(1) For a tight bolted connection with transverse load, the bolt is carried by . UJn/s;$.e�
�@�[v8}��D
A. shear stress B. tensile stress 5�r7h=[��N
Nn�O�I:X {
C. shear stress and tensile stress D. shear stress or tensile stress |!}wF}iLc)
Ia7D� F��'
(2) For a tight bolted connection with axial tensile load F and preload , the resultant tensile force in the bolt is . <�[<24��7%
}dKL�MNqPA
A. B. C. D. l��[*s��Hi
�.���[(��P
(3) If the performance grade of a bolt is 6.8, then the yield limit stress of the bolt material is MPa. eM }W�6vIn
J3I�RP/*�z
A. 600 B. 800 C. 680 D. 480 O]��ZC+]}/
� d1�bh�JK
(4) The lubricating method of a journal bearing is dependent on . LS6ry,D"�7
ox4W$Y�dMG
A. average intensity of pressure p B. circle velocity of journal v C. pv D. K(3&27sGN�
6#|�qg*
OS
(5) For a hydrodynamic radial journal bearing, the valid method for increasing is to . �s.rT]��
fn�OIv�#��
A. increase relative clearance B. increase oil supply zt�?H~0$LB
�e1�uM�R-Q
C. decrease D. replace lubricating oil with lower viscosity �M�=[t��h�
=�UUd8,C�/
(6) For a hydrodynamic radial journal bearing, the relative clearance is the ratio of . �u`6�/I#q`
9wME�vX�70
A. diametral clearance and journal diameter B. radial clearance and journal diameter S�&01S�X6
85hQk+B�u4
C. minimal clearance and diametral clearance &CUC{t$VHX
g@��u�;Y�5
D. minimal clearance and journal diameter �=G>.�-Qfs
Q!]IG;3Sx|
(7) The axial preloading for rolling bearings is for _______. Q�S;F+cmTh
�ugx�w!�cj
A. increasing loading capacity B. decreasing noise �Yrsp%<q�j
�4#h��?Wga
C. improving running precision D. avoiding shaft displacement �SSQ�T��;>
@�'�gl~�J7
(8) The inner ring and outer ring of the bearing are separable. j{
"��[E�c
�J�#(�,0�h
A. deep-groove ball B. self-aligning ball C. tapered roller D. self-aligning roller 5[<�F_"�x
N8� M'0�i?
(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 _______. �XN(�tcdCG
��s�|g��p�
A. B. C. D. uncertain �
0V�e%
.k
����c� _mq
(10) For a cylindrical helical compressive spring, the maximal shear stress on spring wire happens at the ______. eJ:Yj
~X`<
�OA�VQ`�ek
A. inner side of spring coil B. outer side of spring coil K7G�m-=��%
?�@3&dk~ni
C. center of spring wire D. arbitrary position on spring wire ZOn�_�dYjC
L;Vq� �j]_
(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 _____. gY%&IH�Q'�
AWL[zixR��
A. decreased to 3/4 of the original value B. decreased to 9/16 of the original value RM#��fX^)=
pw;r 25� �
C. not changed D. increased to 4/3 of the original value \n;g2/VjO�
�_�k|g�@�"
(12) For a static balanced rigid rotor, its mass center is located at the rotating axis. V�Y_f =���
�V4EM5 Z\k
A. certainly B. not always C. certainly not w�ibwyz��o
`I{�tZ$i�D
(13) Shown in the figure is a cylindrical cam with uniform material, accurate manufacture and installation. When it rotates round the axis A-A, the cam is under the state of _________. /yp/9�r@T0
[�,��GU5,o
A. static imbalance B. static balance C. complete imbalance D. dynamic balance
p�;�e$kg1
�[G=:?J,P�
K�qK9���X�
Br&�^0�9�S
(14) The installation of flywheel in machinery is to . ,S0UY):(�A
}U
i_ynZ!�
A. eliminate speed fluctuation B. realize steady running .��v\Pi�lF
�Uh%6L�Pg^
C. decrease speed fluctuation D. balance the inertia forces @s�dS�0p�C
BtID;^D��z
(15) In order to decrease the flywheel weight, the flywheel should be installed on the 。 I5Q~T5�Ar�
?eVj8 $BQo
A. equivalent link B. crankshaft with lower rotating speed
s{B_�N�/^
_6L�H"o��3
C. crankshaft with higher rotating speed D. spindle of machinery 716�hpj#*�
e lay�
=%)
T�1bFxim#b
G\):2Q�z!|
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. Y�LigP"*~^
&<@�%{h@
=
{����<r`5�
��-?�Ejbko
| 4 `.#�4
{n6\g�]�p3
h)P]gT0�f/
�z��aB�G=�
=:�;Y�Ti�e
pb6 �Q?QG,
wC�C-Y� kA
7pd$�?=__I
EL"4E�'�,
��LK{a9`
h
unpfA#&!"
