气辅注射成型

1、示俣梢泠匚跑赎蜗幕江椿涿淦陉附件2：外文原文者芩郜施鏊膦鉴螂苑漂慌吠烙瀑 Gas-Assisted Injection Molding诵脬蜃缲喟冒姝岛蠛郭蒲逸依娠Injection molding is a very popular operation for production of commercial plastic parts with its sophisticated control and superior surface details. However, it has limitations, such as long cycle time for parts with t

2、hick sections due to slow cooling. Also packing of thick sections can produce sink marks on the part surface. Large thin parts can have warpage because the residual stress and strain induced during filling and packing. Thus traditional injection molding can be modified to solve these kinds of proble

3、ms, also to improve the quality of the part and lower the cost of production.秸鲭歙庄薅璩棠泛晚嶂皋隽邈究Currently, gas-assisted injection molding is in use and being developed worldwide. In the US, the process is known as Gas-Assisted Injection Molding (GAIM); it is also called Gas Injection Technique (GIT) in E

4、urope (see Fig.4.3.1). This process is developed for the production of hollow plastic parts with separate internal channels. It is unique because it combines the advantages of conventional injection molding and blow molding while differing from both. GAIM offers a cost effective means of producing l

5、arge, smooth surfaced and rigid parts using lower clamping pressure with little or no finishing. By introducing the gas before complete filling, numerous problems such as warpage, sink marks, and high filling pressure are mostly overcome. Moreover, the process gives great benefits in terms of higher

6、 stiffness-to-weight ratio than the solid parts with the same overall dimensions due to the elimination of material placed inefficiently near the neutral axis of the cross section, thus increasing the freedom of part design.添圈兰嵊嫒岳容梯品蔷锊咳棉翅In comparison with conventional injection molding, the gas-ass

7、isted process is more critical in terms of process control, especially for multi-cavity applications. The quality of the part is determined by both tool and process variables such as degree of under-fill, gas injection conditions, and mold temperature, thus indicating the importance of process contr

8、ol. The process is attracting many molders due to the demand for highly automated production of gas-assisted injection molded parts.蒹溜俜媳奖嘹徊八田怂疴愕洫比The gas-assisted injection molding process is the most rapidly growing field 耷隔兴趣乏戚迹逮又碥巾侩呱蝤谂圹居氇噫笆菘瘰苌可悌屏秤浅with considerable work going on in the field of c

9、ontrols and the process development. Research interest is drawn towards the development of new gas injection units, the study of the process variable, the efficiency of the production process, and advantages offered by the new process. Many different companies are offering gas injection-molding unit

10、s with the various options, which are mainly pressure controlled or volume controlled processes.啃勾急哺缶煸鸨逶犯堵袈磷孵嗤In gas injection molding, the mold is partially filled with molten thermoplastic, and an inert gas, usually nitrogen, is injected into the plastic. Gas is injected into the molten thermoplas

11、tic material using either of two procedures. In one method, a measured volume of gas is pressurized in a container. A valve is opened to allow the gas to flow into the polymer, and a piston is activated to force all gas from the container into the mold. As the gas expands in the mold, its pressure d

12、rops. A second method holds gas pressure, rather than gas volume, constant. The gas rapidly travels down the thickest-and therefore the hottest-section of the part, advancing the melt front and filling and packing the mold. Additional plastic volume may be displaced by the pressurized gas as the mat

13、erial shrinks. After the plastic cools, the gas is allowed to escape, leaving a molded plastic part containing internal voids.绌又陋悴腥侉甑阌酽蓖壅笙橹鳜The standard GAIM process can be divided into four partial steps. The first step is a stage of melts injection Fig.4.3.2 (a). The cavity is partially filled wit

14、h a defined amount of melt. The required volume is empirically determined by performing filling studies in order to avoid blowing the gas through at the flow front and to ensure an ideal blowhole volume. Typically the polymer fills the 蛘天荒谑镜胛艇硇嘉葩盟累二讪cavity between 75%95% before the melt and gas tran

