TW201615337A - Grinding method for screw - Google Patents

Grinding method for screw Download PDF

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TW201615337A
TW201615337A TW103136516A TW103136516A TW201615337A TW 201615337 A TW201615337 A TW 201615337A TW 103136516 A TW103136516 A TW 103136516A TW 103136516 A TW103136516 A TW 103136516A TW 201615337 A TW201615337 A TW 201615337A
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grinding
screw
spiral groove
portions
amount
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TW103136516A
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TWI581901B (en
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李進勝
楊進財
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全球傳動科技股份有限公司
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Abstract

A grinding method for screw is used for forming a screw having a spiral groove from a blank having a spiral pre-groove. The method includes the steps of providing a grinder having a plurality of grinding parts, abutting against a plurality of curves of the spiral pre-groove by the grinding parts of the grinder, and grinding the curves by the grinding parts at the same time to form the screw having the spiral groove.

Description

螺桿的研磨方法 Screw grinding method

本發明係關於一種螺桿的研磨方法。 The present invention relates to a method of grinding a screw.

滾珠螺桿為一種廣泛應用在許多機械設備中的裝置,其設置的目的在於提供精密的傳動功能,藉由機械操作中的旋轉運動與直線運動,進而使承載的機台或物件於直線方向上進行作動。 The ball screw is a device widely used in many mechanical devices. The purpose of the ball screw is to provide a precise transmission function. In the mechanical operation, the rotary motion and the linear motion are used to carry the loaded machine or object in a straight line. Actuate.

目前所應用的滾珠螺桿的基本元件包括螺桿、螺帽以及多個滾珠。螺桿表面具有螺旋式溝槽,螺帽的內表面亦具有螺旋式內溝槽,能與螺桿間形成滾珠通道,使滾珠容置於其中,並與螺桿、螺帽形成相對滾動的關係,以降低螺桿與螺帽之間相對轉動的摩擦力。 The basic components of the currently used ball screw include a screw, a nut, and a plurality of balls. The surface of the screw has a spiral groove, and the inner surface of the nut also has a spiral inner groove, which can form a ball passage with the screw, so that the ball is accommodated therein, and forms a relative rolling relationship with the screw and the nut to reduce the relationship. The frictional force between the screw and the nut.

精度較高的螺桿其製程手續繁雜,以研磨製程來說,通常會於螺旋式溝槽進行多次的研磨來提高螺桿的精度。然而,反覆的研磨步驟將使得製程的時間增加。更嚴重的是,當研磨時間增加,也會增加成型砂輪機的磨耗,使得成型砂輪機的使用壽命快速減低。 The precision of the screw has a complicated manufacturing process. In the case of the grinding process, the spiral groove is usually ground several times to improve the precision of the screw. However, the repeated grinding step will increase the time of the process. More seriously, as the grinding time increases, the wear of the forming grinder is also increased, so that the service life of the forming grinder is rapidly reduced.

因此,如何提供一種螺桿的研磨方法,其能減少螺桿的研磨時間又能同時降低成型砂輪機的磨耗,已成為重要課題之一。 Therefore, how to provide a grinding method for a screw, which can reduce the grinding time of the screw and simultaneously reduce the wear of the forming grinder, has become one of the important topics.

有鑑於上述課題,本發明的目的為提供一種能減少螺桿研磨時間又能同時降低成型砂輪機的磨耗的螺桿的研磨方法。 In view of the above problems, an object of the present invention is to provide a grinding method for a screw which can reduce the screw grinding time and simultaneously reduce the wear of the molding grinder.

為達上述目的,依據本發明的一種螺桿的研磨方法,用以將具有一預成型螺旋溝槽的一胚料製成具有一螺旋式溝槽的一螺桿,螺桿的研磨方法包括以下步驟:提供一具有多個磨製部的成型砂輪機;將成型砂輪機的該些磨製部抵靠預成型螺旋溝槽的多個弧面;以及藉由該些磨製部同時研磨該些弧面以形成具有螺旋式溝槽的螺桿。 In order to achieve the above object, a grinding method for a screw according to the present invention is for forming a blank having a preformed spiral groove into a screw having a spiral groove, and the grinding method of the screw includes the following steps: a molding grinder having a plurality of grinding portions; abutting the grinding portions of the forming grinder against a plurality of curved surfaces of the preformed spiral groove; and simultaneously grinding the curved surfaces by the grinding portions A screw having a spiral groove is formed.

