了所选用的8031、8255等单片机。

关键词：D/A转换；单片机；电源目录第1章绪论 (1)1.1 设计要求 (2)1.2 总体方案确定 (2)1.3 单元电路设计 (3)第2章系统硬件设计 (4)2.1 MCS—51单片机主要应用特性 (4)2.2 系统面板设计及控制原理图 (4)2.3 输入/输出接口系统设计 (5)2.4 调整输出的设计 (8)2.5 电路调试 (8)2.6 改进措施 (9)2.7 电源 (9)第3章系统软件设计 (11)3.1 主程序 (11)3.2 显示子程序流程图 (12)3.3 输入给定值中断服务程序 (13)第4章结论 (14)参考文献 (15)致谢 (16)第1章绪论电源技术尤其是数控电源技术是一门实践性很强的工程技术，服务于各行各业。

电力电子技术是电能的最佳应用技术之一。

当今电源技术融合了电气、电子、系统集成、控制理论、材料等诸多学科领域。

随着计算机和通讯技术发展而来的现代信息技术革命，给电力电子技术提供了广阔的发展前景，同时也给电源提出了更高的要求。

随着数控电源在电子装置中的普遍使用，普通电源在工作时产生的误差，会影响整个系统的精确度。

前几天发帖atx电源改0V-30V可调电源，我有朋友说很乱，我整理了一下，这是以前的帖子现在开始整理：我的得到了猪蹄煮不烂朋友的大力支持，在他的帮助下一步一步的进行，原文参考：第一步：打开电源拆除电源的 -5V +5v的部分，不知道怎么拆的就顺着后面往前拆，把欠压过压的电路全部拆除。

第二部：拆除TL494的1脚上的全部原件，TL494和7005的原理是一样的，然后拆除2脚的电阻，上面的电容不要拆，第三步：要在2脚做一个调压电路具体的怎么做我下面给大家分享。

调压原理借用的猪蹄煮不烂的“调整1脚和2脚的电阻都能达到调压目的只是1脚不能从0V 起调。

”2脚接7500 14脚取样基准电压（5V）这个电压是恒定的。

所以1脚能比较出电压是不是升高了，或者降低了”第四步：把12V的输出电容换成耐压50V的，不然会吓你一跳。

第五步：用一个24K的电阻接到TL494的一脚，另一角接电源的原12V的输出端作为R1 再找个的电阻接到TL494的1脚另一端接地，（我没有的电阻，我用了个5K的）作为R2。

TL494的2脚接一个的电阻接到电位器的中端，电位器的上端接tl494的13 14 15脚下端接地，我的这个电源，这样接好后，有个问题，电压不能从0v调起，又请教网友猪蹄煮不烂，在他的帮助下，减少电位器中端的电阻的阻值，顺利的把电压从到了。

我没有买到常闭温度控制器，所以我的风扇是长吹的，最后做了个表头的单独的供电电源，找了个电子射灯的电源，刚好上面有个12V的交流输出。

我就在上面加绕了双线并绕得到2个8V的电压，用全桥和7812 7805得到一路12V两路5v给风扇和表头供电，因为电压表，电流表是不能共地的，如果要想共地要买隔离的电压表和电流表，如果用指针的电压表和电流表就不需要另外做电源。

电位器一定要买线绕的，那样就不会感觉调电压变化太快。

电位器可以选用5K-40KZ 之间的任意阻值。

电源的输出端要接个3W500的放电电阻，可以及时的放掉输出电容剩余的电。

学号毕业设计（2016届本科）题目：0-30V可调直流稳压电源设计学院：专业：作者姓名：指导教师：职称：完成日期：年月日二○一六年五月目录摘要1Abstract2第1章绪论31.1 论文研究背景与意义31.2 国内外研究31.3发展趋势41.4 主要内容4第2章硬件设计42.1 主电路设计52.2 整流、滤波、稳压电路设计52.3主电路元器件的选择9本章小结10第3章控制电路设计103.1 LM317芯片及应用电路103.2 控制电路元器件的选择113.3 单片机AT89C51简介123.4芯片方案选择143.5 控制电路图163.6 四位共阳极数码管173.7 S8050三极管作用173.8 采样电路183.9 辅助电源电路19本章小结20第4章软件系统设计及仿真214.1 程序流程图224.2程序234.3仿真结果29本章小结30总结31致谢32 参考文献33 附录34摘要本文设计了一种基于AT89C51单片机为核心控制器的数控直流稳压电源，该电源主要由辅助电源、显示电路、控制电路、数模转换电路、稳压电路和模数转换电路六部分组成。