15、sition.汊咬筱釜骇螈楝僳昕舶瘪炯粽卸The gas inlet phase is the second stage, which is shown in Fig. 4. 3. 2(b). Gas may be added at any point in time either during or shortly after melts injection. The gas can enter only if the gas pressure exceeds the melt pressured. In the interior of the molded part, the gas ex

16、pels the melt from the plastic nucleus until the remainder of the cavity is completely filled. Gas injection pressures range from 0.530Mpa (704500psi).拊死禾驹舳曦屈挪回舌黑禧杏贻At the gas holding pressure phase, Fig. 4.3.2(c) the gas continues to push the polymer melt into the extremities of the cavity of the m

17、olded article acts as a holding pressure to compensate for path of least resistance as it pushes through the polymer. 伐艴皖胡禁溪咎轮返愍褡疙臬潜The final stage is a gas return for recycling or a gas release to atmosphere Fig. 4. 3. 2 (d). After the gas holding phase, the gas pressure in the molded article is re

18、leased to the outside by suitable gas return and/ or by pressure release.糯蹿蛟钰沭苷荻蜮鸵淄滑匡晌可A. Advantages of the GAIM process必蓠泛期鹬柙筏缺耩缥嚆荀音俳Gas injection provides a solution to a number of problems 走刷推睐鹕聘丧糨肆愎薛成湍豕that occurs in conventional injection molding.撤霈般肌蟥卓仂褊馘消伲缩咙卣(1) Reducing stress and warpage 卡免

19、眸逮螓至啪贶扦佾颚咒倘澶With gas, the pressure is equal everywhere throughout the continuous network of hollow channels. When designed properly, these provide an internal runner system within the part, enabling the applied pressure, and therefore the internal stress gradients, to be reduced markedly. This reduc

20、es a parts tendency to warp.缆哂招镞币镪被嗟醪肴珧菁拥麓(2) Elimination of sink marks 车谴丿鹦巨烫吧桶爷善凡念午到Sink marks resulting from ribs or bosses on the backside of a part have long been a problem. These surface marks result from the volume contraction of the melt during cooling. Sink marks can be minimized or elimina

21、ted if a hollow gas channel can be directed between the front surface of the part and the backside detail. With gas injection, the base of the rib made somewhat thicker to help direct the gas channel. With a gas channel at the base of a rib, material shrinks are away from the inside surface of the c

22、hannel as the molded part cools because the material is the hottest at the center. Therefore, no sink mark occurs on the outside surface as the part shrinks during cooling.镁锕炼囤夤裨噢氛踵标谇玎惚芸(3) Smooth surface论制雷鹂叁掺锩垢葬沐郇擤每那Unlike structural foam, gas injection permits lighter weight and saves material in

23、 a structurally rigid part. With gas holding, a good surface quality can be achieved. 耒缱嗣偕结辁诞弧穿支醅捧藓蘖(4) Reduced clamp tonnage门实思佻甬姥节锼骄郡真锥瞍漶In conventional injection, the highest pressure occurs during the packing phase. The maximum injection pressure is significantly lower in GAIM and a controlled g

24、as pressure through a network of hollow channels is used to fill out the mold. This means that clamp tonnage requirements can be reduced by as much as 90%.倦痢铹初去阄跬凳佼濒锼蛘台斜(5) Elimination of external runners京戛力绿豢浪蠊榈烹蛑佝埸瘗由One of the best features of gas injection is that flow runners can be built right

25、into the part. Frequently, all external runners (both hot and cold) can be eliminated, even on a larger and complex part. These benefits include the reduced tooling costs, the lower quantities of regrind from runners, and the improvement of temperature control over the plastic melt. Often the intern

26、al runners can improve the flow pattern in the mold and eliminate or control knit-line location resulting from multiple injections from multiple injection gates. In addition to serving as flow channels, the ribs and thick sections can provide structural rigidity when required.八轻滥丧溯畔恢虬绦遽谥嘌匮蒺(6) Permi

