Axial Static Load Dependence Free Vibration Analysis of Helical Springs Based on the Theory of Spatially Curved Bars

Yildirim, Vebil

doi:10.1590/1679-78253123

Vebil Yildirim

University of Çukurova, Department of Mechanical Engineering, 01330 Adana, TURKEY. vebil@cu.edu.tr

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Figure 1:
Frenet trihedral.

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Figure 2:
Geometry of a helix subjected to an axial compressive force and a torque.

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Figure 3:
Critical buckling loads obtained in a static manner (Yıldırım, 2009bYıldırım V. (2009b). Report: Buckling and Free Vibration Problems of Helical Compression Springs with Pre-Load: A Software Program and Design Charts. Ankara: Tübitak (The Scientific and Technological Research Council of Turkey).).

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Figure 4:
Relation between frequencies and static axial load for the same spring.

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Figure 5:
Critical buckling loads obtained in a static manner for C=10 and n=5 (Yıldırım, 2009bYıldırım V. (2009b). Report: Buckling and Free Vibration Problems of Helical Compression Springs with Pre-Load: A Software Program and Design Charts. Ankara: Tübitak (The Scientific and Technological Research Council of Turkey).).

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Table 1:
Natural frequencies (in rad/s) for the benchmark spring (TMM: Transfer matrix method, FEM: Finite element method, EXP: Experimental).

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Table 2:
The first 16 natural dimensionless frequencies (f/f_axia _l ) for a cylindrical helical spring under a static axial load compressed to half of its free axial length.

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Table 3:
The present first 16 natural frequencies for a cylindrical helical spring based on the Timoshenko and Bernoulli-Euler hypotheses by using .

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Table 4:
Effects of the axial and shear deformations on the first 16 natural dimensionless frequencies (Po=8.242 N).

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Table 5:
Percent effects of the each stress resultants on the relative compression for some applied axial forces.

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Table 6:
Free vibration frequencies and critical buckling load which are both obtained by using .

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Table 7:
Free vibration frequencies and critical buckling load which are both obtained by using .

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Table 8:
Free vibration frequencies and critical buckling load which are both obtained by using .

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Table 9:
Critical buckling loads and corresponding deformations of the spring.

(1)

(2a)

(2b)

(3)

(4)

(5)

(6)

(7)

(8)

(9)

(10)

(11a)

(11b)

(11c)

(11d)

(11e)

(11f)

(11g)

(11h)

(11i)

(11j)

(11k)

(11l)

(12)

(13)

(14)

(15)

(16)

(17)

(18)

(19)

(20)

(21)

(22)

(23)

(24)

(25)

(26)

(27)

(28)

(29)

(30)

(31)

(32)

(33)

(34)

(35)

(36)

(37)

(38)

(39)

(40)