该系统以AT89C51单片机为控制单元，以数模转换芯片DAC0832输出参考电压，以模数转换芯片TLC1534对釆样值进行转换为数字信号。

辅助电源提供各个芯片、数码管和放大器所需工作电压，显示电路用于显示电源输出电压的大小，输出电压值可通过按键对其进行步进控制（±0.1V)，并且在按键长时间按下的时候能连续增加或减小。

关键词：数控直流稳压电源；AT89C51；D/A转换AbstractIn this paper, the design of a based on AT89C51 microcontroller as the core controller of NC DC regulated power supply, the power supply mainly by auxiliary power supply, display circuit, control circuit, digital to analog conversion circuit, a voltage stabilizing circuit and analog digital conversion circuit of six parts composition. The system takes the AT89C51 single chip as the control unit, and the digital analog converter chip DAC0832 output reference voltage, and the sampling value is converted to digital signal by the analog digital conversion chip TLC1534. Auxiliary power supply to provide each chip, digital tube and amplifier working voltage, display circuit is used to display the size of the output voltage and the output voltage value can be through the buttons on the step control (+ 0.1V), and in the button for a long time pressed can increase or decrease.Keywords: NC DC regulated power supply; AT89C51; D/A conversion第1章绪论1.1 论文研究背景与意义随着电子技术的发展，电子设备在人们的生活和生产中的地位也越来越重要，许多的电子设备对所需的电源也提出了更高的要求。

DIY ATX电源改调压0-30V调流0-7A首先提出的是，数字电压电流表要单独电源，（一个表一个电源，必须的）否则会共地烧表。

关于改造清单！选购的原件基本都是方便采购搜集的，或者都是拆机件就可以了！！！！《有人一直在问关于占空比的问题，我这里解释一下变压器改造问题1、当5V和12V绕组是独立的，你可以连接两个绕组。

这样电压达到35V绝对没有问题。

2、但是大部分电源不是单独绕组，5V是12V 一部分。

为简单起见，直接剪断公共地线，用原来12V绕组的两端，做全波整流3、这样可以将12电源由半桥改全桥整流、就是功耗比较大。

这个方案可行……这样不改绕变压器。

仅剪断12V接地。

全波整流达到自己想要的电压，理论上稳定值40V 5A 没有问题。

前提是全波整流桥堆要有散热措施。

》想要稳定必须重绕变压器，用0.2的4股漆包线并绕16匝即可。

具体参数：电压可调：0~30V电流: 0-7A短路电流：6.79A LM339控制过流，防止调流电位器损坏。

过压保护：意外输出32V，关闭电源温度控制：大于45℃自动启动风扇精确数显：数字电压、电流表以下是电路简图，这只是参考原理图，实际改造过程中，需要添加一些电容什么的。

参见下面经典的电路电源通用IC代换表:TL494/KA7500B/BD494/BDL494/S494PA/IR3M02/MB3670/MB3759/MST894C/TL594/ULN8186/DBL494/ULS8194R/IR9494/UPC494/UA494/TL494CN调压电路原理图，可以参照改造这个图只能调压0-15V 想要调压0-24V 换24K 和12K电阻即可，下面有计算公式。

电流表采样电阻和电流表接法以下是网上经典的电路图，仅供与参考下面说说我怎么做的，先要知道原理，看这里每个字看完ATX电源TL494原理：参考电路图下载:首先我是做了电压可调0-15V，几乎不改变原有电路再次换耐压高电容，做0-24V 0-30V最后拆除所有不用原件，做0-7A调流1、找到TL494 1脚和2脚电路，去除所有的原有电路，上面的电容不要拆。

