ImageVerifierCode 换一换
格式:PDF , 页数:24 ,大小:1.53MB ,
资源ID:656582      下载积分:10000 积分
快捷下载
登录下载
邮箱/手机:
温馨提示:
如需开发票,请勿充值!快捷下载时,用户名和密码都是您填写的邮箱或者手机号,方便查询和重复下载(系统自动生成)。
如填写123,账号就是123,密码也是123。
特别说明:
请自助下载,系统不会自动发送文件的哦; 如果您已付费,想二次下载,请登录后访问:我的下载记录
支付方式: 支付宝扫码支付 微信扫码支付   
注意:如需开发票,请勿充值!
验证码:   换一换

加入VIP,免费下载
 

温馨提示:由于个人手机设置不同,如果发现不能下载,请复制以下地址【http://www.mydoc123.com/d-656582.html】到电脑端继续下载(重复下载不扣费)。

已注册用户请登录:
账号:
密码:
验证码:   换一换
  忘记密码?
三方登录: 微信登录  

下载须知

1: 本站所有资源如无特殊说明,都需要本地电脑安装OFFICE2007和PDF阅读器。
2: 试题试卷类文档,如果标题没有明确说明有答案则都视为没有答案,请知晓。
3: 文件的所有权益归上传用户所有。
4. 未经权益所有人同意不得将文件中的内容挪作商业或盈利用途。
5. 本站仅提供交流平台,并不能对任何下载内容负责。
6. 下载文件中如有侵权或不适当内容,请与我们联系,我们立即纠正。
7. 本站不保证下载资源的准确性、安全性和完整性, 同时也不承担用户因使用这些下载资源对自己和他人造成任何形式的伤害或损失。

版权提示 | 免责声明

本文(DIN 3971-1980 Definitions and Parameters for Bevel Gears and Bevel Gear Pairs《伞齿轮和伞齿轮副的定义和参数》.pdf)为本站会员(周芸)主动上传,麦多课文库仅提供信息存储空间,仅对用户上传内容的表现方式做保护处理,对上载内容本身不做任何修改或编辑。 若此文所含内容侵犯了您的版权或隐私,请立即通知麦多课文库(发送邮件至master@mydoc123.com或直接QQ联系客服),我们立即给予删除!

DIN 3971-1980 Definitions and Parameters for Bevel Gears and Bevel Gear Pairs《伞齿轮和伞齿轮副的定义和参数》.pdf

1、DIN 3971 x, = Tooth thickness alteration factor Other quantities as in Fig. 7 Figure 8. Standard basic rack tooth profile with positive tooth thickness alteration DIN3971 Page9 Y 9 II Datum. line ha=ho DIN 867 Datum line Figure 11. Standard basic rack tooth profile with negative addendum modificatio

2、n Page 10 DIN 3971 N o te : The addendum modification is stated for the tip distance R of the standard basic rack tooth profile. Depending on the manufacturing method it either in- creases steadily towards the centre of the crown gear or is constant at all tip distances. In the second case it is the

3、refore simpler to speak of the addendum modification of the complete basic crown gear versus the reference cone of the bevel gear. Because the reference cones of the gears have to coincide with the pitch cones of the gear pair (see Section 3.4) a bevel gear with positive addendum modification is alw

4、ays mated with a bevel gear having equally large negative addendum modification (gear train at reference centre distance): xhl + rh2 = 0 (19) 3.5 Parameters in the crown gear reference plane 3.5.1 Crown gear reference circle, crown gear radius RP The crown gear reference circle is determined by the

5、number of crown gear teeth zp and the module mpt exist- ing on its circumference. Its radius (crown gear radius) RP is given by Straight teeth 3.5.2 Crown gear angular pitch r p The crown gear angular pitch T is the centre angle at the crown gear centre which is enclosed by two crown gear radii runn

6、ing to adjacent right-hand or left-hand flanks, see Fig. 12. It is given by 3.5.3 Tooth thickness half angle #p (on a straight bevel gear) The tooth thickness half angle pp of a straight bevel gear is the centre angle at the crown gear centre which is en- closed by the tooth centre lineand an adjace