Modes	Mottershead (1980Mottershead J.E. (1980). Finite elements for dynamical analysis of helical rods, International Journal of Mechanical Sci. 22: 267-283.) (EXP)	Mottershead (1980Mottershead J.E. (1980). Finite elements for dynamical analysis of helical rods, International Journal of Mechanical Sci. 22: 267-283.) (FEM)	Pearson (1982Pearson D. (1982). The transfer matrix method for the vibration of compressed helical springs. J Mech. Eng. Sci. 24:163-171.) (TMM)	Xiong and Tabarrok (1992Xiong Y. and Tabarrok B. (1992). A finite element model for the vibration of spatial rods under various applied loads. International Journal of Mechanical Sciences 34 (1): 41-51.) (FEM)	Yıldırım (1999Yıldırım V. (1999). An efficient numerical method for predicting the natural frequencies of cylindrical helical springs. International Journal of Mechanical Sciences 41/8: 919-939.a) (TMM)	Busool and Eisenberger (2002Busool W. and Eisenberger M. (2002). Free Vibration of Helicoidal Beams of Arbitrary Shape and Variable Cross Section. J. Vib. Acoust. 124(3), 397-409.)
1	391	396.0	394.9	395.0	393.5	393.411
2	391	397.0	397.6	398.0	395.9	395.991
3	459	469.0	456.4	464.0	462.8	462.751
4	528	532.0	518.3	528.0	525.5	525.571
5	878	887.0	859.7	868.0	864.0	863.601
6	878	900.0	874.7	881.0	876.8	876.775
7	906	937.0	--	--	914.3	--
8	--	1067.0	--	--	1037.0	--
9	1282	1348.0	--	--	1310.5	--
10	1386	1409.0	--	--	1363.8	--
Modes	Becker et al (2002Becker L.E., Chassie G.G., Cleghorn W.L. (2002). On the natural frequencies of helical compression springs. International Journal of Mechanical Sciences 44(4): 825-841.) (TMM)	Girgin et al (2006Girgin K., Olgun O., Darılmaz K., and Omurtag M.H. (2006). Dynamic analysis of cylindrical and conical helices by mixed FEM, Journal of Turkish Chamber of Civil Engineering (İMO Teknik Dergi) 4003-4023 (in Turkish)) (FEM)	Lee (2007Lee J. (2007). Free vibration analysis of non-cylindrical helical springs by the pseudospectral method. Journal of Sound and Vibration 305 (3): 543-551.)	Yu et al (2010Yu A. M., Yang C.J., Nie G.H. (2010). Analytical formulation and evaluation for free vibration of naturally curved and twisted beams Journal of Sound and Vibration 329: 1376-1389) (TMM)	Present Study (TMM)
1	393.5	392.5	393.5	393.5	393.4
2	396.1	395.0	396.1	396.1	396.0
3	462.8	462.8	462.9	462.9	462.7
4	525.7	525.9	525.7	525.7	525.6
5	863.8	862.2	863.8	863.8	863.6
6	876.9	875.0	877.0	877.0	876.8
7	913.7	--	913.8	913.8	913.5
8	1037.5	--	1037.5	1037.5	1037.3
9	1310.6	--	1310.7	1310.7	1310.4
10	1364.6	--	1364.6	1364.6	1364.3
11	--	--	--	1395.8	1395.4
12	--	--	--	--	1522.1
13	--	--	--	--	1677.5
14	--	--	--	--	1778.6
15	--	--	--	--	1841.3
16	--	--	--	--	1935.1

Mode No	Mode Types (Becker et al., 2002Becker L.E., Chassie G.G., Cleghorn W.L. (2002). On the natural frequencies of helical compression springs. International Journal of Mechanical Sciences 44(4): 825-841.)	Becker et al (2002Becker L.E., Chassie G.G., Cleghorn W.L. (2002). On the natural frequencies of helical compression springs. International Journal of Mechanical Sciences 44(4): 825-841.)	Haringx (1949Haringx J. A. (1949). On highly compressible helical springs and rubber rods, and their application for vibration-free mountings. Philips Research Reports 4: 49-80.)	Kacar and Yıldırım (2016Kacar İ. and Yıldırım V. (2016) Free Vibration/Buckling Analyses of Non-Cylindrical Initially Compressed Helical Composite Springs. Mechanics Based Design of Structures and Machines DOI: 10.1080/15397734.2015.1066687 https://doi.org/10.1080/15397734.2015.10... )		PRESENT STUDY
					with additional terms	without additional terms	with additional terms
					Eqn. (16)		Eqn. (18)
1	Symmetric	0.4727	0.4742	0.4684	0.4722	0.4740	0.47042
2	Symmetric	0.4732	0.4742	0.4686	0.4723	0.4742	0.47059
3	Axial	0.9955	1.000	0.9970	0.9950	0.9950	0.99503
4	Torsional	1.140	1.140	1.137	1.139	1.139	1.13899
5	Asymmetric	1.574	1.582	1.576	1.572	1.5739	1.57102
6	Asymmetric	1.574	1.582	1.578	1.573	1.5743	1.57148
7	Axial	1.989	2.000		1.988	1.988	1.98833
8	Torsional	2.275	2.280		2.274	2.274	2.27431
9	Symmetric	2.875	2.898		2.872	2.873	2.87093
10	Symmetric	2.875	2.898		2.874	2.875	2.87286
11	Axial	2.983	3.000		2.982	2.982	2.98192
12	Torsional	3.405	3.421		3.403	3.403	3.40288
13	Axial	3.953	4.000		3.952	3.952	3.95162
14	Asymmetric	3.980	4.025		3.980	3.980	3.97940
15	Asymmetric	3.999	4.025		3.996	3.996	3.99601
16	Torsional	4.527	4.561		4.525	4.525	4.52468