0-30V任意值可调电源供应器制作概述这是一种高质量的连续可变输出稳定在0和30VDC之间的任意值可调的电源。

该电路还采用了电子输出电流限制器，可以有效地控制输出电流从几毫安(2毫安)三安培，该电路可提供的最大输出。

这一特点使得在这个电源中不可缺少的，因为它是可能限制电流典型最大，可能需要根据测试电路，电源，然后没有任何担心，它可能会损坏，如果出现错误。

还有一个限流操作，使你可以看到你的电路是超过或不预设限制一目了然的视觉指示。

技术规格-特点技术规格输入电压：................24VAC输入电流：................3一个(最大)输出电压：.............0-30 V可调输出电流：.............2一个可调输出电压纹波：MA-3......最大0.01%特点-减少了尺寸，施工方便，操作简单-容易调节的输出电压-输出电流限制与视觉指示-防止过??负荷和故障提供的设备的完整保护。

它是如何工作首先，有降压电源变压器次级线圈与额定24V/3A，这是整个电路的输入点连接在引脚1和2。

(耗材输出的质量，将变压器的质量成正比)。

变压器次级绕组的交流电压整流桥由四个二极管D1?D4组成。

采取跨桥的输出直流电压平滑储能电容C1和电阻R1组成的过滤器。

该电路采用了一些独特的功能，这使得它完全不同于其他同类的电源不同。

而不是使用一个变量反馈的安排，以控制输出电压，我们的电路使用一个常数增益放大器提供参考电压，其稳定运行的必要。

U1输出的参考电压产生。

该电路工作过程如下：二极管D8是一个5.6V齐纳，在这里经营的零温度系数电流。

在U1输出电压逐渐增加，直到二极管D8是开启。

当这种情况发生电路的稳定和齐纳参考电压(5.6 V时)通过电阻R5出现。

通过运算放大器的非反相输入的电流流动是微不足道的，因此，通过R5和R6的电流流过，两个电阻具有相同的值跨越他们两个系列的电压将完全两倍每一个两端的电压。

DIY日记——0-30V可调线性稳压电源啊哲作为一名电子爱好者，平时喜欢做一些电子小制作，在电路调试和制作过程中经常为电源犯愁，有时候为了调试一个简单的电路而单独搭一个电源，这样即费时又消磨DIY的兴致。

最近本人利用手头一些闲置零件，自己打造了一台“MINI”型直流0-30V可调稳压电源。

现将整个DIY过程与大家分享。

（图1）本人在深圳工作时买了几个大小不一的铝合金外壳（当时看到这些外壳挺漂亮就买了，一直闲置着），其中一个较大一点的外壳尺寸为：134x106x55mm。

家里还闲置了一个功率约30W左右的小变压器（该变压器是从旧黑白电视机上拆下来的，有8V和18V两组输出），其厚度还刚好能装到这较大尺寸的铝合金外壳内。

既然这么巧合，想不“撮合”它们都找不到理由了。

那接下来就是考虑稳压电路部分了，0-30V可调稳压电路可以通过以下几个方案来实现：1)采用运放加大功率管来实现（市面上很多批量生产的可调稳压电源都采用这种方案），该方案使用的材料非常低廉，但线路复杂不适合手工搭板；2)采用LM723专用电源稳压IC加大功率管来实现，该方案比较成熟，线路也比较简单，但LM723比较难买，需要到电子市场去找或邮购；3)采用LM317/338电源稳压IC，该方案线路非常简单，但按其典型应用电路接法，输出最低只能调到1.25V，要想0V起调必须加一个稳定的负电压基准来修正，一些电子杂志上也有人在LM317输出端串联2个二极管来降压，达到调“0V”的目的，这是初学的菜鸟们讨论的问题，大家心知肚明就行了；4)采用TL431电源稳压IC加大功率管来实现，该方案也具有线路简单的优点，但也同样遇到LM317不能调“0V”的问题；5)采用LM2576-ADJ开关型稳压IC来实现，该方案也具有线路简单、效率高等优点，但也同样遇到输出不能调“0V”的问题和电感线圈比较难加工；通过一番权衡利弊后，决定采用LM317的方案，刚好手头还有几个闲置的LM317T，“量身”设计的完整电路如图2所示。

