Home

Context Navigation

source: palm/trunk/SOURCE/lpm_droplet_collision.f90 @ 1060

Last change on this file since 1060 was 1037, checked in by raasch, 12 years ago
last commit documented
Property svn:keywords set to `Id`
File size: 26.8 KB

Rev	Line
[849]	1	SUBROUTINE lpm_droplet_collision
	2
[1036]	3	!--------------------------------------------------------------------------------!
	4	! This file is part of PALM.
	5	!
	6	! PALM is free software: you can redistribute it and/or modify it under the terms
	7	! of the GNU General Public License as published by the Free Software Foundation,
	8	! either version 3 of the License, or (at your option) any later version.
	9	!
	10	! PALM is distributed in the hope that it will be useful, but WITHOUT ANY
	11	! WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR
	12	! A PARTICULAR PURPOSE. See the GNU General Public License for more details.
	13	!
	14	! You should have received a copy of the GNU General Public License along with
	15	! PALM. If not, see <http://www.gnu.org/licenses/>.
	16	!
	17	! Copyright 1997-2012 Leibniz University Hannover
	18	!--------------------------------------------------------------------------------!
	19	!
[849]	20	! Current revisions:
	21	! ------------------
[850]	22	!
[849]	23	!
	24	! Former revisions:
	25	! -----------------
	26	! $Id: lpm_droplet_collision.f90 1037 2012-10-22 14:10:22Z raasch $
	27	!
[1037]	28	! 1036 2012-10-22 13:43:42Z raasch
	29	! code put under GPL (PALM 3.9)
	30	!
[850]	31	! 849 2012-03-15 10:35:09Z raasch
	32	! initial revision (former part of advec_particles)
[849]	33	!
[850]	34	!
[849]	35	! Description:
	36	! ------------
	37	! Calculates chang in droplet radius by collision. Droplet collision is
	38	! calculated for each grid box seperately. Collision is parameterized by
	39	! using collision kernels. Three different kernels are available:
	40	! PALM kernel: Kernel is approximated using a method from Rogers and
	41	! Yau (1989, A Short Course in Cloud Physics, Pergamon Press).
	42	! All droplets smaller than the treated one are represented by
	43	! one droplet with mean features. Collision efficiencies are taken
	44	! from the respective table in Rogers and Yau.
	45	! Hall kernel: Kernel from Hall (1980, J. Atmos. Sci., 2486-2507), which
	46	! considers collision due to pure gravitational effects.
	47	! Wang kernel: Beside gravitational effects (treated with the Hall-kernel) also
	48	! the effects of turbulence on the collision are considered using
	49	! parameterizations of Ayala et al. (2008, New J. Phys., 10,
	50	! 075015) and Wang and Grabowski (2009, Atmos. Sci. Lett., 10,
	51	! 1-8). This kernel includes three possible effects of turbulence:
	52	! the modification of the relative velocity between the droplets,
	53	! the effect of preferential concentration, and the enhancement of
	54	! collision efficiencies.
	55	!------------------------------------------------------------------------------!
	56
	57	USE arrays_3d
	58	USE cloud_parameters
	59	USE constants
	60	USE control_parameters
	61	USE cpulog
	62	USE grid_variables
	63	USE indices
	64	USE interfaces
	65	USE lpm_collision_kernels_mod
	66	USE particle_attributes
	67
	68	IMPLICIT NONE
	69
	70	INTEGER :: eclass, i, ii, inc, is, j, jj, js, k, kk, n, pse, psi, &
	71	rclass_l, rclass_s
	72
	73	REAL :: aa, bb, cc, dd, delta_r, delta_v, gg, epsilon, integral, lw_max, &
	74	mean_r, ql_int, ql_int_l, ql_int_u, u_int, u_int_l, u_int_u, &
	75	v_int, v_int_l, v_int_u, w_int, w_int_l, w_int_u, sl_r3, sl_r4, &
	76	x, y
	77
	78	TYPE(particle_type) :: tmp_particle
	79
	80
	81	CALL cpu_log( log_point_s(43), 'lpm_droplet_coll', 'start' )
	82
	83	DO i = nxl, nxr
	84	DO j = nys, nyn
	85	DO k = nzb+1, nzt
	86	!
	87	!-- Collision requires at least two particles in the box
	88	IF ( prt_count(k,j,i) > 1 ) THEN
	89	!
