(1) For a tight bolted connection with transverse load, the bolt is carried by . j`��o_Stbg
�yP��^C)��
A. shear stress B. tensile stress �/)-�OK7x�
EW�~M�,+?�
C. shear stress and tensile stress D. shear stress or tensile stress ;��]�PP�+h
Pl\�r|gS�;
(2) For a tight bolted connection with axial tensile load F and preload , the resultant tensile force in the bolt is . +td�]g9�Ie
��xW�.�~Jt
A. B. C. D. �B��'D\l\w
Wc�Onv�'l,
(3) If the performance grade of a bolt is 6.8, then the yield limit stress of the bolt material is MPa. �=H_v�R�d
M?O�bK#l!_
A. 600 B. 800 C. 680 D. 480 H��2JK�Qm_
g�@�2f�&�m
(4) The lubricating method of a journal bearing is dependent on . w�s�EOcaie
d�2U+%%Tdw
A. average intensity of pressure p B. circle velocity of journal v C. pv D. �*w�`_(X�f
WX�s?2�S*�
(5) For a hydrodynamic radial journal bearing, the valid method for increasing is to . )C>8B�`^S�
[aF"5G����
A. increase relative clearance B. increase oil supply �?��P%�-p�
(�&!RX.i��
C. decrease D. replace lubricating oil with lower viscosity Q.Mb�zSgXL
`Fx+HIng�,
(6) For a hydrodynamic radial journal bearing, the relative clearance is the ratio of . e�qSCE6r9x
;Qi0j<d�Xd
A. diametral clearance and journal diameter B. radial clearance and journal diameter dJ�F3]h Y�
:Xs3Vh,��V
C. minimal clearance and diametral clearance >K!$@��]2F
-x���VZm8y
D. minimal clearance and journal diameter �2��-�pv
&
�EYRg�,U&'
(7) The axial preloading for rolling bearings is for _______. D4O^5?F)|�
Yq>K1���E|
A. increasing loading capacity B. decreasing noise KP)t,\@f!�
�7nPje���h
C. improving running precision D. avoiding shaft displacement R�qKk�B�8g
�~�~�3*�o�
(8) The inner ring and outer ring of the bearing are separable. INE�E
�37%
f�XSuJ��<G
A. deep-groove ball B. self-aligning ball C. tapered roller D. self-aligning roller .#}A�/V.-Y
}��t*:EgfI
(9) In an important application, if the reliability of rolling bearings is increased to 95%, then the relation between the dynamic load rating relative to 95% reliability to the basic dynamic load rating C is _______. +�y^'\�K�N
>�eWORf>7�
A. B. C. D. uncertain Q��IfP%,LT
T>|Y_3YO_a
(10) For a cylindrical helical compressive spring, the maximal shear stress on spring wire happens at the ______. {s�0�!hp��
X�]�_9g[V�
A. inner side of spring coil B. outer side of spring coil x�YY^tZIV�
QJSi|&Rx&?
C. center of spring wire D. arbitrary position on spring wire q2U?EP�{8~
a�kG|ic-~
(11) For a cylindrical helical compressive spring with working coils being 12, if the number of working coils is decreased by 3, then spring stiffness is _____. OQVo4y�l"�
O�Bf�$�Z"i
A. decreased to 3/4 of the original value B. decreased to 9/16 of the original value G!Yt.M�0��
�h!�`KX�2~
C. not changed D. increased to 4/3 of the original value �-b)3�+�#f
�U ]7;K>.T
(12) For a static balanced rigid rotor, its mass center is located at the rotating axis. [Wxf,r�W i
V`r�xjv}!�
A. certainly B. not always C. certainly not
.hjN*4RY
� tYG6�G�l
(13) Shown in the figure is a cylindrical cam with uniform material, accurate manufacture and installation. When it rotates round the axis A-A, the cam is under the state of _________. U,lO{J��[T
f�NV-_^,R9
A. static imbalance B. static balance C. complete imbalance D. dynamic balance �o*3��\x�g
fOdX�2{�7m
A�Nfy
+��@
'wWuR�@e#&
(14) The installation of flywheel in machinery is to . (��w�vU;u�
�TPLv]$n��
A. eliminate speed fluctuation B. realize steady running xZ(d*/�6�E
5=b�6B=\*~
C. decrease speed fluctuation D. balance the inertia forces ND�/oK�M+?
�Gi�Khd��y
(15) In order to decrease the flywheel weight, the flywheel should be installed on the 。 $~\Tl:!�#?
pktn�X-Slt
A. equivalent link B. crankshaft with lower rotating speed ��u>:j$@56
+:W�?��:\
C. crankshaft with higher rotating speed D. spindle of machinery 22�1}xhn5
5H�,�(\X�d
1tTY�)Ev�f
{1+�me���E
2. (7 points) In a tight bolted connection with axial tensile load, both the preload and the axial working load are constant. If the metal gasket between the connected components is replaced by a leather one, explain, with force-deformation diagram, the changes of the resultant tensile force in the bolt and residual compressive force on the connected components. �~6+Um_A_L
or�bz`I�Qc
B1]FB�|0's
Cq3�A�u�%7
x�=X&b�%09
@!�|h!�p;�
mo,�"�3YW�
1:_}`x=�hM
�V�t-V'�`Y
�eR/X���9<
�K�uE�M~Q=
�SR`A]EC(V
02)Ybp�6y�
B9��
�
�,�
{�hm-0Q���
�]�\]mwvLT
�EW3--�33s
u�ax�kGEXr
n�A%8�
bZ+
5�HTY ~&C�
|�!1i�LWQ�
uC6�e2py<[
�8%xiHPV�g
�sDu���&9+
&4)�PW\ioY
�}:1qK6
7S
QkLcs�6�)R
ej
�&o,gX�
��|HPb�$#i
�`8TL*��.9
3. (10 points) Shown in the figure are the four structure schemes of the moving pulley shaft system in a lifting device. In each structure scheme, the lifting load is constant; the shaft diameter, shaft material and method of heat treatment are the same, respectively. `_"?$� v2F
k�9c`[M���
(1) Determine the loads carried by the shaft and shaft types in each structure scheme. �}�����/g1
�Rn{�X+�b.