电脑ATX电源改0V-30V可调电源，电流7A（申精）前几天发帖atx电源改0V-30V可调电源，我有朋友说很乱，我整理了一下，这是以前的帖子/read.php?tid=331637现在开始整理：我的得到了猪蹄煮不烂朋友的大力支持，在他的帮助下一步一步的进行，原文参考：/read.php?tid=328518第一步：打开电源拆除电源的3.3V -5V +5v的部分，不知道怎么拆的就顺着后面往前拆，把欠压过压的电路全部拆除。

第二部：拆除TL494的1脚上的全部原件，TL494和7005的原理是一样的，然后拆除2脚的电阻，上面的电容不要拆，第三步：要在2脚做一个调压电路具体的怎么做我下面给大家分享。

调压原理借用的猪蹄煮不烂的“调整1脚和2脚的电阻都能达到调压目的只是1脚不能从0V 起调。

”2脚接7500 14脚取样基准电压（5V）这个电压是恒定的。

所以1脚能比较出电压是不是升高了，或者降低了”第四步：把12V的输出电容换成耐压50V的，不然会吓你一跳。

第五步：用一个24K的电阻接到TL494的一脚，另一角接电源的原12V的输出端作为R1 再找个4.7K的电阻接到TL494的1脚另一端接地，（我没有4.7K的电阻，我用了个5K的）作为R2。

TL494的2脚接一个2.2K的电阻接到电位器的中端，电位器的上端接tl494的13 14 15脚下端接地，我的这个电源，这样接好后，有个问题，电压不能从0v调起，又请教网友猪蹄煮不烂，在他的帮助下，减少电位器中端的2.2K电阻的阻值，顺利的把电压从0.1V到28.6V了。

我没有买到常闭温度控制器，所以我的风扇是长吹的，最后做了个表头的单独的供电电源，找了个电子射灯的电源，刚好上面有个12V的交流输出。

我就在上面加绕了双线并绕得到2个8V的电压，用全桥和7812 7805得到一路12V两路5v给风扇和表头供电，因为电压表，电流表是不能共地的，如果要想共地要买隔离的电压表和电流表，如果用指针的电压表和电流表就不需要另外做电源。

新DIY的30V5A恒压、恒流稳压电源。

输出电压0-30V。

输出电流0-5A。

CC、CV指示。

2、受变压器输出抽头限制，交流2路自动切换0-15V一档，15-30V一档。

3、输出电压稳定性不错，电压漂移很小，空载连续开机4小时电压漂移在5mv之内。

4、负载测试：10V4A电压下载24mv，20V4A电压下载23mv，30V4A电压下载24mv。

5、调整管用了2个2SC3281并联。

变压器300W左右。

电压、电流调整用了多圈电位器，就没加微调了。

6、基准用拆机的431，运放全用LT1012。

电阻小功率的全用5色环。

7、印板是去年在广坛买的，刚好在网上找到相似的线路图。

8、散热片没找到合适的，只能这样装了，散热效果可能差点。

0-30V任意值可调电源供应器制作
概述
这是一种高质量的连续可变输出稳定在0 和30VDC 之间的任意值可调
的电源。

该电路还采用了电子输出电流限制器，可以有效地控制输出电流从几
毫安(2 毫安)三安培，该电路可提供的最大输出。

这一特点使得在这个电源中不
可缺少的，因为它是可能限制电流典型最大，可能需要根据测试电路，电源，
然后没有任何担心，它可能会损坏，如果出现错误。

还有一个限流操作，使你
可以看到你的电路是超过或不预设限制一目了然的视觉指示。

技术规格- 特点
技术规格
输入电压：................ 24 VAC 输入电流：................ 3 一个(最大)输出电压：............. 0-30 V 可调输出电流：............. 2 一个可调输出电压纹波：MA - 3 ... ... 最大0.01%
特点
-减少了尺寸，施工方便，操作简单
- 容易调节的输出
电压-输出电流限制与视觉
指示-防止过??负荷和故障提供的设备的完整保护。