	90	!-- First, sort particles within the gridbox by their size,
	91	!-- using Shell's method (see Numerical Recipes)
	92	!-- NOTE: In case of using particle tails, the re-sorting of
	93	!-- ---- tails would have to be included here!
	94	psi = prt_start_index(k,j,i) - 1
	95	inc = 1
	96	DO WHILE ( inc <= prt_count(k,j,i) )
	97	inc = 3 * inc + 1
	98	ENDDO
	99
	100	DO WHILE ( inc > 1 )
	101	inc = inc / 3
	102	DO is = inc+1, prt_count(k,j,i)
	103	tmp_particle = particles(psi+is)
	104	js = is
	105	DO WHILE ( particles(psi+js-inc)%radius > &
	106	tmp_particle%radius )
	107	particles(psi+js) = particles(psi+js-inc)
	108	js = js - inc
	109	IF ( js <= inc ) EXIT
	110	ENDDO
	111	particles(psi+js) = tmp_particle
	112	ENDDO
	113	ENDDO
	114
	115	psi = prt_start_index(k,j,i)
	116	pse = psi + prt_count(k,j,i)-1
	117
	118	!
	119	!-- Now apply the different kernels
	120	IF ( ( hall_kernel .OR. wang_kernel ) .AND. &
	121	use_kernel_tables ) THEN
	122	!
	123	!-- Fast method with pre-calculated efficiencies for
	124	!-- discrete radius- and dissipation-classes.
	125	!
	126	!-- Determine dissipation class index of this gridbox
	127	IF ( wang_kernel ) THEN
	128	eclass = INT( diss(k,j,i) * 1.0E4 / 1000.0 * &
	129	dissipation_classes ) + 1
	130	epsilon = diss(k,j,i)
	131	ELSE
	132	epsilon = 0.0
	133	ENDIF
	134	IF ( hall_kernel .OR. epsilon * 1.0E4 < 0.001 ) THEN
	135	eclass = 0 ! Hall kernel is used
	136	ELSE
	137	eclass = MIN( dissipation_classes, eclass )
	138	ENDIF
	139
	140	DO n = pse, psi+1, -1
	141
	142	integral = 0.0
	143	lw_max = 0.0
	144	rclass_l = particles(n)%class
	145	!
	146	!-- Calculate growth of collector particle radius using all
	147	!-- droplets smaller than current droplet
	148	DO is = psi, n-1
	149
	150	rclass_s = particles(is)%class
	151	integral = integral + &
	152	( particles(is)%radius*3 &
	153	ckernel(rclass_l,rclass_s,eclass) * &
	154	particles(is)%weight_factor )
	155	!
	156	!-- Calculate volume of liquid water of the collected
	157	!-- droplets which is the maximum liquid water available
	158	!-- for droplet growth
	159	lw_max = lw_max + ( particles(is)%radius*3 &
	160	particles(is)%weight_factor )
	161
	162	ENDDO
	163
	164	!
	165	!-- Change in radius of collector droplet due to collision
	166	delta_r = 1.0 / ( 3.0 * particles(n)%radius*2 ) &
	167	integral * dt_3d * ddx * ddy / dz
	168
	169	!
	170	!-- Change in volume of collector droplet due to collision
	171	delta_v = particles(n)%weight_factor &
	172	* ( ( particles(n)%radius + delta_r )**3 &
	173	- particles(n)%radius**3 )
	174
	175	IF ( lw_max < delta_v .AND. delta_v > 0.0 ) THEN
	176	!-- replace by message call
	177	PRINT*, 'Particle has grown to much because the', &
	178	' change of volume of particle is larger', &
	179	' than liquid water available!'
	180
	181	ELSEIF ( lw_max == delta_v .AND. delta_v > 0.0 ) THEN
	182	!-- can this case really happen??
	183	DO is = psi, n-1
	184
	185	particles(is)%weight_factor = 0.0
	186	particle_mask(is) = .FALSE.
	187	deleted_particles = deleted_particles + 1
	188
	189	ENDDO
	190
	191	ELSEIF ( lw_max > delta_v .AND. delta_v > 0.0 ) THEN
	192	!