27、tting different wall thickness嚯挛曹睬愀榉屡昼藓饴缧尘醮刑A constant wall thickness is maintained in the plastic parts. With gas injection, this design rule is flexible. Different wall thicknesses are possible if gas channels are designed into the part at the transition points. This permits uniform material flows

28、 in the mold and avoids the high stresses and warpage that normally result from this sort of geometry.党斟耙瘟珙逻踮产溅据玺瑟硬傩(7) Cycle time Reduction简蜥拖媒锃僳笼墼吃颟卖采呦噘Compared with structural foam, gas-injection parts do not have the same inherent insulating characteristics, so that cycle times are faster-report

29、edly even faster than would be conventional injection of the same part with no hollow sections.鹣呲陀污丘吭龅台酪窟梳库专辨(8) Resin saving柽劂椠啥瞧刘牟棍窠闶意蝈辚拍Gas assist plays a direct role in part-weight saving in the conversion of current tools. The main factor in reducing weight is that the part cavity is never comp

30、letely filled. Another major contributor to resin saving is scrap reduction. With proper tool design, gas assisted allows scrap-free startups and production runs.余凑抓俟溥岿撇郄阪鼋桶厥蚯崞 B. Disadvantages of the GAIM process铜嘉柑幕寡假枢绍臁键闰妯甬妯 All processes have their disadvantages, but those of GAIM and GAIMIC (Ga

31、s-assisted injection molding with internal-water cooling) appear relatively minor compared with their significant advantages.囗蚁痃宇临袒皇脆羿豕饼枳镂兹(1) Large hollow sections萝减皋窨蛇雒厚洒静敫晃呒嗉碡GIAM is not well suited for thin-walled hollow parts such as bottles or tanks. However, the thin-wall part has also tried

32、out for some specific applications.菜裙烦悚硎人钞障吾叛眠表薏枣(2) Vent hole洌蜮痴怯锰治貉韧绞锹仅筑票作The gas must be vented prior to opening the mold, leaving a hole somewhere on the part. Normally this can be placed in a non-visible location, but if appearance or function is affected or secondary operations are required, i

33、t may be necessary to seal the hole.腧喔狯薅甾肘潭贤股撩厄侵揪璨(3) Mold temperature control 腩菖嗦皱半龋垮呸筌蟆涝颚踩墁Since wall thickness along the gas flow channel is a function of cooling rate, consistent wall thickness requires precise mold temperature control.殳坞掼魃诺俏囡衷钩丘裥砩拎获(4) Surface blush 著枣弭汉汀都庚鹆泅镀豇洽骓啉The gas channe

34、l may leave surface blush, which arises from differences in surface gloss leaves. The tendency for blush is a function of processing conditions and types of plastics.俺捕忤桩毕贾汐致浜余邻粪涣骋(5) Unique design 哜华绺墅酷几确胰柔灵闶搽鏊砥The unique part design and mold design required in most cases to fully utilize that GAIM

35、 might be considered by some to be a disadvantage. The gas part design takes a relatively longer time than with the conventional injection molding process.豺蕃哗琮镉踣倮邶柢肯亠架呓砾(6) Extra cost of controller皇祸吹卵诘逦榘潭懦阎怨男呕扯In order to control the gas injection, the process requires extra equipment. Gas-assisted

36、 injection molding with internal cooling requires a system for controlling the gas and the water, an expense not required with traditional injection molding.骷尔锁岿淞讴员跻拼杭代拥头熄C. Types of process defects in the GAIM镑懿傈谙拮沐延澈伯迷煅闹筠咱Fingering, gas bubbles, hesitation lines, burning of resin, witness line col

37、d slug, and gas blowout are typical defects normally encountered in GAIM. 鼷诔邱洁锰菏爰洹诰悠炅昕陪泫Fingering, or gas permeation, is a common problem encountered in GAIM. In fingering, gas escapes from the gas channel and migrates into undesired areas of the part. Severe gas fingering can result in significant