它是如何工作
首先，有降压电源变压器次级线圈与额定24 V / 3 A，这是整个电路的。

0-30V 可调稳压电源General DescriptionThis is a high quality power supply with a continuously variable stabilised output adjustable at any value between 0 and 30VDC. The circuit also incorporates an electronic output current limiter that effectively controls the output current from a few milliamperes (2 mA) to the maximum output of three amperes that the circuit can deliver. This feature makes this power supply indispensable in the experimenters laboratory as it is possible to limit the current to the typical maximum that a circuit under test may require, and power it up then, without any fear that it may be damaged if something goes wrong. There is also a visual indication that the current limiter is in operation so that you can see at a glance that your circuit is exceeding or not its preset limits.Technical Specifications - CharacteristicsInput Voltage: ................ 24 VAC Input Current: ................ 3 A (max) Output Voltage: ............. 0-30 V adjustable Output Current: ............. 2 mA-3 A adjustable Output Voltage Ripple: . 0.01 % maximumFEATURES- Reduced dimensions, easy construction, simple operation. - Output voltage easily adjustable. - Output current limiting with visual indication. - Complete protection of the supplied device against over loads and malfunction.How it WorksTo start with, there is a step-down mains transformer with a secondary winding rated at 24 V/3 A, which is connected across the input points of the circuit at pins 1 & 2. (the quality of the supplies output will be directly proportional to the quality of the transformer). The AC voltage of the transformers secondary winding is rectified by the bridge formed by the four diodes D1-D4. The DC voltage taken across the output of the bridge is smoothed by the filter formed by the reservoir capacitor C1 and the resistor R1. The circuit incorporates some unique features which make it quite different from other power supplies of its class. Instead of using a variable feedback arrangement to control the output voltage, our circuit uses a constant gainamplifier to provide the reference voltage necessary for its stable operation. The reference voltage is generated at the output of U1. The circuit operates as follows: The diode D8 is a 5.6 V zener, which here operates at its zero temperature coefficient current. The voltage in the output of U1 gradually increases till the diode D8 is turned on. When this happens the circuit stabilises and the Zener reference voltage (5.6 V) appears across the resistor R5. The current which flows through the non inverting input of the op-amp is negligible, therefore the same current flows through R5 and R6, and as the two resistors have the same value the voltage across the two of them in series will be exactly twice the voltage across each one. Thus the voltage present at the output of the op-amp (pin 6 of U1) is 11.2 V, twice the zeners reference voltage. The integrated circuit U2 has a constant amplification factor of approximately 3 X, according to the formula A=(R11+R12)/R11, and raises the 11.2 V reference voltage to approximately 33 V. The trimmer RV1 and the resistor R10 are used for the adjustment of the output voltages limits so that it can be reduced to 0 V, despite any value tolerances of the other components in the circuit. Another very important feature of the circuit, is the possibility to preset the maximum output current which can be drawn from the p.s.u., effectively converting it from a constant voltage source to a constant current one. To make this possible the circuit detects the voltage drop across a resistor (R7) which is connected in series with the load. The IC responsible for this function of the circuit is U3. The inverting input of U3 is biased at 0 V via R21. At the same time the non inverting input of the same IC can be adjusted to any voltage by means of P2. Let us assume that for a given output of several volts, P2 is set so that the input of the IC is kept at 1 V. If the load is increased the output voltage will be kept constant by the voltage amplifier section of the circuit and the presence of R7 in series with the output will have a negligible effect because of its low value and because of its location outside the feedback loop of the voltage control circuit. While the load is kept constant and the output voltage is not changed the circuit is stable. If the load is increased so that the voltage drop across R7 is greater than 1 V, IC3 is forced into action and the circuit is shifted into the constant current mode. The output of U3 is coupled to the non inverting input of U2 by D9. U2 is responsible for the voltage control and as U3 is coupled to its input the latter can effectively override its function. What happens is that the voltage across R7 is monitored and is not allowed to increase above the preset value (1 V in our example) by reducing the output voltage of the circuit. This is in effect a means of maintaining the output current constant and is so accurate that it is possible to preset the current limit to as low as 2 mA. The capacitor C8 is there to increase the stability of the circuit. Q3 is used to drive the LED whenever the current limiter is activated in order to provide a visual indication of the limiters operation. In order to make it possible for U2 to control the output voltage down to 0 V, it is necessary to provide a negative supply rail and this is done by means of the circuit around C2 & C3. The same negative supply is also used for U3. As U1 is working under fixed conditions it can be run from the unregulated positive supply rail and the earth. The negative supply rail is produced by a simple voltage pump circuit which is stabilised by means of R3 and D7. In order to avoid uncontrolled situations at shut-down there is a protection circuit built around Q1. As soon as the negative supply rail collapses Q1 reMOVes all drive to the output stage. This in effect brings the output