(2) Determine the stresses on the shaft and their changing characteristics in each structure scheme. n:D�r< q�.
0 4oMgH>Vd
(3) Compare the strength difference of the four shafts. 5z"
�X>!?^
��r�K�l���
u:��,B�&}j
-NDB.~E^DJ
(a) (b) (c) (d) {�P%\& \{F
�*�P`�k�|-
P{,=a]x,mz
�2�,.8�oa(
�)1O�|+m k
E��c�lsOBg
�SWNT}�{x]
2}5@:�cwR+
�3:b5#c?R-
�0X%#�9s�~
5[^Rf'�w�y
x�J�FxrG'c
"h�&[6-0'�
^5�-SL��?E
Ul:M=8nE%
[kI[qByf�
4. (8 points) Shown in the figure is a transmission layout for a belted conveyer. The arrangement for speed reduction is as follows: 1(motor)→2(chain drive)→3(gear reducer)→4(belt drive)→5(conveyer). Point out the unreasonable aspects of the arrangement and give a correct order represented with the drive number. A�.<�M*[{q
�YRj"]=
5N
.?r}�3C��h
M|�7{�ZE`Y
5. (15 points) Shown in the figure, a helical gear shaft is supported by a pair of angular contact ball bearings (7208AC) with ; the radial loads acting on the bearings are , ; the externally axial load on the shaft is ; the rotating speed of the shaft is . +^%�0/��0e
�F4g3l�� �
(1) Find the axial forces on the two bearings: , . $XFF�NE`�%
"GAKi}y">v
(2) If , find the equivalent dynamic loads of the two bearings: , . 8ya|e�J]/L
(�z%�OK�[�
(3) Find the bearing lives: , . IZZ�
$p�{
�
e:6mz�\J
l,�j0n0�h.
��w�#
;y��
t},71R���y
M =GF@C;�b
QQUZn�eIDp
�Q7?�[@2HN
;7g�~4Uv4}
Q_|��L��v&
UFr5��'�T�
V"|�j Dnn5
n*N`].r#{=
���eo4v[V&
N1'$�;�9 c
us^J�!
s�7
{��7 �nz:f
��$�`Aps7A
E�Bpl�r ,�
�@�5TJ]�=�
6. (15 points) In a gear train shown in the figure, , , , , , , , , , the rotating direction of the gear 1 is as shown in the figure. Find both the magnitude and the direction of . Yf�x'�7�gj
�c]/&x��Rd
((�]Sy,rdk
&�y�:�SK�)
Y/G��~P�,9
Na_O�:\�x#
qb
QH1<yS<
'E�1m-kJz�
�LW�+^m6O
�-De�qlaf(
�9K_p4
�mq
WB=|Ty�~l�
7. (15 points) Shown in Fig. (a) is the dynamically equivalent model of a mechanical system. The equivalent resistant moment of force is a given function of the rotating angle shown in Fig. (b) with the period . The equivalent driving moment of force is constant. The equivalent moment of inertia of the system is (constant). The average rotating speed of the equivalent link is . 47
9yG/+�\
�)�zq� �sn
(1) Find the equivalent driving moment of force. �5K�wT(R o
G^_fbrZjN�
(2) Find the coefficient of speed fluctuation , maximal rotating speed and minimal rotating speed of the equivalent link. �L2^M#�G@t
>^
�M=/+<c
(3) If the allowable coefficient of speed fluctuation is , find the minimum moment of inertia of the flywheel on the crankshaft A of the equivalent link. �;TG�<
$4N
L:RMZp*b�K
}`$Sr�&n 1
������d@_|
�@j?�)uJ0Q
t5jZ8&M5]�
�\�Dr�?�}D
���hQ}B?'>
@F0+�t�;��
�k\�w�I^D�
� w#\*{E�N
pcj
b;&�<�
eNw9"
X�}g
zeG_H}�[2&
e|jmOYWG��
ZF6?N?t}h8
$M� 1�/�74
6Cd% @Q2cr
04�13�K�_�
��O�+Q�t8,
sX$�E�dI�q
�\5��s�#9�
�j[<��}l&�
��1JXa/f�+
J}UG{Rt�tI
jk�'.�G��z
46c�d
5SLK
�Apx�GrC�u
/?wH�1� �,
o|?�bv�F�C
*� vMN�v��
42wa9UL<Ka
m
gxoM|n6�
<p�7�4U( V
}+fM�Yg�w�
[j]3='2}�G
��5 UQ�bd8
tgP�x!��5U
�~Yw`w��2�
SX�W8p>1Jw
�}(/")i4�h
^6E���+l#�
8. (15 points) Point out all the mistakes in the shaft system shown in the figure and explain them with brief words.