在一實施例中,磨製部的數量為2至4個。 In an embodiment, the number of the portions is 2 to 4.

在一實施例中,於研磨步驟中,該些磨製部與該些弧面的干涉量為不相同。 In an embodiment, in the grinding step, the amount of interference between the grinding portions and the curved surfaces is different.

在一實施例中,各磨製部沿胚料的一移動方向上與各弧面的干涉量為遞減。 In one embodiment, the amount of interference of each of the grinding portions with each of the curved surfaces in a moving direction of the blank is decreasing.

在一實施例中,位於成型砂輪機沿移動方向上的末端的磨製部的干涉量可為零。 In an embodiment, the amount of interference of the grinding portion located at the end of the forming grinder in the moving direction may be zero.

在一實施例中,末端磨製部以外的該些磨製部與該些弧面的干涉量可介於0.01mm至0.1mm。 In an embodiment, the amount of interference between the grinding portions other than the end-grinding portion and the curved surfaces may be between 0.01 mm and 0.1 mm.

在一實施例中,螺桿的螺距可介於0.5mm至3mm。 In an embodiment, the pitch of the screw may be between 0.5 mm and 3 mm.

在一實施例中,螺桿的螺距可為1mm。 In an embodiment, the pitch of the screw can be 1 mm.

在一實施例中,該些弧面的角度可由預成型螺旋溝槽的底部向預成型螺旋溝槽的外徑方向延伸之45±25度。 In one embodiment, the angles of the arcuate surfaces may extend from the bottom of the preformed spiral groove to 45 ± 25 degrees toward the outer diameter of the preformed spiral groove.

在一實施例中,研磨方法可應用於滾珠螺桿。 In an embodiment, the grinding method can be applied to a ball screw.

綜上所述,本發明的螺桿的研磨方法,藉由同時研磨胚料的預成型螺旋溝槽的多個弧面,可減少螺桿的研磨時間,加速螺桿的製程,並且可降低成型砂輪機的磨耗。 In summary, the grinding method of the screw of the present invention can reduce the grinding time of the screw, accelerate the processing of the screw, and reduce the grinding process of the forming grinder by simultaneously grinding a plurality of curved surfaces of the preformed spiral groove of the billet. Wear.

1‧‧‧螺桿 1‧‧‧ screw

11‧‧‧螺旋狀溝槽 11‧‧‧Spiral groove

111‧‧‧溝槽弧面 111‧‧‧ Groove curved surface

2‧‧‧胚料 2‧‧‧Bullet

21‧‧‧預成型螺旋溝槽 21‧‧‧Preformed spiral groove

211‧‧‧弧面 211‧‧‧ curved surface

211a‧‧‧部分弧面 211a‧‧‧Partial curved surface

212‧‧‧底部 212‧‧‧ bottom

213‧‧‧外徑 213‧‧‧ outside diameter

3‧‧‧成型砂輪機 3‧‧‧Molding grinder

31、31a、31b、31c‧‧‧磨製部 31, 31a, 31b, 31c‧‧‧ grinding department

A‧‧‧方向 A‧‧‧ direction

B‧‧‧滾珠 B‧‧‧Balls

B1‧‧‧曲率中心 B1‧‧‧ Curvature Center

C‧‧‧頂心 C‧‧‧Top

R‧‧‧區域 R‧‧‧ area

S01、S02、S03‧‧‧步驟 S01, S02, S03‧‧‧ steps

W1‧‧‧凸起 W1‧‧‧ bump

X‧‧‧長軸方向 X‧‧‧ long axis direction

Y‧‧‧短軸方向 Y‧‧‧Short axis direction

θ‧‧‧角度 Θ‧‧‧ angle

圖1為本發明較佳實施例的螺桿的研磨方法的步驟流程圖。 BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a flow chart showing the steps of a method of grinding a screw according to a preferred embodiment of the present invention.

圖2A為圖1所示的步驟加工的示意圖。 2A is a schematic view of the processing of the steps shown in FIG. 1.