voltage to zero as soon as the AC is removed protecting the circuit and the appliances connected to its output. During normal operation Q1 is kept off by means of R14 but when the negative supply rail collapses the transistor is turned on and brings the output of U2 low. The IC has internal protection and can not be damaged because of this effective short circuiting of its output. It is a great advantage in experimental work to be able to kill the output of a power supply without having to wait for the capacitors to discharge and there is also an added protection because the output of many stabilised power supplies tends to rise instantaneously at switch off with disastrous results.ConstructionFirst of all let us consider a few basics in building electronic circuits on a printed circuit board. The board is made of a thin insulating material clad with a thin layer of conductive copper that is shaped in such a way as to form the necessary conductors between the various components of the circuit. The use of a properly designed printed circuit board is very desirable as it speeds construction up considerably and reduces the possibility of making errors. To protect the board during storage from oxidation and assure it gets to you in perfect condition the copper is tinned during manufacturing and covered with a special varnish that protects it from getting oxidised and also makes soldering easier. Soldering the components to the board is the only way to build your circuit and from the way you do it depends greatly your success or failure. This work is not very difficult and if you stick to a few rules you should have no problems. The soldering iron that you use must be light and its power should not exceed the 25 Watts. The tip should be fine and must be kept clean at all times. For this purpose come very handy specially made sponges that are kept wet and from time to time you can wipe thehot tip on them to reMOVe all the residues that tend to accumulate on it. DO NOT file or sandpaper a dirty or worn out tip. If the tip cannot be cleaned, replace it. There are many different types of solder in the market and you should choose a good quality one that contains the necessary flux in its core, to assure a perfect joint every time. DO NOT use soldering flux apart from that which is already included in your solder. Too much flux can cause many problems and is one of the main causes of circuit malfunction. If nevertheless you have to use extra flux, as it is the case when you have to tin copper wires, clean it very thoroughly after you finish your work. In order to solder a component correctly you should do the following: - Clean the component leads with a small piece of emery paper. - Bend them at the correct distance from the components body and insert he component in its place on the board. - You may find sometimes a component with heavier gauge leads than usual, that are too thick to enter in the holes of the p.c. board. In this case use a mini drill to enlarge the holes slightly. Do not make the holes too large as this is going to make soldering difficult afterwards. - Take the hot iron and place its tip on the component lead while holding the end of the solder wire at the point where the lead emerges from the board. The iron tip must touch the lead slightly above the p.c. board. - When the solder starts to melt and flow wait till it covers evenly the area around the hole and the flux boils and gets out from underneath the solder. - The whole operation should not take more than 5 seconds. ReMOVe the iron and allow the solder to cool naturally without blowing on it or moving the component. If everything was done properly the surface of the joint must have a bright metallic finish and its edges should be smoothly ended on the component lead and the board track. If the solder looks dull, cracked, or has the shape of a blob then you have made a dry joint and you should remove the solder (with a pump, or a solder wick) and redo it. Take care not to overheat the tracks as it is very easy to lift them from the board and break them. - When you are soldering a sensitive component it is good practice to hold the lead from the component side of the board with a pair of long-nose pliers to divert any heat that could possibly damage the component. - Make sure that you do not use more solder than it is necessary as you are running the risk of short-circuiting adjacent tracks on the board, especially if they are very close together. - When you finish your work, cut off the excess of the component leads and clean the board thoroughly with a suitable solvent to reMOVe all flux residues that may still remain on it. connections.gif (17,8KB) pcb.gif (60KB) (12,5cm x 8,7cm)As it is recommended start working by identifying the components and separating them in groups. Place first of all the sockets for the ICs and the pins for the external connections and solder them in their places. Continue with the resistors. Remember to mound R7 at a certain distance from the printed circuit board as it tends to become quite hot, especially when the circuit is supplying heavy currents, and this could possibly damage the board. It is also advisable to mount R1 at a certain distance from the surface of the PCB as well. Continue with the capacitors observing the polarity of the electrolytic andfinally solder in place the diodes and the transistors taking care not to overheat them and being at the same time very careful to align them correctly. Mount the power transistor on the heatsink. To do this follow the diagram and remember to use the mica insulator between the transistor body and the heatsink and the special fibber washers to insulate the screws from the heatsink. Remember to place the soldering tag on one of the screws from the side of the transistor body, this is going to be used as the collector lead of the transistor. Use a little amount of Heat Transfer Compound between the transistor and the heatsink to ensure the