⑶ 1957 & Λ發明說明: 【發明所屬之技術領域】 本發明涉及模具定位技術領域,尤其涉及一種模具裝 置。 【先前技術】 使用模具裝置裝^成型件時,成型件之加工精度主要 文模具裝置之製造及裝配精度影響,故,提高模具裝置的 製造及裝配精度玎使藉由該模具裝置製造之成型件(産品) 具'有較高之加工精度。 模具裝置通常包括一相對之第一分模及第二分模,第 分模及第二分模中又分別包括一模座,以及一具模壓面 之模仁,模仁中還可以根據需要設定一個或複數個具模壓 面之嵌入件。另,當模仁用於成型較小尺寸之成型件時, 所述模座中可以設置一模塊,所述模塊中開設複數模穴, 每一模穴中均置入一所述具模壓面之模仁,如此於一次成 型過程中便可以成型多個成型件。裝配時,所述模仁可藉 由楔形塊、定位銷等定位元件固定於所述模座或所述模塊 開設之模穴中。所述第一分模與第二分模合模時,兩相對 之所述模座藉由導柱、導套等導向定位元件對準定位兩 相對之模仁之間形成一模腔,即可注料成型。成型後,將 第一分模與第二分模分離,即可取走成型件。 然’所述模座或所述模塊開設之模穴加工精度可能不 足,如此將造成兩相對之模仁對位偏移,且模具裴置於使 用一段時間後’模仁定位用之楔形塊、定位麟等定位元件 6 1331957 可月b出現局部磨損,如此亦將造成裝配之兩模仁對位誤差 情況發生’其成型之成型件,尤其-賴密元#,加工精 度將無法保障,成型件甚至可能成為廢品。 必要 有鑑於此,提供一種具較佳對位精度之模具裝 置實為 【發明内容】 以下,將以實施例說明一種模具裝置。 • 一種模具裝置,其包括:兩相對設置之模座,以及分 別设置於所述模座中且具模壓面之模仁,其中,至少一所 述模仁藉由-調節裝置設置於所述模座中, ^ 包:-承载該模仁之滑塊,一穿設所述滑塊並螺合= tli—第—鮮部件,以及—穿設該模座朗合於所述 α塊中之-第二調節部件,所述第—調節 調節部件相互垂直。 一弟一 一種模具裝置,其包括:兩相對設置之模座,兩分別 φ 設置在所述模座中之模塊,以及兩分別設置於所述兩模 中且具模壓面之模仁,其中,至少一所述模仁藉由一調節 裝置設置於所述模塊中,所述調節裝置包括一承載該模仁 之滑塊,一穿設所述滑塊並螺合於該模仁中之第一二節部 件,以及一穿設該模座及模塊並螺合於所述滑塊中之第一 調節部件,所述第一調節部件與所述第二調節部件相互垂 直0 與先前技術相比,所述模具裝置之兩相對模仁中,至 少一模仁裝配有一調節裝置。驅動所述第一調節部件,所 將沿該調節部件之長度方向移動 ,驅動所述第二調 部件之县所述π塊帶動其承載之所述模仁將一 起沿該調節 π X方向移動,所述第一調節部件與所述第二調節 ;==、兄如:便可以線上及時調節兩相⑽^ 【實施方式】 成型件之加工精度。 說明對本發明提供之模具|置作進—步詳細 °月並參閱圖1至圖4,本發明之第一實施例提供之模 >、裝置1 ’其包括一第一分模1〇、一與所述第一分模1〇相對 設置之第二分模2〇。 所述第一分模10包括一模座11、一模仁12及一調節裝 置30,所述調節裝置3〇包括一滑塊31、一第一調節螺杆32 及一第一調節螺杆33。所述第二分模2〇包括一模座21及一 模仁22。 所述模座11中開設有一模穴11〇,所述滑塊31設置於該 模穴110中,所述滑塊31開設有一槽穴31〇,所述模仁12設 置於該槽穴310中。所述模座11之侧壁lla及頂壁llb上分別 開設有一溝槽112及通孔113,以分別供所述第一調節螺杆 32及第二調節螺杆33自該模座11外伸入模穴11〇中,所述溝 槽112、通孔113開設之方向相互垂直。所述滑塊31於其對 應於溝槽1丨2位置上開設有通孔311,於其對應於通孔113 位置上開設有螺紋孔312 ’所述模仁12於其對應於通孔311 位置上開設有螺紋孔121,所述第一調節螺杆3 2穿設於所述 滑塊31開設之通孔311及所述模仁12開設之螺紋孔121中, 所述第二調節螺杆33穿設於所述滑塊31開設之螺紋孔312 甲,且進一步穿設至模穴110内壁面上,所述第一調節螺杆 32及第一調節螺杆犯之螺杆軸上分別具有與螺紋孔121及 312配合之螺紋。所述溝槽112沿平行於所述第二調節螺杆 =之螺杆軸向方向之高度尺寸H,大於沿垂直於所述第二調 節螺杆33之螺杆軸向方向之寬度尺寸L,所述溝槽112之寬 度尺寸L可以與所述第一調節螺杆32之螺杆軸徑向尺寸匹 配。 _所述第一調節螺杆32及第二調節螺杆33靠近其螺杆軸 頭D卩位置上分別開設有一徑向凹槽32a,33a,所述模座Η 上。又置有兩個分別向所述溝槽Π2内及通孔113内穿設之螺 釘114a,115a’當調節螺杆32及第二調節螺杆33分別插入溝 槽112及軌113時’所述螺釘U4a,U5a可分別卡持於凹槽 32\33a中’從而可以限制第一調節螺杆犯及第二調節螺; 鲁 33沿其自身之螺杆軸向位移。優選地,所述螺釘⑽穿設 之方向與所述第二調節螺杆33之螺杆轴向垂直,從而不声 響第-調節螺杆32與滑塊31及模紅12於第二調節螺杆犯作 用下一起沿第二調節螺杆33之螺杆軸向位移。 當然,其他適合用於限制所述第一調節螺杆32及第二 -調節螺杆33沿其自身螺杆軸向位移之卡持部件,例如定: 鎖、可伸縮之軸杆等,亦均於本發明可採用之列,該 部件僅須與所述第-調節螺杆32及第二調節螺杆犯之 軸上開設之凹槽32a、33a配合即可。 9 1331957 另外可以理解的是’上述模座11開設之溝槽Η 2亦可直 接為一圓形孔,所述溝槽112僅須使得其平行於所述第二調 • ·節螺杆33之螺杆轴向方向之高度尺寸η大於所述第一調節 ·-螺杆32之徑向尺寸即可。 所述模座21設置有一模穴210,所述模仁22可藉由楔形 塊等定位元件固定於所述模穴210中。 所述第一調節螺杆32及第二調節螺杆33可以分別連接 φ 一驅動裝置(圖未示),所述兩驅動裝置可以分別控制所述 第一調節螵杆32及第二調節螺杆33之轉動量,而藉由設置 於該第〜調節螺杆32及第二調節螺杆33之螺杆轴上之螺 紋’所述兩驅動裝置便可以分別控制與所述第一調節螺杆 32螺合之模仁12,以及與第二調節螺杆33螺合之滑塊31之 移動量。 所述模座11具有一表面11c ’所述模座21具有一表面 21a ’該表面11c與2ia相面對設置。所述模座11之表面11c • 延伸出四個導柱111 ;所述模座21之表面21a向内開設有與 所述導杈111配合之導套211,所述第一分模10與第二分模 2〇合模時,導柱lu可插入所述導套211中,引導第一分模 10與第二分模20對準定位。 所述模仁12,22分別具有一模壓面120,220,所述第一 刀模10與第二分模合模時,所述模仁12, 22之間可以形成 一模腔。另,所述模仁12中可以設置一流道系統以注料成 里所迷模仁22中可以設置一頂出裝置以頂出成型件,所 述模仁12, 22之分模面邊緣玎以設置相配合之導向定位用 1331957 之定位凸台及定位孔等。 +所曰述第一分模10與第二分模20合模製造出成型件後, 藉由量測成型件之同心度,便可知道模仁12, 22之模壓面 120’220之對位狀況。當所述模仁12,22對位存在偏移時, 利用所述第—調節螺杆32配合之驅動裝置轉動第—調節螺 杆32,所述模仁12於所述第一調節螺杆32之螺紋作用下便 將向左或向右移動。利用所述第二調節螺杆33配合之驅動 裝置轉動第二調節螺杆33,所述滑塊31於所述第二調節螺 杆33之螺紋作用下帶動其内置之模仁12向上或向下移動:、 如此所述模仁12與模仁22之模壓面12〇,22〇之對位 以得到調節。 / 凡可 可以理解的是,所述第一分模1〇及第二分模2〇 笼疋位凸台、定位孔等多個導向定位用之定位元 件述模仁12與模仁22偏移量係微小的,故,利用所= 兩調節螺杆32’ 33調節模仁12之調節量亦為微小,亦即模介 ==二=穴3Γ以及滑塊31於所述模;(3) 1957 & ΛInvention Description: TECHNICAL FIELD The present invention relates to the field of mold positioning technology, and more particularly to a mold apparatus. [Prior Art] When using a mold device to mount a molded part, the processing accuracy of the molded part is mainly influenced by the manufacturing and assembly precision of the mold device, so that the manufacturing and assembly precision of the mold device is improved, and the molded part manufactured by the mold device is improved. (Product) With 'higher processing accuracy. The mold device generally includes a first split mold and a second split mold, and the first split mold and the second split mold respectively include a mold base, and a mold having a molded surface, and the mold core can also be set as needed. One or a plurality of inserts with molded surfaces. In addition, when the mold core is used to form a molded part of a smaller size, a module may be disposed in the mold base, and a plurality of mold cavities are formed in the mold, and each of the mold cavities is provided with the mold surface. The mold core can be molded into a plurality of molded parts in one molding process. When assembled, the mold core may be fixed to the mold base or the mold cavity formed by the module by a positioning member such as a wedge block or a positioning pin. When the first partial mold and the second partial mold are closed, the opposite mold holders are aligned with the guide members by guiding pillars, guide sleeves and the like to form a cavity between the two opposite mold cores. Material molding. After molding, the first parting mold is separated from the second parting mold, and the molded part can be removed. However, the precision of the cavity formed by the mold base or the module may be insufficient, which will cause the alignment of the two opposite molds to be offset, and the mold is placed on the wedge for the positioning of the mold after a period of use. Positioning Lin and other positioning components 6 1331957 can cause local wear on the monthly b, which will also cause the alignment error of the two molds assembled. 'The molded parts, especially Lai Miyuan #, the processing precision will not be guaranteed, the molded parts It may even become a waste product. In view of the above, there is provided a mold apparatus having a better alignment accuracy. [Explanation] Hereinafter, a mold apparatus will be described by way of examples. A mold apparatus comprising: two oppositely disposed mold bases, and mold cores respectively disposed in the mold base and having a molding surface, wherein at least one of the mold cores is disposed on the mold by an adjusting device In the seat, ^ bag: - the slider carrying the mold, one piercing the slider and screwing = tli - the first fresh component, and - the piercing of the die seat in the alpha block - the first Two adjustment members, the first adjustment adjustment members being perpendicular to each other. a mold device comprising: two oppositely disposed mold bases, two modules respectively disposed in the mold base, and two mold cores respectively disposed in the two molds and having a molded surface, wherein At