7、nt right-hand or left-hand flank of the standard basic rack tooth profile, see Fig. 12. It is given by SP *p=2.Rp Spiral teeth (left-hand) (22) Helical teeth (left-hand) Spiral teeth (right-hand) Figure 12. Straight, helical and spiral teeth on the crown gear DIN 3971 Page 11 3.5.4 Tooth space half

8、angle lp (on a straight bevel gear) The tooth space half angle Qp of a straight bevel gear is the centre angle at the crown gear centre which is en- closed by the tooth space centre line and an adjacent right-hand or left-hand flank of the standard basic rack tooth profile, see Fig. 12. It is given

9、by 23) 3.5.5 Datum tooth traces, reference tooth trace5 The datum tooth traces (reference tooth traces) are the linesof intersection of the crown gear tooth flanks (bevel gear tooth flanks) with the crown gear reference plane (with the reference cone). Depending on the form and disposition of these

10、lines, see Fig. 12, the following are distinguished: 3.5.5.1 Straight teeth, With straight teeth the datum tooth traces are straight lines passing through the crown gear centre. With straight bevel gears the prolongations of the (straight) reference tooth traces pass through the reference cone apex.

11、 3.5.5.2 Helical teeth, With helical teeth the datum tooth traces are straight lines touching a circle concentric with the crown gear axis and lying within the tooth system. With helical bevel gears the reference tooth traces are helices on the reference cone envelope surfaces. 3.5.5.3 S p i r a I t

12、e e t h, spiral bevel gears With spiral teeth the datum tooth traces are curves having various forms in the crown gear reference plane, depending on the manufacturing method used.Typical forms include the circle, involute, cycloids and sinoids. With spiral bevel gears the disposition of the referenc

13、e tooth traces is derivable from the datum tooth traces. The parameters for the datum tooth traces and reference tooth traces result from the manufacturing method. straight bevel gears helical bevel gears 3.5.6 Helix angle (spiral angle)/?, The helix angle/? is the acute angle formed at a tip dist-

14、ance R between a tangent to the datum tooth trace and the line through the tangent contact point to the crown gear centre, see Fig. 12. In the case of spiral bevel gears the helix angle is also termed the spiral angle. On a bevel gear the helix angle/? is the acute angle between a tangent to the ref

15、erence tooth trace and the reference cone envelope line through the tangent contact point. On straight bevel gears the helix angle /?equal to zero. The helix angles of a bevel gear may alter with the tip distance R. In thiscase the characteristic helix angles and the disposition of the tooth traces

16、shall be stated, for example the helix anglePP on the crown gear reference circle, or the helix angle/?, at the mean cone distance, or the helix angle/?, at the outer cone distance. right-hand and left-hand teeth A tooth system is right-hand (left-hand) if, on viewing the upright tooth from the apex

17、 of the cone, the tangent to the tooth trace is disposed to the right (left) at the refer- ence point observed. 35.7 Facewidth b The facewidth b is the portion of a reference cone envelope line lying between the outer and inner end faces of the teeth, see Figs 1 to 3 and Fig. 12. 3.6 Tip surface and

18、 root surface, tip cone and root cone The tip surface and root surface are generally surfaces which are conical with regard to the crown gear axis or cone axis; they are designated as the tip cone and root cone. The envelope surfaces on the basic crown gear determine the variation of the tooth depth

19、 along the facewidth. Since the tooth depths of the basic crown gear transfer directly to the bevel gear, their parameters coincide with those of the bevel gear in Section 4.3.1. 3.6.1 Tip angle , addendum angle 8, The angle enclosed by the gear axis and a tip cone envelope line is the tip angle 6,

20、see Fig. 1. The addendum angle 8, is the angle in an axial section between the tip cone envelope line and the reference cone envelope line (the crown gear reference plane in the case of a crown gear), see Figs 1 and 2. 3.6.2 Root angle 6f. dedendum angle Of The angle enclosed by the gear axis and a

21、root cone enve- lope line is the root angle df, see Fig. 1. The dedendum angle of is the angle in an axial section between the root cone envelope and the reference cone envelope line (the crown gear reference plane in the case of a crown gear), see Figs 1 and 2. 3.6.3 Bevel gears with tapering tooth