	193	!-- Calculate new weighting factor of collected droplets
	194	DO is = psi, n-1
	195
	196	rclass_s = particles(is)%class
	197	particles(is)%weight_factor = &
	198	particles(is)%weight_factor - &
	199	( ( ckernel(rclass_l,rclass_s,eclass) * particles(is)%weight_factor &
	200	/ integral ) * delta_v )
	201
	202	IF ( particles(is)%weight_factor < 0.0 ) THEN
	203	WRITE( message_string, * ) 'negative ', &
	204	'weighting factor: ', &
	205	particles(is)%weight_factor
	206	CALL message( 'lpm_droplet_collision', '', &
	207	2, 2, -1, 6, 1 )
	208
	209	ELSEIF ( particles(is)%weight_factor == 0.0 ) &
	210	THEN
	211
	212	particles(is)%weight_factor = 0.0
	213	particle_mask(is) = .FALSE.
	214	deleted_particles = deleted_particles + 1
	215
	216	ENDIF
	217
	218	ENDDO
	219
	220	ENDIF
	221
	222	particles(n)%radius = particles(n)%radius + delta_r
	223	ql_vp(k,j,i) = ql_vp(k,j,i) + particles(n)%weight_factor &
	224	* particles(n)%radius**3
	225
	226	ENDDO
	227
	228	ELSEIF ( ( hall_kernel .OR. wang_kernel ) .AND. &
	229	.NOT. use_kernel_tables ) THEN
	230	!
	231	!-- Collision efficiencies are calculated for every new
	232	!-- grid box. First, allocate memory for kernel table.
	233	!-- Third dimension is 1, because table is re-calculated for
	234	!-- every new dissipation value.
	235	ALLOCATE( ckernel(prt_start_index(k,j,i): &
	236	prt_start_index(k,j,i)+prt_count(k,j,i)-1, &
	237	prt_start_index(k,j,i): &
	238	prt_start_index(k,j,i)+prt_count(k,j,i)-1,1:1) )
	239	!
	240	!-- Now calculate collision efficiencies for this box
	241	CALL recalculate_kernel( i, j, k )
	242
	243	DO n = pse, psi+1, -1
	244
	245	integral = 0.0
	246	lw_max = 0.0
	247	!
	248	!-- Calculate growth of collector particle radius using all
	249	!-- droplets smaller than current droplet
	250	DO is = psi, n-1
	251
	252	integral = integral + particles(is)%radius*3 &
	253	ckernel(n,is,1) * &
	254	particles(is)%weight_factor
	255	!
	256	!-- Calculate volume of liquid water of the collected
	257	!-- droplets which is the maximum liquid water available
	258	!-- for droplet growth
	259	lw_max = lw_max + ( particles(is)%radius*3 &
	260	particles(is)%weight_factor )
	261
	262	ENDDO
	263
	264	!
	265	!-- Change in radius of collector droplet due to collision
	266	delta_r = 1.0 / ( 3.0 * particles(n)%radius*2 ) &
	267	integral * dt_3d * ddx * ddy / dz
	268
	269	!
	270	!-- Change in volume of collector droplet due to collision
	271	delta_v = particles(n)%weight_factor &
	272	* ( ( particles(n)%radius + delta_r )**3 &
	273	- particles(n)%radius**3 )
	274
	275	IF ( lw_max < delta_v .AND. delta_v > 0.0 ) THEN
	276	!-- replace by message call
	277	PRINT*, 'Particle has grown to much because the', &
	278	' change of volume of particle is larger', &
	279	' than liquid water available!'
	280
	281	ELSEIF ( lw_max == delta_v .AND. delta_v > 0.0 ) THEN
	282	!-- can this case really happen??
	283	DO is = psi, n-1
	284
	285	particles(is)%weight_factor = 0.0
	286	particle_mask(is) = .FALSE.
	287	deleted_particles = deleted_particles + 1
	288
	289	ENDDO
	290
	291	ELSEIF ( lw_max > delta_v .AND. delta_v > 0.0 ) THEN
	292	!
	293	!-- Calculate new weighting factor of collected droplets
	294	DO is = psi, n-1
	295
	296	particles(is)%weight_factor = &
	297	particles(is)%weight_factor - &
	298	( ckernel(n,is,1) / integral * delta_v * &
	299	particles(is)%weight_factor )
	300
	301	IF ( particles(is)%weight_factor < 0.0 ) THEN
	302	WRITE( message_string, * ) 'negative ', &
	303	'weighting factor: ', &
	304	particles(is)%weight_factor
	305	CALL message( 'lpm_droplet_collision', '', &
	306	2, 2, -1, 6, 1 )
	307
	308	ELSEIF ( particles(is)%weight_factor == 0.0 ) &
	309	THEN
	310
	311	particles(is)%weight_factor = 0.0
	312	particle_mask(is) = .FALSE.