least one of the mold cores is disposed in the module by an adjusting device, the adjusting device includes a slider carrying the mold, a first threaded through the slider and screwed into the mold core a two-section component, and a first adjustment component threaded through the die holder and the module and screwed into the slider, the first adjustment component and the second adjustment component being perpendicular to each other 0 compared with the prior art At least one of the two opposite mold cores of the mold device is equipped with an adjustment device. Driving the first adjusting member to move along the length direction of the adjusting member, and driving the π block of the county of the second adjusting member to drive the mold cores carried by the second modulating member to move together in the adjusting π X direction, The first adjusting component and the second adjusting; ==, brother: can adjust the two phases in time (10) ^ [Embodiment] The processing precision of the molded part. The mold provided by the present invention is described in detail with reference to FIGS. 1 to 4, and the first embodiment of the present invention provides a mold, which includes a first partial mold, one a second partial mold 2〇 disposed opposite to the first partial mold 1〇. The first parting mold 10 includes a mold base 11, a mold core 12 and an adjusting device 30. The adjusting device 3 includes a slider 31, a first adjusting screw 32 and a first adjusting screw 33. The second partial mold 2 includes a mold base 21 and a mold core 22. A cavity 11 is defined in the die holder 11 , and the slider 31 is disposed in the cavity 110 . The slider 31 defines a slot 31 , and the die 12 is disposed in the cavity 310 . . A groove 112 and a through hole 113 are defined in the sidewall 11a and the top wall 11b of the die holder 11 for respectively extending the first adjusting screw 32 and the second adjusting screw 33 from the die holder 11 into the die. In the hole 11 , the grooves 112 and the through holes 113 are perpendicular to each other. The slider 31 is provided with a through hole 311 at a position corresponding to the groove 1丨2, and a screw hole 312 ′ is formed at a position corresponding to the through hole 113. The mold core 12 is corresponding to the position of the through hole 311. The first adjusting screw 32 is disposed in the through hole 311 of the slider 31 and the threaded hole 121 formed in the mold core 12, and the second adjusting screw 33 is disposed through the threaded hole 121. The threaded hole 312A of the slider 31 is further disposed on the inner wall surface of the cavity 110, and the first adjusting screw 32 and the first adjusting screw have screw holes 121 and 312 respectively. Fit the thread. The groove 112 has a height dimension H parallel to the axial direction of the screw of the second adjusting screw=, and is larger than a width L of the screw axial direction perpendicular to the second adjusting screw 33, the groove The width dimension L of 112 can be matched to the radial dimension of the screw shaft of the first adjustment screw 32. The first adjusting screw 32 and the second adjusting screw 33 are respectively provided with radial grooves 32a, 33a adjacent