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Up date你的補鈣觀念www.tool-tool.com Up date你的補鈣觀念
撰文／邱明瑜、袁燕　攝影／詹建華　圖片提供／西德有機醫藥生技、康是美
採訪諮詢／台北林口長庚醫院骨科醫師暨桃園分院骨科主任葉文凌、骨質疏鬆症學會理事長蔡克嵩醫師、上海徐匯區中心醫院醫師毛旭東、上海國賓醫療中心骨質疏鬆科醫師崔淮
「鈣」除了是人體骨骼中的重要成份外，包括神經的傳導、肌肉的收縮、血液的凝固、荷爾蒙作用都少不了鈣。在人生的各個生長階段，「鈣」都肩負著重要的生理功能，但你的補鈣觀念正確嗎？補進去了，身體又能吸收了多少？

世間男女啊...www.tool-tool.com 【女人啊！】 必 備 的 條 件 ：
首先是要漂亮。
妳要是不漂亮，那麼妳要有氣質。
妳要是沒氣質，那麼妳要溫柔。

你有將車匙鎖在車中的難堪經驗嗎？www.tool-tool.com 你有將車匙鎖在車中的難堪經驗嗎？
「你有將車匙鎖在車中的難堪經驗嗎？別著急！請用手機打電話給家人，請他一邊接著電話，一邊拿出備份的遙控鑰匙，在靠近電話筒的下方，按下遙控車匙開門的 鈕，此時你把仍在線上的手機靠在車門一英尺處，則車門自行打開，據說這個方法，即使車在幾百哩外，都通行無阻呢！」
好哇！居然有如此良策，那麼當年我被困車旁的窘境，相信再也難以重現啦！
但 當我把如此佳音，「大家告訴大家」知會親朋好友時，獲得的反應結果，千篇一律的都是「開玩笑！當我是三歲小孩好騙啊？荒謬呢！」「試又不要錢，既然沒有損 失，何不試試看呢！就看在它不但可省掉好多冤枉時間外，同時更可省下好多金錢的份上，就值得一試！反正『不試白不試』嘛！」親友們在我幾番苦口婆心的規勸 下，礙於情面不好堅持拒絕，終於勉強嘗試，結局卻是峰迴路轉。

何處無師-管理故事：仇人與恩人www.tool-tool.com 管理故事：仇人與恩人
作者/轉載者: 高永斌
大學剛畢業的時候，某電視公司請我去主持個特別節目，那節目的導播看我文章不
錯，又要我兼編劇。可是當節目做完，領酬勞的時候，導播不但不給我編劇費，還

包容www.tool-tool.com 每個人一生中都要信兩種教
你知道是什麼教嗎?? 當然不是睡覺......
是不計較與不比較
人活著都會有許多慾望，慾望多了，漸漸會慾求不滿。

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BW碧威股份有限公司針對客戶端改善切削方式、提供專業切削CNC數控刀具專業能力、製造客戶需求如：Cutting tool、切削刀具、HSS Cutting tool、Carbide end mills、Carbide cutting tool、NAS Cutting tool、Carbide end mill、Aerospace cutting tool、Carbide drill、High speed steel、Milling cutter、Core drill、鎢鋼銑刀、航太刀具、鎢鋼鑽頭、高速剛、鉸刀、中心鑽頭、Taperd end mills、斜度銑刀、Metric end mills、公制銑刀、Miniature end mills、微小徑銑刀、鎢鋼切削刀具、Pilot reamer、領先鉸刀、Electronics cutter、電子用切削刀具、Step drill、階梯鑽頭、Metal cutting saw、金屬圓鋸片、Double margin drill、領先階梯鑽頭、Gun barrel、Angle milling cutter、角度銑刀、Carbide burrs、滾磨刀、Carbide tipped cutter、銲刃刀具、Chamfering tool、倒角銑刀、IC card engraving cutter、IC晶片卡刀、Side cutter、側銑刀、NAS tool、DIN tool、德國規範切削刀具、Special tool、特殊刀具、Metal slitting saws、Shell end mills、滾筒銑刀、Side and face milling cutters、Side chip clearance saws、交叉齒側銑刀、Long end mills、長刃銑刀、Stub roughing end mills、粗齒銑刀、Dovetail milling cutters、鳩尾刀具、Carbide slot drills、Carbide torus cutters、鎢鋼圓鼻銑刀、Angeled carbide end mills、角度鎢鋼銑刀、Carbide torus cutters、短刃平銑刀、Carbide ball-noseed slot drills、鎢鋼球頭銑刀、Mould cutter、模具用刀具、BW微型渦流管槍、Tool manufacturer、刀具製造商等相關切削刀具、以服務客戶改善工廠加工條件、爭加競爭力。

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Reference source from the internet.   
In every machining system, one simply can't ignore the important role that cutting tools play. Oftentimes, the quality of a finished product would rely on the quality of the cutting tools. The quality and the performance of cutting tools would also directly affect a machining system's overall productivity. It is because of their importance that manufacturers would take into consideration several criteria before eventually buying a piece of cutting tool for their machining system. Included in these criteria are the tools ability to last long under rigorous operating conditions and their capability to perform at very high speeds. Also important is the tool's resistance to wear and tear, including resistance to breakage, edge and flank wear, cratering or top wear, chipping, built-up edge (BUE), deformation, and thermal cracking.
1. Kinds Of Tools
As the demand for better cutting tools increase, cutting tool suppliers also continuously develop products that can pass manufacturers' demands. Through the years, a lot of materials for the manufacture of cutting tools have been experimented upon; some have passed the standards while others were simply dropped. Today, there are only two types of cutting tools heavily favored in the machining industry: high speed steel (HSS) cutting tools and carbide cutting tools; and it seems that carbide cutting tools have slightly overtaken the other in popularity. So, what advantages do carbide cutting tools have over their HSS counterparts? Considering their lead in popularity, it is clear that the benefits of carbide cutting tools outnumber that of HSS cutting tools. And we'll understand these benefits better if we know what carbide really is.