	313	deleted_particles = deleted_particles + 1
	314
	315	ENDIF
	316
	317	ENDDO
	318
	319	ENDIF
	320
	321	particles(n)%radius = particles(n)%radius + delta_r
	322	ql_vp(k,j,i) = ql_vp(k,j,i) + particles(n)%weight_factor &
	323	* particles(n)%radius**3
	324
	325	ENDDO
	326
	327	DEALLOCATE( ckernel )
	328
	329	ELSEIF ( palm_kernel ) THEN
	330	!
	331	!-- PALM collision kernel
	332	!
	333	!-- Calculate the mean radius of all those particles which
	334	!-- are of smaller size than the current particle and
	335	!-- use this radius for calculating the collision efficiency
	336	DO n = psi+prt_count(k,j,i)-1, psi+1, -1
	337
	338	sl_r3 = 0.0
	339	sl_r4 = 0.0
	340
	341	DO is = n-1, psi, -1
	342	IF ( particles(is)%radius < particles(n)%radius ) &
	343	THEN
	344	sl_r3 = sl_r3 + particles(is)%weight_factor &
	345	* particles(is)%radius**3
	346	sl_r4 = sl_r4 + particles(is)%weight_factor &
	347	* particles(is)%radius**4
	348	ENDIF
	349	ENDDO
	350
	351	IF ( ( sl_r3 ) > 0.0 ) THEN
	352	mean_r = ( sl_r4 ) / ( sl_r3 )
	353
	354	CALL collision_efficiency_rogers( mean_r, &
	355	particles(n)%radius, &
	356	effective_coll_efficiency )
	357
	358	ELSE
	359	effective_coll_efficiency = 0.0
	360	ENDIF
	361
	362	IF ( effective_coll_efficiency > 1.0 .OR. &
	363	effective_coll_efficiency < 0.0 ) &
	364	THEN
	365	WRITE( message_string, * ) 'collision_efficien' , &
	366	'cy out of range:' ,effective_coll_efficiency
	367	CALL message( 'lpm_droplet_collision', 'PA0145', 2, &
	368	2, -1, 6, 1 )
	369	ENDIF
	370
	371	!
	372	!-- Interpolation of ...
	373	ii = particles(n)%x * ddx
	374	jj = particles(n)%y * ddy
	375	kk = ( particles(n)%z + 0.5 * dz ) / dz
	376
	377	x = particles(n)%x - ii * dx
	378	y = particles(n)%y - jj * dy
	379	aa = x2 + y2
	380	bb = ( dx - x )2 + y2
	381	cc = x2 + ( dy - y )2
	382	dd = ( dx - x )2 + ( dy - y )2
	383	gg = aa + bb + cc + dd
	384
	385	ql_int_l = ( (gg-aa) * ql(kk,jj,ii) + (gg-bb) * &
	386	ql(kk,jj,ii+1) &
	387	+ (gg-cc) * ql(kk,jj+1,ii) + ( gg-dd ) * &
	388	ql(kk,jj+1,ii+1) &
	389	) / ( 3.0 * gg )
	390
	391	ql_int_u = ( (gg-aa) * ql(kk+1,jj,ii) + (gg-bb) * &
	392	ql(kk+1,jj,ii+1) &
	393	+ (gg-cc) * ql(kk+1,jj+1,ii) + (gg-dd) * &
	394	ql(kk+1,jj+1,ii+1) &
	395	) / ( 3.0 * gg )
	396
	397	ql_int = ql_int_l + ( particles(n)%z - zu(kk) ) / dz *&
	398	( ql_int_u - ql_int_l )
	399
	400	!