to the screw shaft head D, respectively, on the mold base. Further, two screws 114a, 115a' respectively inserted into the groove Π2 and the through hole 113 are respectively disposed. When the adjusting screw 32 and the second adjusting screw 33 are respectively inserted into the groove 112 and the rail 113, the screw U4a is inserted. The U5a can be respectively held in the groove 32\33a' so that the first adjusting screw can be restrained from the second adjusting screw; the Lu 33 is axially displaced along its own screw. Preferably, the direction in which the screw (10) is worn is perpendicular to the screw axial direction of the second adjusting screw 33, so that the first adjusting screw 32 and the slider 31 and the red mold 12 are not acted upon by the second adjusting screw. Together, they are axially displaced along the screw of the second adjustment screw 33. Of course, other holding members suitable for limiting the axial displacement of the first adjusting screw 32 and the second adjusting screw 33 along their own screws, such as a lock, a retractable shaft, etc., are also in the present invention. Alternatively, the member only needs to be engaged with the grooves 32a, 33a formed on the shaft by the first adjusting screw 32 and the second adjusting screw. 9 1331957 It can also be understood that the groove Η 2 formed by the above mold base 11 can also be directly a circular hole, and the groove 112 only needs to be parallel to the screw of the second adjustment screw 33. The height dimension η of the axial direction may be larger than the radial dimension of the first adjustment screw 32. The mold base 21 is provided with a cavity 210, and the mold core 22 can be fixed in the cavity 210 by a positioning member such as a wedge block. The first adjusting screw 32 and the second adjusting screw 33 may be respectively connected to a driving device (not shown), and the two driving devices may respectively control the rotation of the first adjusting mast 32 and the second adjusting screw 33. And the two driving devices disposed on the screw shafts of the first adjusting screw 32 and the second adjusting screw 33 can respectively control the mold core 12 screwed with the first adjusting screw 32, And the amount of movement of the slider 31 screwed to the second adjustment screw 33. The die holder 11 has a surface 11c' which has a surface 21a' which faces the face 2ia. The surface 11c of the die holder 11 extends out of the four guide posts 111; the surface 21a of the die holder 21 is internally provided with a guide sleeve 211 that cooperates with the guide bush 111, and the first split die 10 and the first die When the split mold 2 is closed, the guide post lu can be inserted into the guide sleeve 211 to guide the first split mold 10 and the second split mold 20 to be aligned. The mold cores 12, 22 respectively have a molding surface 120, 220. When the first die 10 is closed with the second partial mold, a cavity can be formed between the mold cores 12, 22. In addition, the mold core 12 can be provided with a first-class road system for injecting the mold. The mold core 22 can be provided with an ejection device for ejecting the molding member, and the mold edge of the mold core 12, 