Modes		P_o=0				P_o=8.2532 N {with eqn. (18)}
	TIMOSHENKO		BERNOULLI		TIMOSHENKO		BERNOULLI
	f (Hz)	f/faxial	f (Hz)	f/faxial	f (Hz)	f/faxial	f (Hz)	f/faxial
1	79.6940	0.67082	79.7693	0.67146	55.8861	0.47042	56.2129	0.47317
2	79.7155	0.67100	79.7907	0.67164	55.9066	0.47059	56.2335	0.47335
3	118.363	0.99632	118.687	0.99905	118.209	0.99503	118.531	0.99773
4	135.010	1.13645	135.180	1.13787	135.313	1.13899	135.486	1.14045
5	191.610	1.61287	191.939	1.61565	186.638	1.57102	187.458	1.57793
6	191.703	1.61366	192.033	1.61643	186.692	1.57148	187.512	1.57838
7	236.538	1.99106	237.186	1.99651	236.215	1.98833	236.858	1.99375
8	269.569	2.26910	269.909	2.27196	270.189	2.27431	270.536	2.27723
9	327.402	2.75591	328.147	2.76217	341.067	2.87093	342.431	2.88241
10	327.713	2.75852	328.455	2.76477	341.296	2.87286	342.686	2.88456
11	354.446	2.98355	355.415	2.99170	354.253	2.98192	355.254	2.99034
12	403.364	3.39532	403.874	3.39961	404.263	3.40288	404.788	3.40730
13	467.859	3.93820	469.101	3.94865	469.453	3.95162	470.759	3.96261
14	473.721	3.98755	474.990	3.99822	472.753	3.97940	475.060	3.99881
15	477.471	4.01911	478.798	4.03028	474.727	3.99601	477.070	4.01573
16	536.179	4.51328	536.859	4.51901	537.533	4.52468	538.239	4.53063

Modes	Becker et al (2002Becker L.E., Chassie G.G., Cleghorn W.L. (2002). On the natural frequencies of helical compression springs. International Journal of Mechanical Sciences 44(4): 825-841.) (Bernoulli Euler)	Present Study (Everything is included) {eqn. (16)}		Present Study (Rotatory inertia effects are included){eqn. (16)}
			Just axial deformations are neglected	Just shear deformations are neglected	Both axial and shear deformations are neglected
1	0.4754	0.472166	0.4723	0.4746	0.4747
2	0.4758	0.472339	0.4725	0.4747	0.4749
3	0.9982	0.995032	0.9950	0.9977	0.9977
4	1.141	1.13899	1.139	1.139	1.139
5	1.580	1.57235	1.573	1.5769	1.5779
6	1.580	1.57280	1.574	1.5773	1.5784
7	1.995	1.98835	1.988	1.994	1.994
8	2.278	2.27431	2.274	2.274	2.274
9	2.885	2.87201	2.874	2.879	2.881
10	2.885	2.87399	2.876	2.881	2.883
11	2.992	2.98200	2.982	2.990	2.990
12	3.409	3.40287	3.403	3.403	3.403
13	3.964	3.95170	3.952	3.962	3.962
14	3.996	3.97984	3.983	3.988	3.991
15	4.017	3.99638	3.999	4.005	4.008
16	4.533	4.52468	4.525	4.525	4.525