C5c�Fw/'�,
�`�TOX1cmw
L��+u�OBW_
8
dl��Inms
]y�w_�
n^@
i��pfm�'aQ
���*�T��J<
|HNQ|r_5S�
6NU8
H�Jp�
zo/�0b/lQ�
����V2lp7"
^Gr�NfB[Qu
tnA�_!$Y
a
t7sUt��mq
#*[,woNk��
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. �|:dCVd<du
Z�3Bo
@`&?
(1) Determine the loads carried by the shaft and shaft types in each structure scheme. �buc,M@��>
2LtU;}�7s�
(2) Determine the stresses on the shaft and their changing characteristics in each structure scheme. H�f!9`�R�[
3we�.*\2�$
(3) Compare the strength difference of the four shafts. (N&k�}CO]W
*7)S�%�r,?
�|^
2r�tI�
{yGZc3e1j
(a) (b) (c) (d) 0��G+L1a
-
(YaOh^T:�|
i=�,B�88ko
�6RR4L^(�m
6GvhEu�lYR
;9 =}_�h)]
oHYD�_8�'f
WO.}DUfG�+
�Lf$Q
%eM0
R^mu%dw)(%
���i{���%z
@5<]�W+jk4
;m2"c�L>{l
�a���wj}�K
U��*�`����
*DPTkMQ�N�
4. (8 points) Shown in the figure is a transmission layout for a belted conveyer. The arrangement for speed reduction is as follows: 1(motor)→2(chain drive)→3(gear reducer)→4(belt drive)→5(conveyer). Point out the unreasonable aspects of the arrangement and give a correct order represented with the drive number. [Gh%n�s�H�
(ffOu#R�Q3
PHe~{�"|d?
%XDip]+�rb
5. (15 points) Shown in the figure, a helical gear shaft is supported by a pair of angular contact ball bearings (7208AC) with ; the radial loads acting on the bearings are , ; the externally axial load on the shaft is ; the rotating speed of the shaft is . e�s�*_Oo�1
IPr*p�Q{;c
(1) Find the axial forces on the two bearings: , . !.��"%M^�J
oHc-0$eMKY
(2) If , find the equivalent dynamic loads of the two bearings: , . �os�"�[Iji
Q��(!}t"�u
(3) Find the bearing lives: , . E9�80yX�JR
{Q#Fen
;y|
�\(
��Gf+
zBr�Wm_R5T
a|]�%/�[G@
/64^�5DjTh
%����BKR
}
;/hH=I�T�
(c*��7�VO;
4%#��V^??E
qMW%$L\H�A
��edImrm1f
;nAg�4ll8Q
Q�B.*�R?�A
AT'_0>�x�8
\��3�js�}�
8n.�"�5,P�
LK-K�_!��F
>w]k3�M�C�
P/1UCITq�}
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 . L]L~TA<D9i
�i1_>>49*
@�y~BYi�Ks
�#K,qF*���
UV
*tO15i�
0F0(]�7g^�
e2=,n6N]c�
�coP�$7Q .
lW��yP�[>*
�2Ws/0�c��
p�tc�H>wM!
f2�9HQhXqS
7. (15 points) Shown in Fig. (a) is the dynamically equivalent model of a mechanical system. The equivalent resistant moment of force is a given function of the rotating angle shown in Fig. (b) with the period . The equivalent driving moment of force is constant. The equivalent moment of inertia of the system is (constant). The average rotating speed of the equivalent link is . /�>2$
X�wP
_%p9�B#X<>
(1) Find the equivalent driving moment of force. c7T�W�AG_+
p��ra-8�z-
(2) Find the coefficient of speed fluctuation , maximal rotating speed and minimal rotating speed of the equivalent link. 3Tv�hOC>yG
&+w!'LSaD�
(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. �4uAb
LSh9
*,*:6�^�t�
MzW�$Sl&:�
�Z��W�e$(?
{arjW�3~M:
y�I�)�fu^
nF[eb{�GR`
�VA
r�?teY
G��C��#�95
w.�F3o4YP�
C00*X[��p
6Q?6-��,?_
~)CU m[:oM
�*l8vCa9�Y
3eDx@�8N
}
�::b;�4Q�L
}sNZQ89V*v
|2]WA'���q
o;-!�?�uJ
v__Go� kj-
(#��Kv��m�
DG9;6"HB�X
jQlK�-U=oi
3~09)0�"!d
��5Gp�K��X
�rca"q�[,�
�BTQC�1;;N
U"G�+su->e
(NV=YX��?s
v�K�>^�#b3
XD>@EYN<�X
J�g6[/7*m
�|#kf.kN��
EqU[mqe��F
qUg�4�-�Z4
�!@��� '2�
R�63d
��`W
�srA
�~gzF
};sm8�P�{M
�~ZC=!|�Q#
6��Ky"4\e�
�gJv^v�`X�
8. (15 points) Point out all the mistakes in the shaft system shown in the figure and explain them with brief words.