maximum transfer of heat between them, and tighten the screws as far as they will go. Attach a piece of insulated wire to each lead taking care to make very good joints as the current that flows in this part of the circuit is quite heavy, especially between the emitter and the collector of the transistor. It is convenient to know where you are going to place every thing inside the case that is going to accommodate your power supply, in order to calculate the length of the wires to use between the PCB and the potentiometers, the power transistor and for the input and output connections to the circuit. (It does not really matter if the wires are longer but it makes a much neater project if the wires are trimmed at exactly the length necessary). Connect the potentiometers, the LED and the power transistor and attach two pairs of leads for the input and output connections. Make sure that you follow the circuit diagram very care fully for these connections as there are 15 external connections to the circuit in total and if you make a mistake it may be very difficult to find it afterwards. It is a good idea to use cables of different colours in order to make trouble shooting easier. The external connections are: - 1 & 2 AC input, the secondary of the transformer. - 3 (+) & 4 (-) DC output. - 5, 10 & 12 to P1. - 6, 11 & 13 to P2. - 7 (E), 8 (B), 9 (E) to the power transistor Q4. - The LED should also be placed on the front panel of the case where it is always visible but the pins where it is connected at are not numbered. When all the external connections have been finished make a very careful inspection of the board and clean it to reMOVe soldering flux residues. Make sure that there are no bridges that may short circuit adjacent tracks and if everything seems to be all right connect the input of the circuit with the secondary of a suitable mains transformer. Connect a voltmeter across the output of the circuit and the primary of the transformer to the mains. DO NOT TOUCH ANY PART OF THE CIRCUIT WHILE IT IS UNDER POWER. The voltmeter should measure a voltage between 0 and 30 VDC depending on the setting of P1, and should follow any changes of this setting to indicate that the variable voltage control is working properly. Turning P2 counter-clockwise should turn the LED on, indicating that the current limiter is in operation.AdjustmentsIf you want the output of your supply to be adjustable between 0 and 30 V you should adjust RV1 to make sure that when P1 is at its minimum setting the output of the supply is exactly 0 V. As it is not possible to measure very small values with a conventional panel meter it is better to use a digital meter for this adjustment, and to set it at a very low scale to increase its sensitivity.WarningWhile using electrical parts, handle power supply and equipment with great care, following safety standards as described by international specs and regulations.CAUTIONThis circuit works off the mains and there are 220 VAC present in some of its parts. Voltages above 50 V are DANGEROUS and could even be LETHAL.In order to avoid accidents that could be fatal to you or members of your family please observe the following rules: - DO NOT work if you are tired or in a hurry, double check every thing before connecting your circuit to the mains and be ready - to disconnect it if something looks wrong. - DO NOT touch any part of the circuit when it is under power. - DO NOT leave mains leads exposed. All mains leads should be well insulated. - DO NOT change the fuses with others of higher rating or replace them with wire or aluminium foil. - DO NOT work with wet hands. - If you are wearing a chain, necklace or anything that may be hanging and touch an exposed part of the circuit BE CAREFUL. - ALWAYS use a proper mains lead with the correct plug and earth your circuit properly. - If the case of your project is made of metal make sure that it is properly earthen. - If it is possible use a mains transformer with a 1:1 ratio to isolate your circuit from the mains. - When you are testing a circuit that works off the mains wear shoes with rubber soles, stand on dry non conductive floor - and keep one hand in your pocket or behind your back. - If you take all the above precautions you are reducing the - risks you are taking to a minimum and this way you are protecting - yourself and those around you. - A carefully built and well insulated device does not constitute any danger for its user. - BEWARE: ELECTRICITY CAN KILL IF YOU ARE NOT CAREFUL.If it does not workCheck your work for possible dry joints, bridges across adjacent tracks or soldering flux residues that usually cause problems. Check again all the external connections to and from the circuit to see if there is a mistake there. - See that there are no components missing or inserted in the wrong places. - Make sure that all the polarised components have been soldered the right way round. - Make sure the supply has the correct voltage and is connected the right way round to your circuit. - Check your project for faulty or damaged components. Electronic Diagram.schem.gif (14,8 KB)Parts List.R1 = 2,2 KOhm 1W R3 = 220 Ohm 1/4W R5, R6, R13, R20, R21 = 10 KOhm 1/4W R8, R11 = 27 KOhm 1/4W R10 = 270 KOhm 1/4W R14 = 1,5 KOhm 1/4W R17 = 33 Ohm 1/4W RV1 = 100K trimmer C1 = 3300 uF/50V electrolytic C4 = 100nF polyester C6 = 100pF ceramic C8 = 330pF ceramic D1, D2, D3, D4 = 1N5402,3,4 diode 2A - RAX GI837U D7, D8 = 5,6V Zener D11 = 1N4001 diode 1A Q2 = 2N2219 NPN transistor Q4 = 2N3055 NPN power transistor D12 = LED diode R2 = 82 Ohm 1/4W R4 = 4,7 KOhm 1/4W R7 = 0,47 Ohm 5W R9, R19 = 2,2 KOhm 1/4W R12, R18 = 56KOhm 1/4W R15, R16 = 1 KOhm 1/4W R22 = 3,9 KOhm 1/4W P1, P2 = 10KOhm linear pontesiometer C2, C3 = 47uF/50V electrolytic C5 = 200nF polyester C7 = 10uF/50V electrolytic C9 = 100pF ceramic D5, D6 = 1N4148 D9, D10 = 1N4148 Q1 = BC548, NPN transistor or BC547 Q3 = BC557, PNP transistor or BC327 U1, U2, U3 = TL081, operational amplifier。