22、 depth Simple geometrical relationships result when the tip cone apex and the root cone apex coincide with the reference cone apex in the crown gear reference plane. In this case 8,=6+0, 6,= 6- Of, and the tooth depths are proportional to the tip distance R, see Fig. 1. In this case the bottom clear

23、ance is not constant. To obtain a constant bottom clearance over the facewidth it is necessary for the tipcone apex to lie within the refer- ence cone when the root cone apex and reference cone apex coincide. This usually leads to the following being adopted ha, = 6, +Of2 (.e. Sal = Sf2) (26) Sa, =6

24、, + Sfl (.e. Oa =Ofl), i 27) see Fig. 2. N o te : This design allows the use of larger tool radi- using without the risk of meshing interference at the inner end of the tooth. The versions according to equations (24) to (27) are to be regarded as limiting cases of the geometrical design between whic

25、h other versions are feasible, e.g. “inclined root cone line“ in which the root cone apex does not coincide with the reference cone apex. Page 12 DIN 3971 For bevel gears with tapering tooth depth it is usual to adopt as the standard basic rack tooth profile only the cylindrical section through the

26、basic crown gear, and hence the transverse module as the datum length. 3.6.4 Bevel gears with constant tooth depth Simple geometrical relationships also exist when the tip angle and root angle of a gear are equal. In this case the tooth depth is constant over the entire facewidth; this means that it

27、 is the same at each tip distance. The tip angle and root angle may be the same as the refer- ence cone angle, see Fig. 3. In this case the tip surface and root surface of the basic crown gear are circular surfaces parallel to the crown gear reference plane. In the case of bevel gears with constant

28、tooth depth the normal section through a tooth at the mean diameter of the basic crown gear is usually taken as the standard basic rack tooth profile, and hence the normal module as the datum length. 4 Additional definitions All definitions in this Section.relate to the bevel gear devoid of deviatio

29、ns. The equations thus apply to the nominal dimensions or the limiting dimensions of the toothsystem. and parameters on a bevel gear 4.1 Parameters far the tooth profile 4.1.1 Pressure anglea, The pressure anglea, at any flank point Y is formed by two tangentserected in this point to the spherical s

30、urface surrounding the apex, one of these tangents intersecting the gear axis whilst the other is tangent to the tooth flank. With helical and spiral bevel gears a distinction has to be made between the pressure angleafi on the spherical surface of radiusR and the pressure anglea, in a nor- mal sect

31、ion. On a straight bevel gear ayt and a, coincide. 4.1.2 Transverse pressure angle a The transverse pressure angle a is that pressure angle whose vertex lies on the reference cone. Assuming that the standard basic rack tooth profile is given in the normal section then the transverse pressure anglea,

32、 is equal to the pressure angleap. If the standard basic rack tooth profile is given in the cylindrical section then the transverse pressure angle a, is equal to the pres- sure angle ap. 4.2 Parameters for the flank spacing 4.2.1 Transverse tooth thickness s, The transverse tooth thicknessst is the

33、length of the refer- ence circle arc at the tip distance R between the two flanks of the tooth. The nominal dimension of the tooth thick- ness derives from the tooth thickness on the standard basic rack tooth profile and the addendum modification. If the standard basic rack tooth profile is given in

34、 the cylindrical section then normal tooth thickness s, mp *I 2 St = - + 2 - mp - (x, + xh * tan ap). (28) If the standard basic rack tooth profile is given in the normal section then the transverse tooth thickness st is calculated from the normal tooth thickness s, as follows Sn st =cosp ( 29) wher

35、e mp *I 2 ,=-+2-m*(x+.tanap). (30) For the tip distances according to Sections 2.4.1 to 2.4.3 it is necessary to distinguish the following: the tooth thickness se on the back cone, the tooth thickness si on the inner cone distance and the tooth thickness s, on the mean cone distance. The tooth thick

36、ness on cones other than the reference cone can only be calculated in conjunction with the manufacturing method concerned, or approximately by way of the equivalent cylindrical gear teeth (see Section 4.4.3). With the tooth thickness allowances A, (upper allowance A, lower allowance Ad) referred to