22 is Set the positioning boss and positioning hole of the 1331957 for the coordinated positioning. + After the first split mold 10 and the second split mold 20 are molded to form a molded part, by measuring the concentricity of the molded part, the alignment of the molded surface 120'220 of the mold core 12, 22 can be known. situation. When the alignment of the mold cores 12, 22 is offset, the driving mechanism of the first adjusting screw 32 is rotated to rotate the first adjusting screw 32, and the mold core 12 acts on the thread of the first adjusting screw 32. It will move to the left or right. The second adjusting screw 33 is rotated by the driving device of the second adjusting screw 33, and the slider 31 drives the built-in mold core 12 to move up or down under the action of the thread of the second adjusting screw 33: Thus, the mold core 12 is aligned with the molding faces 12, 22 of the mold core 22 to be adjusted. / It can be understood that the first partial mold 1 〇 and the second partial mold 2 〇 cage truss boss, positioning hole and the like are used for locating components for guiding positioning, and the mold core 12 and the mold core 22 are offset. The amount is small, so the adjustment amount of the mold core 12 is also small by using the two adjustment screws 32' 33, that is, the mode is == two = hole 3Γ and the slider 31 is in the mold;
<模八110中所需之移動空間係微小的,不會 道毛邊之問題。 巧"IL 本實%例提供之模具裝置之兩相對模仁中,至少一 仁上裝配有一調節裝置。轉動所述第一調節螺杆,、 =將=調節螺杆之螺杆料向移動,轉動所述第二調節螺 :螺=塊帶動其承載之所梅將一起沿該調節螺: ==移動,所述第—調節螺杆與所述第二 螺_向相互垂直’如此便可以線上及時調節兩相對之 模仁=模壓面對位狀況,提高成型件之加工精度。 . 4參閱圖5 ’為本發明之第二實施例提供之模具裝置2 局部剖面立體示意圖,所述模具裝置2包括-第-分模1〇、 • ·· 一與所述第一分模10相對設置之第二分模2(^ 所述第一實施例與所述第一實施例之區別在於:所述 第一,節螺杆32完全位於模座n開設之模穴11()内,所述第 一調節螺杆32直接配合於所述滑塊31及模仁12上,而溝槽 鲁112之作,便在於驅動裝置可以自模座⑴卜伸人而驅動該 第一調節螺杆32,此時,上述用於限制該第一調節螺杆32 沿其自身螺杆軸向位移之螺釘114&便設置於所述滑塊31 上。 另,請參閱圖6,為本發明之第三實施例提供之模具裝 置3立體示意圖,所述模具裝置3與所述模具裝置丨之區別在 於:所述模仁12上裝配有兩滑座34a,34b,所述兩滑座 34a,34b與所述模仁12固定配合,所述滑塊31之槽穴31〇内 • 壁可以開設兩個與所述兩滑座34a,34b配合之滑槽,如此利 用兩滑座34a,34b帶動模仁12於所述第一調節螺杆32作用 下向左或向右移動,可以避免模仁12磨損’且可以提高移 動之精度。所述兩滑座34a,34b可以設置於所述模仁12側 面,亦可以設置於所述模仁12底部。本實施例中,所述兩 滑座34a, 34b設置於所述模仁12側面’所述第一調節螺杆32 自所述模座11開設之溝槽112外穿入,穿設所述滑塊31,並 螺合所述滑座34a,34b及其中之模仁12。 當然,上述模仁12亦可爲僅裝配一滑座34a之形式。 1331957 另’所述模座丨1之模穴lio内璧上亦可以開設兩個便於 所述滑塊31滑動之滑槽,如此提高滑塊31移動之精度。 請參閱圖7 ’為本發明之第四實施例提供之模具裝置4 立體示意圖。所述模具裝置2包括一第一分模1〇、一與所述 第一分模10相對設置之第二分模20。 所述第四實施例提供之模具裝置4與所述第一實施例 提供之模具裝置1之區別在於:所述第一分模1〇包括一模座 11、一設置於所述模座11中之模塊12a以及複數模仁i2b。 所述模塊12a可以藉由楔形塊等定位元件固定於模座11 中’所述模塊12a中開設有複數個模穴12c,每一模仁12b 藉由一調節裝置30a設置於一所述模穴12c中。當然,所述 第二分模20亦包括與所述第一分模10配合之模座、模塊以 及複數模仁(圖未示),所述第二分模20之模塊可以藉由楔 形塊等定位元件固定於該模座中,複數模仁可以藉由定位 銷等定位元件固定於該模塊中。如此所述模具裝置2—次便 可以成型複數個成型件。 所述調節裝置30a可以採用前述實施例提供之調節裝 置之結構。所述模座11及模塊12a均開設有一溝槽112a,所 述第一調節螺杆32自所述兩溝槽112a外穿入,並穿設所述 滑塊31且與該滑塊31中之所述模仁12b螺合。所述第二調節 螺杆33自所述模座11及所述模塊12a外穿入,螺合於所述滑 塊31中,且進一步穿設至模塊12a開設之模穴12c内壁面上。 綜上所述,本發明符合發明專利要件,爰依法提出專 利申請。惟,以上所述者僅為本發明之較佳實施方式,本 13 1331957 發明之範®並不以上述實施方式為限,舉凡熟習本案技藝 之人士援依本發明之精神所作之等效修飾或變化,皆應涵 ·-蓋於以下申請專利範圍内。 一 ·-【圖式簡單說明】 圖1係本發明之第一實施例提供之模具裝置之分解立 體示意圖。 圖2係圖1提供之模具裝置裝配後之立體示意圖。 圖3係圖2提供之第一分模沿ΙΠ_ΠΙ線之剖面示意圖。 圖4係圖2提供之第一分模沿IV_IV線之剖面示意圖。 圖5係本發明之第二實施例提供之模具裝置之局部剖 面立體示意圖。 圖6係本發明之第三實施例提供之模具裝置立體示意 圖。 圖7係本發明之第四實施例提供之模具裝置立體示意 圖。 