简单易制的0-30V（10A）可调稳压电源简单易制的0-30V(10A)可调稳压电源“工欲善其事，必先利其器”！对于电子爱好者来说，能拥有一台性能优良的电源，应该说是可以从“源”头上保证了制作作品的成功率和优良性能的发挥！本文介绍一种简单易制的可调稳压电源，可以在0-30V的范围内稳定的输出最大10A的电流，基本上可以满足常见的电子制作需要。

而且其电路非常简洁、制作简单，性能优良稳定、成本低廉，非常适合电子爱好者制作，下面简要介绍一下其电路原理、制作方法和注意事项。

电路原理本电源在保证功能适用、性能稳定的前提下对电路尽量简化，这样既可以降低制作工作量和难度，又可以提高制作的成功率。

电路如图（1），主要由Q1、Q2、IC1组成的调整稳压电路和IC2组成的-1.25V生成电路，以及IC4组成的输入电压自动切换控制电路和以Q3、M1、M2为主组成的输出显示、指示电路等4部分电路完成整机功能。

由电路图可以清楚的发现本机稳压部分采用了常见的工频变压器整流、滤波、线性稳压的工作原理，之所以没有采用高效率、轻便的开关电源电路模式，主要是因为考虑到作为实验用供电电源，对其主要的要求是输出宽可调电压范围、大输出电流供应、低输出纹波电压、电源纯净度高，对于电源效率要求并不高，而开关电源虽然效率高，但其输出波形干扰纹波大、可调范围窄，因此采用传统的线性稳压电路。

下面介绍一下整机电路的工作原理。

从J1、J2输入的交流电网220V电压经K1、F1输入电源变压器B1的初级，从其次级分别输出9V、12V、24V的交流电压。

输出的9V交流电压经D2整流、C7、C8滤波后加在IC2/LM337的输入端，在其输出端产生-1.25V的电压，R6作为IC2的负载，C9使IC2输出端的电压更为稳定、纯净。

设置此部分电路的目的是为了用其产生的-1.25V电压抵消IC1/LM317输出端最低只能到达+1.25V的电压，从而使整机输出电压可以从0V起输出，而并非是从+1.25V开始输出，这样可以满足部分需要低于1.25V的低电压的试验场合的需要。