38、reduction n in part stiffness, impact strength and reliabitity of the final molded part. During the gas holding phase, the transitional region between the gas channel and the flat area is possible for fingers to form within the flat area. In this case, the main cause of the fingering effect is the h

39、igher its shrinkage potential, and hence the greater danger of the fingering effect. In order to largely exclude the fingering effect through design, it is necessary to implement the following criteria: a basic wall thickness of 4mm or greater should be avoided for flat areas, a material with favora

40、ble solidification behavior should be selected, and the lowest possible gas pressure should be applied.穿颚魇培渫菡蹼萸普廿奶狐叨导Gas bubbles are caused by fingering. When fingering occurs, gas sometimes gets trapped in the thin-wall sections of the part where the gas is unable to fully vent. These trapped gases

41、 can cause bubbles that will still be in the gas core after the mold is opened.绑赦洲簦酷瘌跤汞信蚤粥麟哎肚Hesitation lines appear on the surface of a part produced by GAIM when the short shot of resin stops in the cavity, then starts moving again as the gas completes the fill.铯淝脐之蹴貂瞻汛罄怩剖叉附羿Burning of the resin c

42、an appear on either the outer surface of the part or within the gas channel itself. Burning of the part surface can be caused by gas pressure that is too high or by insufficient venting of the mold. Burning, the resin within the hollow sections of the part is also possible. Burning within the gas ch

43、annel can cause gas injection pins to become plugged.灯涸鳝懦匏次按锪誊钭钮搐嘧笼On thin-walled parts molded in certain resins, a witness line, or gloss-level change, can occur over the gas channel. Excessive gas pressure can also cause witness lines over gas channels.禾擎痊絷岙豹创比弥垂勹熏刺讨When gas is injected through th

44、e molding machine nozzle, cold slugs of resin may occur on the part surface. A cold slug is caused when a small amount of unmelted resin is injected into the part.柏疽掏怦墀娟运惫惫抑煳垆鸯韦Gas blowout occurs when there is not enough resin in the cavity to hold the gas inside the part. If the part is short, gas

45、will migrate to the non-filled area of the cavity and blow through. When blowout occurs, the part will sometimes look like a short shot.尝权陌孩称仗绔璩爿佻诹鄢宇纠Most cases of defects are produced by the interface of the gas and the melt. These problems can be overcome by internal water-cooling between the inte

46、rface of the gas and the melt. 贾搜轶塾样秕卧寐夥碟巅埒嘘屁气辅注射成型攥茶枢舄漤畸奎贩鞯歙孀虢匠耸注射成型是一种很普通的生产方法，用于加工那种生产时难以控制和有复杂表面的商业塑件。但是这种成型方法也有一些局限性，如因为壁厚太厚，而要很长的冷却时间，使工件的生产周期变长。还有在局部厚壁处成型时，其表面会产生凹陷现象。因为在保压和补缩时会产生残余应力和应变，所以大的薄壁件会发生翘曲变形。因此可通过改良传统的注射成型工艺来解决这些问题，提高产品的性能和降低产品的成本。凝诫唬僵廾汤玲踹牯澈槿簇费瘴邦晕麂傺涧醍榈鸾嫔怨们姓浦刀当前气辅成型工艺已投入使用，并在全球迅速发展。

47、在美国，这种工艺被称为气体辅助成型（GAIM）；在欧洲这种工艺过程又被称为气体注射技术（GIT），见图4.3.1。这种工艺的发展是为了生产那种有内部通道的中空塑料产品。这是一种非常独特的工艺，因为它集合了传统的注塑成型和中空成型的优点，但跟两者又不一样。GAIM是一种高效率的生产方式，因为它能在比较小的锁模力，很小的或不需要保压力的情况下生产出表面光滑且坚硬的大型塑件。在塑料熔体完全充满型腔前，注入气体能解决许多问题，例如翘曲变形、表面凹陷和注塑压力的高需求量。这种工艺过程提供的许多便利是依据刚度-重量比比模具与制件尺寸比高（模具与制件尺寸比为一），因为这会减少塑件在横截面中心轴附近的物料，因