【主要元件符號說明】 模具裝置 1,2,3,4 第一分模 10 第二分模 20 調節裝置 30, 30a 模座 11,21 模仁 12,22, 12b 模穴 11 0,2 1 0,1 2 C 側壁 11a 頂壁 lib 表面 11c,21a 導柱 111 導套 211 溝槽 112, 112a 通孔 113,311 螺釘 114a, 115a 模壓面 120,220 1331957 滑塊 31 槽六 310 螺紋孔 121,312 模塊 12a 調節螺杆 32,33 凹槽 32a,33a 滑座 34a,34b<The moving space required in the model eight 110 is small, and there is no problem with the burrs. In the two opposite mold cores of the mold device provided by the embodiment of the present invention, at least one of the cores is equipped with an adjusting device. Rotating the first adjusting screw, == moving the screw of the adjusting screw to move, rotating the second adjusting screw: the screw = block drives the load bearing the plum along the adjusting screw: == moving, The first adjusting screw and the second screw _ are perpendicular to each other. Thus, the two opposing mold cores can be adjusted on the line in time to improve the processing precision of the molded part. 4 is a partial cross-sectional perspective view of a mold apparatus 2 according to a second embodiment of the present invention, the mold apparatus 2 including a --partition mold 1 and a first split mold 10 The second partial mold 2 is oppositely disposed (the first embodiment is different from the first embodiment in that: the first, the pitch screw 32 is completely located in the cavity 11 () in which the mold base n is opened. The first adjusting screw 32 is directly fitted to the slider 31 and the mold core 12, and the groove ruin 112 is used to drive the first adjusting screw 32 from the mold base (1). The screw 114& for limiting the axial displacement of the first adjusting screw 32 along its own screw is disposed on the slider 31. In addition, please refer to FIG. 6, which is provided for the third embodiment of the present invention. A schematic view of the mold device 3, the mold device 3 is different from the mold device, in that the mold core 12 is equipped with two sliding seats 34a, 34b, the two sliding seats 34a, 34b and the mold core 12 With a fixed fit, the slot 31 of the slider 31 can be opened and the two slides 34a, 34 can be opened. With the two sliding seats 34a, 34b, the mold core 12 is moved to the left or right by the first adjusting screw 32, so that the mold core 12 can be prevented from being worn out and the precision of the movement can be improved. The two sliding seats 34a, 34b may be disposed on the side of the mold core 12, or may be disposed on the bottom of the mold core 12. In the embodiment, the two sliding seats 34a, 34b are disposed on the side of the mold core 12' The first adjusting screw 32 penetrates from the groove 112 opened by the die holder 11, passes through the slider 31, and screws the sliders 34a, 34b and the die 12 therein. The mold core 12 can also be in the form of only one sliding seat 34a. 1331957 Another 'the inner cavity of the mold base 丨1 can also be provided with two sliding grooves for sliding the slider 31, thus improving the sliding. The precision of the movement of the block 31. Please refer to FIG. 7 ' is a perspective view of a mold device 4 according to a fourth embodiment of the present invention. The mold device 2 includes a first partial die 1 and a first partial die 10 a second partial mold 20 disposed oppositely. The mold device 4 provided by the fourth embodiment and the first embodiment The