圖2B為圖2A區域R的磨製部與弧面的部分放大圖。 Fig. 2B is a partial enlarged view of the worn portion and the curved surface of the region R of Fig. 2A.

圖3為圖1所示的步驟加工完成所得的螺桿的外觀示意圖。 Fig. 3 is a schematic view showing the appearance of the screw obtained by the process shown in Fig. 1.

圖4為步驟S03的操作示意圖。 FIG. 4 is a schematic diagram of the operation of step S03.

圖5為螺桿與滾珠的搭配示意圖。 Figure 5 is a schematic diagram of the matching of the screw and the ball.

以下將參照相關圖式,說明依本發明較佳實施例的一種螺桿的研磨方法,其中相同的元件將以相同的參照符號加以說明。 DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a method of grinding a screw according to a preferred embodiment of the present invention will be described with reference to the accompanying drawings, wherein the same elements will be described with the same reference numerals.

圖1為依據本發明較佳實施例的螺桿的研磨方法的步驟流程圖,圖2A為圖1所示的步驟加工的示意圖,而圖3為圖1所示的步驟加工完成所得的螺桿的外觀示意圖。請同時參照圖1、圖2A及圖3所示,本實施例的螺桿1係應用於滾珠螺桿(Ball Screw),較佳是應用於小螺距的滾珠螺桿,例如螺距為0.5mm至1.5mm,其中本實施例是以螺距為1mm為例,但本發明不限於此。 1 is a flow chart showing the steps of a grinding method of a screw according to a preferred embodiment of the present invention, FIG. 2A is a schematic view of the step processing shown in FIG. 1, and FIG. 3 is an appearance of the screw obtained by the step shown in FIG. schematic diagram. Referring to FIG. 1 , FIG. 2A and FIG. 3 simultaneously, the screw 1 of the present embodiment is applied to a ball screw, preferably to a small pitch ball screw, for example, a pitch of 0.5 mm to 1.5 mm. The present embodiment is exemplified by a pitch of 1 mm, but the present invention is not limited thereto.

螺桿1為一圓柱狀桿體,且其外表面具有一沿縱軸連續纏繞的螺旋狀溝槽11。於此,螺桿1是由一胚料2製作而成,而胚料2可為金屬塊狀或柱狀材料。在實施上,胚料2可經由輥軋或車刀車削攻牙的方式形成一預成型螺旋溝槽21。舉例來說,若採用輥軋方式將在胚料2上形成預成型螺旋溝槽21,則是將胚料2置於旋轉的以圓滾模式運動的二滾輪(圖未示)之間,以壓力冷擠、輾壓,使二滾輪之間的距離慢慢減少,同時迫使胚料2產生塑性流動,進而形成預成型螺旋溝槽21。此外,胚料2於輥軋後可另外透過表面硬化處理、拋光處理、加熱處理等加工方式以提高螺桿1的精度及強度,本發明在此不作限制。然而,上述輥軋製作預成型螺旋溝槽21的方式僅是舉例,本發明亦不限定預成型螺旋溝槽21的製作方法。 The screw 1 is a cylindrical rod body, and its outer surface has a spiral groove 11 continuously wound along the longitudinal axis. Here, the screw 1 is made of a blank 2, and the blank 2 may be a metal block or a columnar material. In practice, the blank 2 can form a preformed spiral groove 21 by means of rolling or turning and tapping. For example, if the preformed spiral groove 21 is formed on the blank 2 by rolling, the blank 2 is placed between two rotating rollers (not shown) that are rotated in a rolling mode to The pressure is cold squeezed and pressed, so that the distance between the two rollers is gradually reduced, and at the same time, the blank 2 is forced to flow plastically, thereby forming the preformed spiral groove 21. In addition, the billet 2 may be additionally subjected to a surface hardening treatment, a buffing treatment, a heat treatment or the like to improve the precision and strength of the screw 1 after the rolling, and the present invention is not limited thereto. However, the manner in which the above-described rolling is used to form the preformed spiral groove 21 is merely an example, and the present invention does not limit the method of manufacturing the preformed spiral groove 21.