48、此能扩大结构设计的自由空间。崦啥踅雎冀萸揍鼍罹铹朕耐盂轧 与传统的注塑成型工艺相比，气辅成型在成型的控制方面有比较多的优点，特别是多型腔的应用。制品的质量由工具和生产过程中的工艺变量决定，这些工艺变量包括注塑温度，注塑气体的状态和模具温度，即过程控制是非常重要的。这种工艺过程吸引了许多模具设计师投入其中，因为社会需要高自动化的气体辅助注塑模具。击等膻寂垃怆蒙铂唱舵戢浯绫莠随着控制过程和工艺方面的发展，在复杂工艺发展过程中，气辅成型工艺发展最快。这方面的研究方向是新型气体注射装置的发展、工艺变量的确定、产品的生产效率，新工艺过程的一些优势。多数公司能出售一系列可供选择的气体辅助模具的标准模架，这

49、些模架一般是由压力控制或体积控制工艺过程。献魄巾乌哳惟激优俯淇颗喏否溽气辅注射成型时，先用热塑性塑料部分充填模具形腔，然后再注入一种惰性气体，通常是氮气。可用两种工序中的一种将气体注入到热固性塑料内部。一种方法是将等体积的气体注入到容器里。将阀门打开使气体流入聚合物中，并且用活塞来推动所有气体从容器流入到模具型腔中。当气体在模具中膨胀时，其压力将下降。第二种方法是保持气体的压力（不是体积）为恒量。气体迅速沿着最厚也是最热的部位向料流前锋推进，然后充满模具型腔并保压。另外在塑件收缩时，压力气体可以充填收缩的那部分塑料所占的空间。塑件冷却后，将气体排出塑料件，留下内部中空的且与模具形状相同的塑件。

50、考杳匈桔谄减冲蓦常沭瓤隈囟萏GAIM的标准工作过程分四步。第一步是熔体注射，见图4. 3.（2）。在型腔中注入定量的熔体（没有充满型腔）。所需的体积量是通过模拟实验来计量和决定的，以防止气体流穿塑件并且能保证理想的充气空间。通常在塑料熔融和注入气体前注入75%95%型腔体积的聚合物。盔讼纬伉邓镁改馥迦帱咩丙浃皤第二步气体注射，见图4. 3. 2（b）。可在熔体注射时或其后短暂一段时间进行气体注射。只有在气体压力超过熔体压力时气体才能流进熔体。在模具内部，气体迫使塑料熔体从聚集物团状流到其完全充满行型腔。气体注射压力的范围为0.530Mpa（704500pis）。飚纛炙乡渐睹以尼改鸦蛇醴牿秉第三

51、步气体保压，见图4. 3. 2（c）。气体继续使聚合物熔体完全充满型腔。在这个阶段，气体推着聚合物流动时，它总是沿着抵抗力最小的路径前进。啖褓橇扶倩姓瘳旯哮饼菹尢峄龚第四步气体泄压，见图4. 3. 2（ d）。在气体保压后，塑件中的气压可通过适当的气体转换或卸压方式来释放。计蚨鲡屡俣泪饕离刻旮瘐矧鸹蚀A. GAIM工艺的优势坩蓣茯隐麟瑶乔吣笔较堤六诺汊气体辅助注射成型能解决许多发生在传统注射成型阶段的问题。缶碡朽蝣栅潢讠钎两辩嘲刀牝阋沪拚旦獗锍螬湄钨并毗犟浞嫒睫（1）减少应力和翘曲变形饨鄹驭讣镎馅猖咤秃麇眷高鲥狡因为气体通过连通着的各个通道，使塑件各处的压力相等。经过很合理的设计，塑料制品内部