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Reference source from the internet.    
The challenges involved in designing machine tools, cutting tools and fixtures to effectively mill features on miniature molds and microcomponents are daunting. The same could be said for optimizing tool paths for a tool that a machine operator probably won’t be able to see or hear while it’s in cut. Unlike standard milling operations, there’s no way that a machine operator can tell just how a tool is behaving while cutting in order to make the necessary changes to optimize the process. In addition, the toolpath strategies that might be suitable for “typical” milling work do not always scale down elegantly to work for micromilling applications.
probe
Still, there is an increasing demand for small part machining of medical, electronics and optic components. Recognizing this trend, the Fraunhofer Institute for Production Technology (IPT) in Aachen, Germany, recently sponsored a micromilling research project that brought together machine tool equipment manufacturers and mold makers with the goal of developing effective micromoldmaking strategies and processes. The struggle in creating NC software for micromilling has been effectively calculating tool motions with a tolerance of 0.1 micron. Cimatron (Novi, Michigan) is one software company that took part in the IPT project. The result was upgrading Cimatron E NC software to include a variety of functions for micromilling work.
Uri Shakked, a product manager for Cimatron who specializes in micromilling, offers the following five considerations when generating tool paths for micromilling applications.
1) Develop machining strategies appropriate for micromilling. Similarities between high speed machining (HSM) and micromilling do exist, such as avoiding sharp tool motions. When approaching corners, tool paths should be rounded, and the amount of that roundness depends on the machine tool and the feed rate. When micromilling, rounding becomes virtually useless below a certain value. Rounding of 0.2 mm, for example, is too large because typical micromilling stepovers are extremely small (approximately 0.01 mm). In this example, the roundness value is 20 times that of the stepover value, which means there would be wide gaps between sequential passes, high scallop height and poor surface quality.
The zero-overlap trochoidal method developed by Cimatron offers a way to clean such ridges. This method machines all relevant areas in a trochoidal style, but in order to prevent double-machining, tool back motions are raised from the workpiece surface in the Z axis. The tool then plunges tangent to the tool path on succeeding forward motions (see image on the following page).
Milling with cutting tools that measure 0.1 mm
Milling with cutting tools that measure 0.1 mm in diameter, such as the one shown here, creates challenges for both equipment and programming software.
HSM uses high cutting feeds to allow the chip to remove the heat that results from cutting; high spindle speeds to generate high cutting feeds; and high feed rates to reduce machining time and allow cutting with small stepover values. The feed rate, though, is limited by the tool’s maximum chip size per cutting edge. Because micromilling cutting tools have such small diameters, the spindle speed is often too slow to produce a high cutting feed, which, in turn, limits the maximum attainable feed rate. For example, to maintain a cutting feed of 100 meters per minute with a 10-mm cutter, the spindle should rotate at approximately 3,200 rpm. For a 0.1-mm cutter, the spindle would have to rotate at 320,000 rpm. Such a high spindle speed currently isn’t available. The maximum cutting feed possible with a 0.1 mm cutter is approximately 15 meters per minute—far from being considered HSM.
2) Conventional milling is generally more effective than climb milling. The decision whether to use conventional or climb milling for micromilling applications depends largely on the part feature being machined. Considering the delicate features typically found on micromolds and microcomponents, conventional milling is generally the milling method of choice.
Conventional milling is best suited for micromilling when the tool is long or the workpiece wall is very thin. As a cutting edge starts a conventional milling cut, the chip size is essentially zero and becomes thicker as the tool rotates. As the cutting edge penetrates the material, the force between them builds and the cutting edge tends to be drawn into the workpiece. This provides for a stable cutting condition that is well-suited for soft materials and delicate features.
However, conventional milling can potentially damage the tool’s cutting edge. As the cutting edge finishes the cut, it pushes away from the material. As it rotates back into a cut, it digs into the material. This causes the force on the cutting edge to rapidly change directions, shortening tool life.
In climb milling, the cutter engages the material at maximum chip size, and the tool and the part tend to push away from each other. The machine tool, workpiece and cutting tool must be robust enough so that vibrations are not introduced. Otherwise, cutting tool life would be shortened and surface quality would be poor.
tool back motions
Ridges that remain when milling a tight radius can be cleaned using a zero-overlap trochoidal tool path. In this method, tool back motions are raised from the workpiece in the Z axis and the tool then plunges tangent to the tool path on succeeding forward motions to create a better surface finish.
3) Combined roughing/finishing operations may be necessary. Roughing and finishing passes are traditionally performed as separate operations, using different spindle speeds, feed rates and depth of cut. However, this might not be possible when micromilling, especially when machining tall, thin walls or bosses on miniature parts. The wall thickness after a roughing operation will not provide sufficient support for the finishing operation, causing the walls to vibrate or possibly fracture during finish milling. At the very least, wall surface finish would be unacceptable.
When micromilling, cutting thin walls, roughing and finishing should be combined into a single operation, cutting layer-by-layer down the Z axis on alternating sides of the wall. The cutter should be tilted away from the wall to guarantee a single contact point between the cutter and the wall.