difference between the mold device 1 is that the first partial mold 1 includes a mold base 11, a module 12a disposed in the mold base 11, and a plurality of mold cores i2b. The module 12a can be formed by a wedge block The positioning member is fixed in the die holder 11. The module 12a is provided with a plurality of cavity 12c, and each of the die 12b is disposed in a cavity 12c by an adjusting device 30a. Of course, the second The split mold 20 also includes a mold base, a module and a plurality of mold cores (not shown) that are coupled to the first split mold 10, and the module of the second split mold 20 can be fixed to the mold by a positioning member such as a wedge block. In the seat, the plurality of mold cores can be fixed in the module by positioning members such as positioning pins. The mold device 2 as described above can form a plurality of molded parts. The adjusting device 30a can adopt the structure of the adjusting device provided by the foregoing embodiment. Each of the die holder 11 and the module 12a defines a groove 112a. The first adjusting screw 32 penetrates from the two grooves 112a and penetrates the slider 31 and the slider 31. The mold core 12b is screwed. The second adjusting screw 33 penetrates from the die holder 11 and the module 12a, is screwed into the slider 31, and is further disposed to the inner wall surface of the cavity 12c opened by the module 12a. In summary, the present invention complies with the requirements of the invention patent and submits a patent application according to law. However, the above description is only a preferred embodiment of the present invention, and the present invention is not limited to the above-described embodiments, and those skilled in the art will be able to modify the equivalent modifications according to the spirit of the present invention. The changes are all covered by the following patents. BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is an exploded perspective view of a mold apparatus according to a first embodiment of the present invention. 2 is a perspective view of the mold device provided in FIG. 1 after assembly. 3 is a schematic cross-sectional view of the first partial mold provided along FIG. 2 along the ΙΠ_ΠΙ line. 4 is a schematic cross-sectional view of the first partial mold provided along FIG. 2 taken along line IV_IV. Fig. 5 is a partially cutaway perspective view showing a mold apparatus according to a second embodiment of the present invention. Fig. 6 is a perspective view showing a mold apparatus according to a third embodiment of the present invention. Fig. 7 is a perspective view showing a mold apparatus according to a fourth embodiment of the present invention. [Description of main component symbols] Mold device 1, 2, 3, 4 First parting die 10 Second parting die 20 Adjusting device 30, 30a Mold base 11, 21 Mold core 12, 22, 12b Mold hole 11 0, 2 1 0 , 1 2 C side wall 11a top wall lib surface 11c, 21a guide post 111 guide sleeve 211 groove 112, 112a through hole 113, 311 screw 114a, 115a molded surface 120, 220 1331957 slider 31 slot six 310 threaded hole 121, 312 module 12a adjustment screw 32, 33 grooves 32a, 33a slides 34a, 34b
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