P _0(N)	(δ_Tt /L ₀).100	(δ_Tb /L ₀).100	(δ_Mb /L ₀).100	(δ_Mt /L ₀).100	(δ_Total /L ₀).100
1	0,002	0,0004	0,133	0,426	0,561
5	0,012	0,0017	0,664	2,129	2,807
10	0,023	0,0033	1,328	4,259	5,613
15	0,035	0,0050	1,992	6,388	8,420
20	0,047	0,0066	2,655	8,518	11,23
23,5	0,055	0,0078	3,120	10,01	13,19

α(º)	32.48	31.01	30.25	29.49	29.33	29.30	29.29	29.29	29.29	29.28
P₀(N)	0	10	15	20	21	21.2	21.28	21.285	21.29	21.3
δ/L ₀	0	0.056	0.084	0.112	0.117	0.119	0.119	0.119	0.119	0.119
Modes
1	222.642	169.226	129.217	59.7461	28.2138	15.3332	3.18760	10.7438	10.0724	8.57331
2	222.894	169.362	129.272	60.5366	30.1637	18.7829	11.3754	458.462	458.428	458.360
3	563.766	523.956	497.573	467.041	460.392	459.039	458.496	465.656	465.622	465.554
4	579.415	532.768	505.281	474.283	467.595	466.236	465.690	574.289	574.285	574.276
5	599.363	585.097	580.029	575.431	574.541	574.364	574.294	718.852	718.860	718.876
6	684.590	700.701	708.774	716.801	718.397	718.716	718.844	949.949	949.934	949.904
7	1005.47	981.556	968.123	953.776	950.802	950.204	949.964	974.033	974.018	973.987
8	1033.48	1006.84	992.637	977.901	974.893	974.290	974.048	1054.26	1054.25	1054.24
9	1083.05	1068.97	1062.30	1055.87	1054.61	1054.36	1054.26	1357.64	1357.63	1357.61
10	1351.43	1377.39	1368.61	1359.87	1358.14	1357.79	1357.65	1368.61	1368.60	1368.58
11	1394.88	1380.08	1378.87	1370.76	1369.09	1368.75	1368.62	1416.67	1416.68	1416.71
12	1405.88	1390.37	1398.13	1412.82	1415.81	1416.41	1416.65	1442.35	1442.35	1442.35
13	1442.43	1442.24	1442.23	1442.31	1442.34	1442.35	1442.35	1936.80	1936.82	1936.84
14	1886.91	1909.39	1921.25	1933.56	1936.08	1936.59	1936.79	2091.97	2091.99	2092.03
15	2004.48	2045.51	2066.10	2086.69	2090.80	2091.62	2091.95	2609.91	2609.94	2609.99
16	2505.54	2552.70	2577.50	2603.17	2608.41	2609.46	2609.89	2743.34	2743.36	2743.40