	401	!-- Interpolate u velocity-component
	402	ii = ( particles(n)%x + 0.5 * dx ) * ddx
	403	jj = particles(n)%y * ddy
	404	kk = ( particles(n)%z + 0.5 * dz ) / dz ! only if eqist
	405
	406	IF ( ( particles(n)%z - zu(kk) ) > (0.5*dz) ) kk = kk+1
	407
	408	x = particles(n)%x + ( 0.5 - ii ) * dx
	409	y = particles(n)%y - jj * dy
	410	aa = x2 + y2
	411	bb = ( dx - x )2 + y2
	412	cc = x2 + ( dy - y )2
	413	dd = ( dx - x )2 + ( dy - y )2
	414	gg = aa + bb + cc + dd
	415
	416	u_int_l = ( (gg-aa) * u(kk,jj,ii) + (gg-bb) * &
	417	u(kk,jj,ii+1) &
	418	+ (gg-cc) * u(kk,jj+1,ii) + (gg-dd) * &
	419	u(kk,jj+1,ii+1) &
	420	) / ( 3.0 * gg ) - u_gtrans
	421	IF ( kk+1 == nzt+1 ) THEN
	422	u_int = u_int_l
	423	ELSE
	424	u_int_u = ( (gg-aa) * u(kk+1,jj,ii) + (gg-bb) * &
	425	u(kk+1,jj,ii+1) &
	426	+ (gg-cc) * u(kk+1,jj+1,ii) + (gg-dd) * &
	427	u(kk+1,jj+1,ii+1) &
	428	) / ( 3.0 * gg ) - u_gtrans
	429	u_int = u_int_l + ( particles(n)%z - zu(kk) ) / dz &
	430	* ( u_int_u - u_int_l )
	431	ENDIF
	432
	433	!
	434	!-- Same procedure for interpolation of the v velocity-com-
	435	!-- ponent (adopt index k from u velocity-component)
	436	ii = particles(n)%x * ddx
	437	jj = ( particles(n)%y + 0.5 * dy ) * ddy
	438
	439	x = particles(n)%x - ii * dx
	440	y = particles(n)%y + ( 0.5 - jj ) * dy
	441	aa = x2 + y2
	442	bb = ( dx - x )2 + y2
	443	cc = x2 + ( dy - y )2
	444	dd = ( dx - x )2 + ( dy - y )2
	445	gg = aa + bb + cc + dd
	446
	447	v_int_l = ( ( gg-aa ) * v(kk,jj,ii) + ( gg-bb ) * &
	448	v(kk,jj,ii+1) &
	449	+ ( gg-cc ) * v(kk,jj+1,ii) + ( gg-dd ) * &
	450	v(kk,jj+1,ii+1) &
	451	) / ( 3.0 * gg ) - v_gtrans
	452	IF ( kk+1 == nzt+1 ) THEN
	453	v_int = v_int_l
	454	ELSE
	455	v_int_u = ( (gg-aa) * v(kk+1,jj,ii) + (gg-bb) * &
	456	v(kk+1,jj,ii+1) &
	457	+ (gg-cc) * v(kk+1,jj+1,ii) + (gg-dd) * &
	458	v(kk+1,jj+1,ii+1) &
	459	) / ( 3.0 * gg ) - v_gtrans
	460	v_int = v_int_l + ( particles(n)%z - zu(kk) ) / dz &
	461	* ( v_int_u - v_int_l )
	462	ENDIF
	463
	464	!
	465	!-- Same procedure for interpolation of the w velocity-com-
	466	!-- ponent (adopt index i from v velocity-component)
	467	jj = particles(n)%y * ddy
	468	kk = particles(n)%z / dz
	469
	470	x = particles(n)%x - ii * dx
	471	y = particles(n)%y - jj * dy
	472	aa = x2 + y2
	473	bb = ( dx - x )2 + y2
	474	cc = x2 + ( dy - y )2
	475	dd = ( dx - x )2 + ( dy - y )2
	476	gg = aa + bb + cc + dd
	477
	478	w_int_l = ( ( gg-aa ) * w(kk,jj,ii) + ( gg-bb ) * &
	479	w(kk,jj,ii+1) &
	480	+ ( gg-cc ) * w(kk,jj+1,ii) + ( gg-dd ) * &
	481	w(kk,jj+1,ii+1) &
	482	) / ( 3.0 * gg )
	483	IF ( kk+1 == nzt+1 ) THEN
	484	w_int = w_int_l
	485	ELSE
	486	w_int_u = ( (gg-aa) * w(kk+1,jj,ii) + (gg-bb) * &
	487	w(kk+1,jj,ii+1) &
	488	+ (gg-cc) * w(kk+1,jj+1,ii) + (gg-dd) * &
	489	w(kk+1,jj+1,ii+1) &
	490	) / ( 3.0 * gg )
	491	w_int = w_int_l + ( particles(n)%z - zw(kk) ) / dz &
	492	* ( w_int_u - w_int_l )
	493	ENDIF
	494
	495	!