承上,由於預成型螺旋溝槽21的精度不足,尚具有後續需再行研磨的不平整表面以製作成螺桿1。是以,相較於上述對胚料2的輥軋製作的預成型,本發明的螺桿的研磨方法則為對螺旋式溝槽進行精緻的研磨,故可稱為精磨。研磨方法包括以下步驟:提供一具有多個磨製部的成型砂輪機(S01);將成型砂輪機的該些磨製部抵靠預成型螺旋溝槽的多個弧面(S02);以及藉由該些磨製部同時研磨該些弧面以形成具有螺旋式溝槽的螺桿(S03)。 As a result, due to the insufficient precision of the preformed spiral groove 21, there is still an uneven surface to be further polished to be made into the screw 1. Therefore, compared with the above-described preforming for the rolling of the blank 2, the grinding method of the screw of the present invention is a fine grinding of the spiral groove, so it can be called fine grinding. The grinding method comprises the steps of: providing a forming grinder having a plurality of grinding portions (S01); abutting the grinding portions of the forming grinder against a plurality of curved surfaces of the preformed spiral groove (S02); The arc faces are simultaneously ground by the grinding portions to form a screw having a spiral groove (S03).

於步驟S01中,成型砂輪機3可為一輪盤狀的砂輪機,且成型砂輪機3具有多個磨製部31,而磨製部31可為2至4個或以上,本實施例是以三個磨製部31為例,然並不以此為限。在本實施例中,各磨製部31可為相互平行的環狀結構,並且彼此間距以相同者為較佳。 In the step S01, the forming grinder 3 may be a wheel-shaped grinder, and the forming grinder 3 has a plurality of grinding portions 31, and the grinding portion 31 may be 2 to 4 or more, in this embodiment The three grinding portions 31 are taken as an example, but are not limited thereto. In the present embodiment, each of the grinding portions 31 may be an annular structure that is parallel to each other, and the same spacing is preferred.

於步驟S02中,各磨製部31分別抵靠預成型螺旋溝槽21 的相對應的弧面211,其中弧面211為預成型螺旋溝槽21的表面。在本實施例中,胚料2可透過二頂心C夾持來進行研磨。具體而言,各頂心C分別夾持於胚料2長軸方向X的二個端部,以便於研磨過程控制胚料2的移動。於此,胚料2透過頂心C以短軸方向Y移動至成型砂輪機3,並由弧面211抵靠磨製部31,且可沿長軸方向X來進行研磨。此外,成型砂輪機3的磨製部31與胚料2的干涉量可依據欲研磨的溝槽精度需求而定,越高精密度的研磨則磨製部31與胚料2的干涉量以越低者為佳,如此可以較低干涉量的磨製部31對胚料2進行較微幅的研磨,以滿足較高的溝槽精度要求。 In step S02, each of the grinding portions 31 respectively abuts against the pre-formed spiral groove 21 Corresponding curved surface 211, wherein the curved surface 211 is the surface of the preformed spiral groove 21. In the present embodiment, the blank 2 can be ground by sandwiching the two center cores C. Specifically, each of the center cores C is respectively clamped at the two end portions of the longitudinal direction X of the blank 2 to facilitate the movement of the blank 2 by the grinding process. Here, the blank 2 is moved to the molding grinder 3 in the short-axis direction Y through the center of the core C, and is abutted against the grinding portion 31 by the curved surface 211, and is polished in the longitudinal direction X. Further, the amount of interference between the ground portion 31 of the forming grinder 3 and the billet 2 may depend on the accuracy of the groove to be ground, and the higher the precision of the grinding, the more the amount of interference between the grind portion 31 and the billet 2 The lower one is preferable, so that the blank portion 2 can be slightly ground by the grinding portion 31 with a lower interference amount to meet the higher groove precision requirement.