37、the reference circle the tooth thickness limits are found as (31) N o te : It should be noted in this connection that the allowancesgenerally have negative signs so that the tooth thickness limiting sizes are smaller than the nominal di- mension. 4.2.2 Spacewidth e, The spacewidth et is the length o

38、f the reference circle arc at the tip distance R within a tooth space. (32) Corresponding to Section 4.2.1, the following are to be distinguished: the spacewidth e, on the back cone, the spacewidth ei on the inner cone distance and the space- width e, on the mean cone distance. With the tooth thickn

39、ess allowance A, (upper allowance A, lower allowance Ag) referred to the reference circle the spacewidth limits are found as (331 N o te : It should be noted in this connection that the allowancesgenerally have negative signs so that the space- width limiting dimensions are larger than the nominal d

40、imension. 4.2.3 Normal chordal tooth thickness The normal chordal tooth thickness is the chord of the reference circle arc at the tip distance R between the two flanks of a tooth. It is found as e, = Pt - St %(Ci) = et - A, - St st = d * sin - d (34) If this equation is calculated first with the upp

41、er tooth thickness limiting dimension ste and then with the lower tooth thickness limitingdimension sti this yields the limit- ing dimensions for the normal chordal tooth thickness and hence the normal chordal tooth thickness allowances. These allowances can generally be made equal to the tooth thic

42、kness allowances. It is therefore usually suffi- cient to calculate the nominal dimension of the normal chordal tooth thickness and to add the tooth thickness allowances to this. DIN 3971 Page 13 Only with small numbers of teeth may it be necessary to calculate the normal chordal tooth thickness all

43、owances. For this purpose it is usually sufficient to convert with the aid of the allowance factor A: which gives the ratio of a normal chordal tooth thickness allowance Ayto the tooth thickness allowance A,. The allowance factor is i A- A-=?=co S- st a AS d (35) 4.2.4 Height ha above the chord The

44、height h7, above the chord S, is stated at tip distance R in the middle of the tooth perpendicular to the refer- ence cone envelope line. Starting from the tip circle of the complementary cone it is found as - d ha =ha + -. (1 - cos;) * cos8 2 (36) For a straight bevel gear the values for the transv

45、erse sec- tion% and quantities on this virtual tooth system are designated by the subscript v. The quantities mainly involved are as follows: 4.4.3.1 Reference diameter d, The length of the cone envelope line between the com- plementary cone apex and the reference circle of the bevel gear at the tip

46、 distance R is half the reference diameter d, of the virtual equivalent cylindrical gear tooth system. d d,=- cos6 (41) 4.4.3.2 N u m be r of teeth z, The number of teeth L, is that number of teeth which, multiplied by the reference circle pitch pt, yields the circumference of the reference circle o

47、f the virtual equiv- alent cylindrical gear tooth system. d;n z z,=-=- pt cos8 (42) N o t e : In the case of helical and spiral bevel gears it is necessary to distinguish between the number of teeth 2, arising in rhe plane of the developed back cone, and the number of teeth z, ruling for a normal se

48、ction of the virtual equivalent cylindrical gear tooth system. The following can be taken as an approximation: z 2, = cos 6 * cos3 (43) 4.4.3.3 Ti p d i am et e r d, The length of the envelope line between the complemen- tary cone apex and the tip circle of the bevel gear is half the tip diameter d,

49、 of the virtual equivalent cylindrical gear tooth system. d,=d,+ 2 *ha (44) 4.4.3.4 R o o t d i a m e t e r dd The length of the envelope line between the complemen- tary cone apex and the root circle of the bevel gear is half the root diameter dd of the virtual equivalent cylindrical gear tooth system. dd=d, - 2 *hi (45) 4.4.3.5 Ba se d i a m e t e r dvb For approximate representation in drawings and for the manufacture of templates and patterns the virtual equiv- alent cylindrical gear tooth system is usually regarded as an involute tooth system with parameters acco

copyright@ 2008-2019 麦多课文库(www.mydoc123.com)网站版权所有
备案/许可证编号:苏ICP备17064731号-1