α(º)	32.48	30.25	30.79	30.56	30.33	30.27	30.22	30.17	30.16	30.10
P₀(N)	0	10	15	17	19	19.5	20	20.4	20.5	21
δ/L ₀	0	0.043	0.064	0.073	0.081	0.083	0.085	0.087	0.087	0.089
Modes
1	222.642	165.142	121.753	97.7279	64.1083	52.1781	36.3886	14.0473	4.70327	438.639
2	222.894	165.283	121.817	97.9632	64.7290	53.0238	37.7138	17.4083	442.687	445.634
3	563.766	515.256	483.458	469.384	454.468	450.600	446.673	443.489	449.692	568.302
4	579.415	523.687	490.866	476.579	461.529	457.638	453.693	450.497	568.906	712.619
5	599.363	582.060	575.610	573.149	570.718	570.113	569.509	569.026	711.965	919.762
6	684.590	697.987	704.689	707.351	709.996	710.654	711.310	711.835	922.131	945.238
7	1005.47	968.179	947.128	938.261	929.140	926.820	924.483	922.603	947.550	1041.01
8	1033.48	993.714	972.302	963.447	954.425	952.143	949.852	948.011	1041.99	1333.96
9	1083.05	1062.67	1052.76	1048.83	1044.92	1043.94	1042.96	1042.18	1335.47	1340.81
10	1351.43	1366.59	1351.94	1345.99	1340.00	1338.49	1336.98	1335.77	1342.38	1405.03
11	1394.88	1370.82	1359.18	1353.19	1347.05	1345.50	1343.94	1342.69	1403.80	1408.38
12	1405.88	1381.77	1390.55	1395.29	1400.14	1401.36	1402.58	1403.56	1409.26	1888.77
13	1442.43	1426.98	1418.73	1415.34	1411.89	1411.02	1410.14	1409.44	1888.76	2075.31
14	1886.91	1888.13	1888.50	1888.61	1888.70	1888.72	1888.74	1888.75	2073.62	2547.47
15	2004.48	2038.12	2055.01	2061.78	2068.54	2070.24	2071.93	2073.28	2546.44	2729.88
16	2505.54	2525.26	2535.28	2539.32	2543.38	2544.40	2545.42	2546.24	2727.99	3336.15

α(º)	32.48	31.15	29.78	29.74	29.70	29.66	29.65	29.64
P₀(N)	0	10	20	20.3	20.6	20.9	20.95	21
δ/L ₀	0	0.050	0.101	0.102	0.104	0.106	0.106	0.106
Modes
1	222.642	167.554	51.2411	42.3180	30.8474	10.3869	9.00528	451.454
2	222.894	167.693	52.1726	43.5052	32.5441	14.8720	451.820	458.566
3	563.766	520.406	458.675	456.531	454.368	452.185	458.934	572.004
4	579.415	529.054	465.820	463.665	461.492	459.300	572.054	716.061
5	599.363	583.855	573.021	572.715	572.410	572.105	715.987	938.074
6	684.590	699.598	714.580	715.025	715.469	715.913	938.259	62.721
7	1005.47	976.097	941.769	940.665	939.557	938.445	962.906	1049.08
8	1033.48	1001.48	966.394	965.295	964.194	963.090	1049.16	1348.39
9	1083.05	1066.40	1050.62	1050.16	1049.70	1049.23	1348.50	1357.55
10	1351.43	1373.01	1350.64	1349.96	1349.29	1348.61	1357.66	1411.45
11	1394.88	1376.67	1359.82	1359.14	1358.46	1357.77	1411.31	1428.33
12	1405.88	1386.51	1408.67	1409.50	1410.34	1411.17	1428.36	1916.67
13	1442.43	1435.99	1429.04	1428.83	1428.61	1428.40	1916.59	2084.62
14	1886.91	1900.71	1915.18	1915.62	1916.07	1916.52	2084.43	2583.34
15	2004.48	2042.53	2080.79	2081.94	2083.09	2084.24	2583.15	2737.34
16	2505.54	2541.48	2579.43	2580.60	2581.77	2582.95	2737.14	3361.80

	Equation used	P_cr (N)	α_cr (degree)	δ_cr /L ₀ (%)
Present Study	19	21.283	29.287	11.9
	18	20.4	30.17	8.7
	17	20.9	29.66	10.6
Yıldırım (2009bYıldırım V. (2009b). Report: Buckling and Free Vibration Problems of Helical Compression Springs with Pre-Load: A Software Program and Design Charts. Ankara: Tübitak (The Scientific and Technological Research Council of Turkey).)	--	21.299	29.271	11.96

Brasil

Brasil

Axial Static Load Dependence Free Vibration Analysis of Helical Springs Based on the Theory of Spatially Curved Bars

Abstract