	496	!-- Change in radius due to collision
	497	delta_r = effective_coll_efficiency / 3.0 &
	498	* pi * sl_r3 * ddx * ddy / dz &
	499	* SQRT( ( u_int - particles(n)%speed_x )**2 &
	500	+ ( v_int - particles(n)%speed_y )**2 &
	501	+ ( w_int - particles(n)%speed_z )**2 &
	502	) * dt_3d
	503	!
	504	!-- Change in volume due to collision
	505	delta_v = particles(n)%weight_factor &
	506	* ( ( particles(n)%radius + delta_r )**3 &
	507	- particles(n)%radius**3 )
	508
	509	!
	510	!-- Check if collected particles provide enough LWC for
	511	!-- volume change of collector particle
	512	IF ( delta_v >= sl_r3 .AND. sl_r3 > 0.0 ) THEN
	513
	514	delta_r = ( ( sl_r3/particles(n)%weight_factor ) &
	515	+ particles(n)%radius3 )( 1./3. ) &
	516	- particles(n)%radius
	517
	518	DO is = n-1, psi, -1
	519	IF ( particles(is)%radius < &
	520	particles(n)%radius ) THEN
	521	particles(is)%weight_factor = 0.0
	522	particle_mask(is) = .FALSE.
	523	deleted_particles = deleted_particles + 1
	524	ENDIF
	525	ENDDO
	526
	527	ELSE IF ( delta_v < sl_r3 .AND. sl_r3 > 0.0 ) THEN
	528
	529	DO is = n-1, psi, -1
	530	IF ( particles(is)%radius < particles(n)%radius &
	531	.AND. sl_r3 > 0.0 ) THEN
	532	particles(is)%weight_factor = &
	533	( ( particles(is)%weight_factor &
	534	* ( particles(is)%radius**3 ) ) &
	535	- ( delta_v &
	536	* particles(is)%weight_factor &
	537	* ( particles(is)%radius**3 ) &
	538	/ sl_r3 ) ) &
	539	/ ( particles(is)%radius**3 )
	540
	541	IF ( particles(is)%weight_factor < 0.0 ) THEN
	542	WRITE( message_string, * ) 'negative ', &
	543	'weighting factor: ', &
	544	particles(is)%weight_factor
	545	CALL message( 'lpm_droplet_collision', '', &
	546	2, 2, -1, 6, 1 )
	547	ENDIF
	548	ENDIF
	549	ENDDO
	550
	551	ENDIF
	552
	553	particles(n)%radius = particles(n)%radius + delta_r
	554	ql_vp(k,j,i) = ql_vp(k,j,i) + &
	555	particles(n)%weight_factor * &
	556	( particles(n)%radius**3 )
	557	ENDDO
	558
	559	ENDIF ! collision kernel
	560
	561	ql_vp(k,j,i) = ql_vp(k,j,i) + particles(psi)%weight_factor &
	562	* particles(psi)%radius**3
	563
	564
	565	ELSE IF ( prt_count(k,j,i) == 1 ) THEN
	566
	567	psi = prt_start_index(k,j,i)
	568	ql_vp(k,j,i) = particles(psi)%weight_factor * &
	569	particles(psi)%radius**3
	570	ENDIF
	571
	572	!
	573	!-- Check if condensation of LWC was conserved during collision
	574	!-- process
	575	IF ( ql_v(k,j,i) /= 0.0 ) THEN
	576	IF ( ql_vp(k,j,i) / ql_v(k,j,i) >= 1.0001 .OR. &
	577	ql_vp(k,j,i) / ql_v(k,j,i) <= 0.9999 ) THEN
	578	WRITE( message_string, * ) 'LWC is not conserved during',&
	579	' collision! ', &
	580	'LWC after condensation: ', &
	581	ql_v(k,j,i), &
	582	' LWC after collision: ', &
	583	ql_vp(k,j,i)
	584	CALL message( 'lpm_droplet_collision', '', 2, 2, -1, 6, 1 )
	585	ENDIF
	586	ENDIF
	587
	588	ENDDO
	589	ENDDO
	590	ENDDO
	591
	592	CALL cpu_log( log_point_s(43), 'lpm_droplet_coll', 'stop' )
	593
	594
	595	END SUBROUTINE lpm_droplet_collision

Note: See TracBrowser for help on using the repository browser.

Download in other formats:

| Impressum | ©Leibniz Universität Hannover |