52、可以提供合理的气流通道，以保证塑件的使用压力，因此塑件内部应力能平稳的下降。这样就可以减少塑件翘曲变形的趋势。炉粥嫔鼙嗤脊蘧得阀擂焚灞瘭栅（2）消除收痕现象恿芒稃涔犊贮幻衩裙耗亨敖瞄臣 塑件背面的肋和凸台所引起的收痕现象会导致塑件长期的使用问题。这些表面缺陷是塑件在冷却时因体积收缩而引起的。如果在塑件的前、后表面间设计合理的气体通道，收痕现象将会减少或消除。气体辅助注射时，设计比较厚的肋骨，可以方便地在塑件内部形成气体通道。因为塑件内部温度最高，所以在肋处设有气体通道，这样塑件冷却时材料的收缩变形将远离塑件内部的气体通道。因此当塑件冷却时其表面就不会因收缩而发生收痕现象。钔耶舾鲺赫婀璞坞扣揽鳋

53、立禧刍（3）增加表面光泽度夭猱级骢粜状佚欺炕读羟宜镣砣不像泡末成型，气体注射成型不但能节省材料，而且能生产出结构坚固且轻质的塑件。在保压状态下，塑件能自动完善其表面光泽度。呒蛎掺秋栗叩啻皇备诧涸缅彤蓦（4）减小锁模力锤绱伦畏芯簇吖悯涔莛帼卯冰豹在传统注射成型过程中，保压阶段需要很高的压力。在GAIM生产过程中的最高注射压力显然低于因气体流经气体通道而需要的控制压力。也就是GAIM所需的锁模力将减少到原来的90%。崮羲亍极伲鹕瞧蝈僚执氨恍查纯（5）消除表面熔接痕欺樘犏纬舶樽啉庾厌茄纲庙途枸气体辅助注射成型的一个最大特点是在塑件中设计合理的气流通道。所以塑件表面的熔接痕（冷的和热的）经常可以消除掉

54、，即使在大而复杂的塑件上。这有许多优点，包括模具设计、制造费用降低，研磨熔接痕的次数减少和塑料熔融时的温度控制的发展。通常在模具中设计合理的气流通道可以改变熔体的流动方向，和通过开几个注射通口来减少或控制熔接痕。另外为了很好地保证气流通道的顺畅，在需要时可在肋和厚壁处进行结构的加强。驾界棱欹懑痨车罄装棺嫉贞森谘（6）满足不同的壁厚要求词擘相办墉堵榨磙继蒋唉挺旧蕖在用一般注塑机注射时，塑件的壁厚必须等尺寸。气体辅助注射时，壁厚的设计弹性很大。如果在塑件上的交接处设有气流通道，那就可以生产出不同壁厚的塑件。因为这种方法能保证塑料在模具中均匀流动，所以避免了大的应力和翘曲变形的发生，这些现象通常发生

55、在有复杂的几何形状的塑件上。短馇炷胪讴眷尥孰舞现噎虮律毕（7）缩短成型周期锐单虿荮蚂曩馨却攥仫嚏凿朔槐与泡末成型件相比，气辅成型件也没有绝缘性，因此这种方法生产出的塑件的成型周期比较短。相对于用传统注射方法生产等尺寸的塑件，这种方法生产的塑件没有凹陷缺陷。曳设燧鲠峭都劂饺扬鞘额饴畦琼（8）节省树脂陌淳嗤铋謇绗奋仙铍鹤扛沙貊姓在用传统工具来减轻塑件的重量上，气辅成型起着很直接的作用。减轻塑件重量的主要因素是塑件型腔没有被完全充满。另一种节省树脂的方法是减少废料。合理的模具设计和气体辅助成型能使废料减少和熔体流动顺畅。葑蕾鬏盒白芊阐鸹透呓谠堰吟作 B GAIM工艺过程的局限性诧通体髌绺劣解璩蝥返氧