接著,於步驟S03中,各磨製部31係同時研磨各磨製部31抵靠的弧面211。在本實施例中,由於三個磨製部31分別抵靠各個弧面211,因此成型砂輪機3可一次研磨預成型螺旋溝槽21的三個弧面211。同樣地,當成型砂輪機3具有四個磨製部31時,即可一次研磨四個弧面211。是以,本實施例藉由三個磨製部31來同時研磨預成型螺旋溝槽21,可節省研磨的時間。傳統上使用單一磨製部對預成型螺旋溝槽進行成型研磨時,為了磨除預成型螺旋溝槽中的預設部份以達到預定精度,需要控制胚料的移動速度,以避免發生胚料移動速度過快而致使研磨後未達預定精度之情況。相較之下,若要求要達到與傳統上使用單一磨製部對預成型螺旋溝槽進行成型研磨的相同研磨精度,則本實施例中每一個磨製部31在單位時間內所需負擔的平均研磨量較低。換句話說,磨製部31愈多,則每一磨製部31在單位時間內須負擔的平均研磨量就越低。舉例而言,如圖2A所示,方向A為胚料2研磨時的移動方向,而成型砂輪機3沿著方向A上的磨製部依序為31a、31b、31c。於本步驟中進行研磨時,可由第一個磨製部31a負責磨除弧面211中預設總研磨量的1/3,接著再由第二個磨製部31b繼續研磨同一弧面211而磨除另外1/3的研磨量,最後由第三個磨製部31c對同一弧面211進行最後研磨而磨除最後1/3的研磨量,以達到預定的研磨精度。因此,在要求於單位時間內要磨除相同研磨量(亦即要在相同時間內達到相同研磨精度)的情形下,原本在單位時間內完全由單一磨製部來負擔的研磨量以及整個研磨過程中所負擔的總研磨量,在本實施例中則平均 由3個磨製部31來負擔,故螺桿1所需的成型研磨時間便可降低;並且因為每一個磨製部31所需負擔的平均總研磨量較由單一磨製部所需負擔者為低,即本實施例之方法對於每一個磨製部31的耗損量也因此而降低,故本實施例可降低成型砂輪機3的耗損,進而可提高成型砂輪機3的使用壽命。 Next, in step S03, each of the grinding portions 31 simultaneously grinds the curved surface 211 against which the respective grinding portions 31 abut. In the present embodiment, since the three grinding portions 31 abut against the respective curved surfaces 211, the molding grinder 3 can grind the three curved surfaces 211 of the pre-formed spiral grooves 21 at a time. Similarly, when the molding grinder 3 has four grinding portions 31, the four arc surfaces 211 can be ground at a time. Therefore, in the present embodiment, the pre-formed spiral grooves 21 are simultaneously polished by the three grinding portions 31, thereby saving the polishing time. Conventionally, when a preformed spiral groove is formed and ground using a single grinding portion, in order to remove the preset portion in the preformed spiral groove to achieve a predetermined precision, it is necessary to control the moving speed of the blank to avoid the occurrence of the billet. The moving speed is too fast to cause a predetermined accuracy after the grinding. In contrast, if it is required to achieve the same grinding precision as conventionally using a single grinding portion for the forming and grinding of the preformed spiral groove, each of the grinding portions 31 in this embodiment requires a burden per unit time. The average amount of grinding is low. In other words, the more the grinding portion 31, the lower the average amount of grinding that each grinding portion 31 has to bear per unit time. For example, as shown in FIG. 2A, the direction A is the moving direction when the blank 2 is ground, and the grinding portion of the forming grinder 3 along the direction A is sequentially 31a, 31b, 31c. When the grinding is performed in this step, the first grinding portion 31a may be responsible for 1/3 of the preset total grinding amount in the grinding surface 211, and then the second grinding portion 31b continues to grind the same curved surface 211. The other 1/3 of the grinding amount is removed, and finally the same grinding surface 211 is finally ground by the third grinding portion 31c to remove the last 1/3 of the grinding amount to achieve a predetermined polishing precision. Therefore, in the case where it is required to grind the same amount of grinding per unit time (that is, to achieve the same grinding accuracy in the same time), the amount of grinding which is originally borne by the single grinding portion per unit time and the entire grinding The total amount of grinding that is carried out in the process is averaged in this embodiment. The burden is required to be reduced by the three grinding portions 31, so that the molding and polishing time required for the screw 1 can be reduced; and because the average total grinding amount required for each of the grinding portions 31 is larger than that required by the single grinding portion Since the method of the present embodiment reduces the amount of wear of each of the grinding portions 31, the present embodiment can reduce the wear of the molding grinder 3, thereby improving the service life of the forming grinder 3.

另外,各磨製部31與各弧面211的干涉量可不相同。舉例而言,可部分磨製部31具有較大的干涉量,以作較大程度的研磨,而部分的磨製部31具有較小的干涉量,來作較小程度(亦即較為精細)的研磨(即成型研磨)。當然,上述的干涉量也可以是相同,只要是能同時研磨多個弧面211即可。 Further, the amount of interference between each of the grinding portions 31 and each of the curved surfaces 211 may be different. For example, the partially grindable portion 31 has a large amount of interference for a greater degree of grinding, while the portion of the ground portion 31 has a smaller amount of interference for a smaller degree (ie, more fine). Grinding (ie forming grinding). Of course, the amount of interference described above may be the same as long as the plurality of curved faces 211 can be simultaneously polished.

進一步地,各磨製部31沿胚料2的一移動方向A上與各弧面211的干涉量可為遞減。請同時參考圖2A及圖2B所示,其中圖2B為圖2A區域R的磨製部與弧面的部分放大圖,並且方向A為胚料2研磨時的移動方向,而成型砂輪機3沿著方向A上的磨製部依序為31a、31b、31c。具體而言,磨製部31a與弧面211的干涉量可介於0.03mm至0.1mm,磨製部31b與弧面211的干涉量可介於0.01mm至0.03mm,而磨製部31c與弧面211的干涉量可介於0至0.01mm。如此一來,胚料2的其中一弧面211將經由磨製部31a進行較大程度的研磨。之後,由於胚料2將依移動方向A持續轉動前進,使得此弧面211由磨製部31b繼續進行研磨。此時,若此弧面211仍具有凸出而不平滑的表面時,磨製部31b可進一步地將其磨除,使此弧面211可更為平滑。同樣地,此弧面211轉動前進至磨製部31c進行研磨後,可使弧面211成型而具有與滾珠(圖未示)精密契合的溝槽表面。於此,相較於三個同樣干涉量的磨製部,本實施例藉由三個干涉量依序漸減的磨製部31可在一次的研磨製程中,對胚料2的同一個弧面211依序進行較大程度至較小程度的成型研磨,因此更能藉由較小程度的成型研磨而提高研磨精度。是以,當胚料2經由完整的研磨後,即成為具有螺旋式溝槽11的螺桿1。 Further, the amount of interference of each of the grinding portions 31 with each of the curved surfaces 211 along a moving direction A of the blank 2 may be decremented. Please refer to FIG. 2A and FIG. 2B simultaneously, wherein FIG. 2B is a partial enlarged view of the grinding portion and the curved surface of the region R of FIG. 2A, and the direction A is the moving direction when the blank 2 is ground, and the forming grinder 3 is along The grinding portions in the direction A are sequentially 31a, 31b, and 31c. Specifically, the interference amount of the grinding portion 31a and the curved surface 211 may be between 0.03 mm and 0.1 mm, and the interference amount of the grinding portion 31b and the curved surface 211 may be between 0.01 mm and 0.03 mm, and the grinding portion 31c and The amount of interference of the curved surface 211 may be between 0 and 0.01 mm. As a result, one of the curved surfaces 211 of the blank 2 will be ground to a greater extent via the grinding portion 31a. Thereafter, since the billet 2 is continuously rotated in the moving direction A, the arc surface 211 is continuously polished by the grinding portion 31b. At this time, if the curved surface 211 still has a convex and unsmooth surface, the grinding portion 31b can be further removed to make the curved surface 211 smoother. Similarly, after the curved surface 211 is rotated to the grinding portion 31c for polishing, the curved surface 211 can be formed to have a groove surface that closely matches the ball (not shown). In this embodiment, compared with the three grinding portions of the same interference amount, in the embodiment, the grinding portion 31 with the three decreasing amounts of interference can be used to make the same curved surface of the blank 2 in one grinding process. The 211 is sequentially subjected to a large degree to a small degree of molding and polishing, so that the polishing precision can be improved by a small degree of molding and polishing. Therefore, when the blank 2 is completely ground, it becomes the screw 1 having the spiral groove 11.