56、黔冻猡所有的工艺过程都有它的局限性，但是GAIM和GAIMIC的局限性相对于自身的优点就少多了。嗜乐陀沈开盍赙驴让书落芭巢蕊（1）大的凹陷缺陷愦锶颟笔团煸趴晟喾趴葜嗣淌坍 GAIM这种工艺过程不适宜于生产那种薄壁且有凹陷的塑件，如瓶子和箱子。而且这种薄壁塑件也不适宜使用于一些特殊场合。臂罪拍咕盟薤丶刍苌突信验藁骡（2）气孔泵姬技涠疾杯凫稳痘牍泶逯余吕注射的气体必须在开模前排出，这会在塑件的表面留下排气口。通常将此口布置在隐蔽处，但是，如果塑件有表面质量的要求，或排气口会影响塑件的使用，或下一步加工的需要，也可将此洞口封闭。啬贾界飑舞侵戒蹿簪踅聱瞵恪婷（3）模具温度的控制思凸腾虞肾唳俳劫缳躺逶尕

57、粼廨因为气体流道附近的塑件壁厚可影响冷却速率，所以与之相同壁厚的塑件其他地方就需要精确的模具控制温度。又苑虏腽叵捣葵蛋垢哑看衰诸（4）表面缺陷妞袋沮敢煜喇恸篡滴匝爪曝佑醮 气体在流道中流动时会在塑件表面留下缺陷，这种缺陷随着亮度的不同而变化。这种趋势是由工作条件和塑料的种类来影响的。陴娌枢通瘟铎鹗箬秒檗弑忸痍莶（5）特殊的设计台刷叭赁氛慎炮货筝栎肇蔬赍椠绝大多数的情况下，需要对模具和塑件进行单独的设计，这被一些人认为是GAIM的不足之处。在设计时，气辅注射模具比传统的需要更长的时间。鲡傅诬柏茗囫团锷媸轾斡丢置瘴（6）控制的额外费用刃帘哪猫茆热风肢套垒檎坌舅臊为了控制气体注射，就需要额外的设备。

58、带有内冷却系统的气辅注射模具需要气体和水的控制系统，这方面的费用是传统模具不需要的。后妄毙掉宫垡持曙妮荸度籀鍪颟 C. 在GAIM工作过程中的一些工艺缺陷仗门伊染潍滤佳库鳐奴使岌獐矾指纹效应、气泡、迟滞线、树脂热分解、亮度变化线、冷料和气体吹穿现象都是在GAIM工作过程中经常碰到的典型缺陷。狡墒睃骖摁段鲒暮晶堍敖拚梳阻指纹效应或气体穿透现象是GAIM工艺过程中常碰到的问题。在有指纹现象时，气体从气体流道中流出，侵入到塑件中没有设计流道的部分。严重的指纹效应将导致塑件坚硬处和有强烈冲击处发生明显的变形，也会影响塑件的使用性能。在气体保压过程中，在有气流通道和没有的过渡处，将可能在没有气流通道处发

59、生指纹效应。在这种情况下，主要影响指纹效应的因素是塑件没有气流通道处的壁厚。壁厚越厚，指纹收缩现象就越有可能，指纹效应的危害就越大。为了通过设计来减少指纹效应，就需要遵循下列原则：在没有气流通道处必须避免大于等于4mm的基本壁厚，需要选择易于凝固的材料，应用尽可能低的气体压力。绠萄檠挪晤伪陆轴醇勤纷恂啄帆气泡是由指纹效应引起的。当发生指纹效应时，气体将在塑件的薄壁处被困住，此处的气体将不能被完全排出。这些留在塑件中的气体就引起气泡现象，在模具开启后，这些气泡将一直留在塑件中。癞毫荆忿目瘕擅焚矸青自垅荜鹰 欠料注射的树脂在型腔中先停顿一下，再重新开始流动直到完成注满型腔，在此过程中塑件表面就会出现迟滞线。晦豢著谅虑穆瘭普窥氮蔸铀孀硎在塑件的外表面或气体通道内可能会发生树脂的热分解。塑件表面的热分解是由注射气体的压力太高，或模