請同時參照圖4及圖5,其中圖4為步驟S03的操作示意圖,而圖5為螺桿1與滾珠B的搭配示意圖。進一步而言,於本實施例的研磨步驟中,可僅需研磨預成型螺旋溝槽21的至少部分弧面211a(即圖中所示 的凸起W1)即可達成精磨之效果。所稱部分弧面211a可為以預定經磨除而成形的溝槽弧面111之曲率中心B1為準,由預成型螺旋溝槽21的底部212向預成型螺旋溝槽21的外徑213方向兩邊延伸的45±25度的區域(如圖5所示之角度θ所涵蓋之凸起W1部份)。此外,預成型螺旋溝槽21的底部212可為一凹陷構型,以作為一潤滑溝或油溝使用,例如於日後組配完成時,可容置潤滑液或潤滑油以作為潤滑之用途;此外,此一構型也可於此研磨步驟中,容置研磨液或冷卻液而供其流動,進而帶走於研磨過程中所產生的廢熱,更能有效降低研磨過程中因廢熱累積而導致的熱變形。另外,預成型螺旋溝槽21的底部212的凹陷構型,可例如但不限定為輥軋方式而直接成型。 Please refer to FIG. 4 and FIG. 5 at the same time, wherein FIG. 4 is a schematic diagram of the operation of step S03, and FIG. 5 is a schematic diagram of the matching of the screw 1 and the ball B. Further, in the grinding step of the embodiment, only at least part of the curved surface 211a of the preformed spiral groove 21 may be ground (ie, as shown in the figure) The bulging W1) can achieve the effect of fine grinding. The portion of the curved surface 211a may be defined by the center of curvature B1 of the grooved curved surface 111 formed by the predetermined ablation, from the bottom 212 of the preformed spiral groove 21 toward the outer diameter 213 of the preformed spiral groove 21. The area of 45 ± 25 degrees extending on both sides (the portion of the protrusion W1 covered by the angle θ shown in Fig. 5). In addition, the bottom portion 212 of the pre-formed spiral groove 21 may be in a recessed configuration for use as a lubrication groove or oil groove, for example, when the assembly is completed in the future, the lubricating fluid or the lubricating oil may be accommodated for lubrication purposes; In addition, this configuration can also accommodate the flow of the slurry or the cooling liquid in the grinding step, thereby taking away the waste heat generated during the grinding process, and effectively reducing the accumulation of waste heat during the grinding process. Thermal deformation. Additionally, the recessed configuration of the bottom portion 212 of the preformed spiral groove 21 can be directly formed, for example, but not limited to, by a rolling method.

另外,於預成型螺旋溝槽21中,滾珠B的吃點角度即可為底部212向外徑213兩側方向延伸的45度。而經磨除凸起W1的溝槽弧面111即為滾珠B與螺桿1的螺旋式溝槽11的有效接觸範圍(即為胚料2的底部212向外徑213方向延伸的45±25度之範圍),且與滾珠B之球面互相契合;而於運動時,可因此而盡量降低滾珠B與螺桿1兩者互相摩擦而產生的震動。因此相較於習知螺桿製程中的精磨程序需完整研磨預成型螺旋溝槽21的整個表面,本實施例可以減少實施上所需耗費的時間,並在一定的精度水準下,快速地製成。 Further, in the pre-formed spiral groove 21, the eating angle of the ball B may be 45 degrees in which the bottom portion 212 extends in both directions of the outer diameter 213. The groove arc surface 111 of the grinding protrusion W1 is the effective contact range of the ball B and the spiral groove 11 of the screw 1 (that is, the bottom portion 212 of the billet 2 extends 45±25 degrees toward the outer diameter 213 direction. The range is matched with the spherical surface of the ball B; and during the movement, the vibration generated by the friction between the ball B and the screw 1 can be reduced as much as possible. Therefore, compared with the refining process in the conventional screw process, the entire surface of the pre-formed spiral groove 21 needs to be completely polished. This embodiment can reduce the time required for implementation and quickly manufacture at a certain level of precision. to make.

綜上所述,本發明的螺桿的研磨方法,藉由同時研磨胚料的預成型螺旋溝槽的多個弧面,可減少螺桿的研磨時間,加速螺桿的製程。 In summary, the grinding method of the screw of the present invention can reduce the grinding time of the screw and accelerate the manufacturing process of the screw by simultaneously grinding a plurality of curved surfaces of the preformed spiral groove of the blank.

以上所述僅為舉例性,而非為限制性者。任何未脫離本發明之精神與範疇,而對其進行之等效修改或變更,均應包含於後附之申請專利範圍中。 The above is intended to be illustrative only and not limiting. Any equivalent modifications or alterations to the spirit and scope of the invention are intended to be included in the scope of the appended claims.

S01、S02、S03‧‧‧步驟 S01, S02, S03‧‧‧ steps

Claims (10)

一種螺桿的研磨方法,用以將具有一預成型螺旋溝槽的一胚料製成具有一螺旋式溝槽的一螺桿,包括以下步驟:提供一具有多個磨製部的成型砂輪機;將該成型砂輪機的該些磨製部抵靠該預成型螺旋溝槽的多個弧面;以及藉由該些磨製部同時研磨該些弧面以形成具有該螺旋式溝槽的該螺桿。 A method of grinding a screw for forming a billet having a preformed spiral groove into a screw having a spiral groove, comprising the steps of: providing a forming grinder having a plurality of grinding portions; The grinding portions of the molding grinder abut against a plurality of curved surfaces of the pre-formed spiral groove; and the grinding portions simultaneously grind the arc surfaces to form the screw having the spiral groove. 如申請專利範圍第1項所述的研磨方法,其中該些磨製部的數量為2至4個。 The grinding method of claim 1, wherein the number of the grinding portions is 2 to 4. 如申請專利範圍第1項所述的研磨方法,其中於該研磨步驟中,該些磨製部與該些弧面的干涉量為不相同。 The polishing method according to claim 1, wherein in the grinding step, the amount of interference between the portions of the grinding portions and the curved surfaces is different. 如申請專利範圍第3項所述的研磨方法,其中各該磨製部沿該胚料的一移動方向上與各該弧面的干涉量為遞減。 The polishing method according to claim 3, wherein the amount of interference of each of the grinding portions with each of the curved surfaces in a moving direction of the blank is decreased. 如申請專利範圍第4項所述的研磨方法,其中位於該成型砂輪機沿該移動方向上的末端的該磨製部的干涉量為零。 The grinding method of claim 4, wherein the amount of interference of the grinding portion located at the end of the forming grinder along the moving direction is zero. 如申請專利範圍第5項所述的研磨方法,其中該末端的該磨製部以外的該些磨製部與該些弧面的干涉量是介於0.01mm至0.1mm。 The polishing method according to claim 5, wherein the amount of interference between the grinding portions other than the grinding portion at the end and the curved surfaces is between 0.01 mm and 0.1 mm. 如申請專利範圍第1項所述的研磨方法,其中該螺桿的螺距是介於0.5mm至3mm。 The grinding method of claim 1, wherein the pitch of the screw is between 0.5 mm and 3 mm. 如申請專利範圍第7項所述的研磨方法,其中該螺桿的螺距是1mm。 The grinding method of claim 7, wherein the screw has a pitch of 1 mm. 如申請專利範圍第1項所述的研磨方法,其中該些弧面的角度是由該預成型螺旋溝槽的底部向該預成型螺旋溝槽的外徑方向延伸之45±25度。 The grinding method of claim 1, wherein the angle of the curved surface is 45 ± 25 degrees extending from the bottom of the preformed spiral groove toward the outer diameter of the preformed spiral groove. 如申請專利範圍第1項所述的研磨方法,其係應用於滾珠螺桿。 The polishing method according to claim 1, which is applied to a ball screw.
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CN106041680A (en) * 2016-07-27 2016-10-26 南京理工大学 Grinding device for outer roller path of ball screw pair and grinding method
CN114393463A (en) * 2021-12-31 2022-04-26 安徽凯瑞汽配制造有限公司 Metal bolt surface grinding device

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CN110977621B (en) * 2019-11-22 2020-12-04 抚州金叶农资有限责任公司 Surface treatment method for casting and molding fire grate of biomass burner accessory

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JP2002283195A (en) * 2001-03-27 2002-10-03 Takada Seisakusho:Kk Method for manufacturing ball screw shaft
DE102004034542A1 (en) * 2004-07-16 2006-02-16 Zf Lenksysteme Gmbh Grinding wheel for producing external or internal ball threads on workpieces

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN106041680A (en) * 2016-07-27 2016-10-26 南京理工大学 Grinding device for outer roller path of ball screw pair and grinding method
CN114393463A (en) * 2021-12-31 2022-04-26 安徽凯瑞汽配制造有限公司 Metal bolt surface grinding device

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