Vermes Seal Element

Description

The Vermes Seal element is typically used to model flow through labyrinth seals found in rotating machinery (gas turbines). The flowrate, swirl, and fluid temperature rise due to windage is calculated based on the seal geometry, and fluid conditions at the inlet and exit of the seal.

The seal clearance is the main dimension that controls the flowrate passing through the seal. It is the distance between the tip of the seal tooth and the opposite surface which is usually honeycomb. The seal clearance changes during gas turbine operation since the parts move due to temperature and rotation.

The Vermes seal element is based on the method of calculation of flow through labyrinth seals proposed in the paper by Geza Vermes (ref 1.)

The element is typically used for compressible flow, but Flow Simulator can use this element with incompressible or compressible fluid.

Quick Guide for Vermes Seal Creation in the GUI

Vermes seal can be found under the “Compressible Gas Elements” - “Seals” section

The figure below shows the geometric inputs. The seal clearance is the besides the geometric inputs the user needs to enter honeycomb information

A Vermes seal typically has the seal teeth rotating. This requires the user to enter an RPM reference condition in the Solution Panel.

Vermes Seal Inputs

Table of the inputs for the Vermes seal. See the image in the user interface to help understand geometric variables.

Vermes Seal Element Input Variables
Index	UI Name (.flo label)	Description
1	Seal Clearance (CL)	Seal clearance .
2	Nominal Seal Radius or Inlet Radius (RAD)	Nominal seal radius for a straight seal or the inlet radius for a stepped seal.
3	Number of Teeth (NT)	Number of teeth in seal.
4	Seal Axial Pitch (PT)	Seal axial pitch .
5	Tooth Tip Width (WT)	Axial width of seal tooth tip.
6	Seal Tooth Height (HT)	Seal tooth height . This variable influence only the windage calculated for a rotating seal.
7	Wedge Angle (AN)	Angle between sides of a seal tooth .
8	Rotor Surf. Rot. Speed (RPMSELR)	Rotational speed pointer of seal rotor surface. 0.0: Specifies a stationary element. 1.0: Points to general data ELERPM(1). 2.0: Points to general data ELERPM(2). 3.0: Points to general data ELERPM(3).
9	Slant Angle (SL)	Angle the tooth centerline makes with the radial direction. Positive angle if tooth is angled into the flow and negative angle if slanted away from the flow.
10	Land Surf. Rot. Speed (RPMSELL)	Rotational speed pointer of seal land surface. 0.0: Specifies a stationary element. 1.0: Points to general data ELERPM(1). 2.0: Points to general data ELERPM(2). 3.0: Points to general data ELERPM(3).
11	Seal Type (SEAT)	Seal-Seat and Type Flag Seal Type Straight Through Seal Stepped Seal Solid Land (No HC) 1/32” HC cell size 1/16” HC cell size 1/8” HC cell size Straight Teeth Slanted Teeth 1 X   X       X   2 X   X         X 3 X     X     X   4 X     X       X 5   X X       X   6   X X         X 7   X   X     X   8   X   X       X 9 X       X   X   10 X       X     X 11 X         X X   12 X         X   X 13   X     X   X   14   X     X     X 15   X       X X   16   X       X   X
12	Portion of Ustrm Cham. Dyn. Head Lost (DQ_IN)	Inlet dynamic head loss. If DQIN ≥ 0 and the upstream chamber has a positive component of relative velocity aligned with the axis of the tube, the driving pressure will be reduced by the equation: The default value of -1.0 will be interpreted by Flow Simulator as a flag to use only static pressure if the upstream chamber is an inertial chamber and a DQ_IN of 0 if the upstream chamber is a momentum chamber.
13	Element Alignment (AXIS_DIR)	Direction of positive flow through the seal If AXIS_DIR ≥ 0, the axial direction for positive flow is assumed to be the direction defined by THETA = 0, PHI = 0. If AXIS_DIR < 0, the axial direction for positive flow is assumed to be the direction defined by THETA = 180, PHI = 0.
14	Laminar-Transitional Reynolds Number (RE_LAM)	Reynolds number below which pocket swirl flow is assumed to be laminar. Flow at Reynolds numbers between RE_LAM and RE_TURB are assumed to be in the transition region. Defaults to 2070 for Vermes Seal.
15	Turbulent-Transitional Reynolds Number (RE_TURB)	Reynolds number above which pocket swirl flow is assumed to be turbulent. Flow at Reynolds numbers between RE_LAM and RE_TURB are assumed to be in the transition region. Defaults to 2530 for Vermes Seal.
16	Clearance Factor Method (KFAC_METHOD)	0: Bell-Bergelin curve for CD of annular orifice (Default) 1-: User supplies their own KFAC, either constant value or calculated using controllers. See KFAC details below.
17	Kinetic Energy Carryover Method (KE_METHOD)	0: Vermes 1961 Kinetic Energy Carryover curve 1: Morrison Kinetic Energy Carryover curve 2: Minimum of Vermes and Morrison curves (Default, matches NASA Tipton data best) 3: Saikishan-Morrison -1: User supplies their own KEMULT, either constant value or calculated using controllers. See KEMULT details below.
18	Honeycomb Method (HC_METHOD)	1: Stocker/Schramm Method (Default) – Stocker for Straight Seals, Schramm for Stepped Seals -1: User supplies their own HCMULT, either constant value or calculated using controllers. See HCMULT details below.
19	Slanted Teeth Method (SL_METHOD)	1: Curve fitted to NASA Tipton data -1: User supplies their own SLMULT, either constant value or calculated using controllers. See SLMULT details below.
20	Honeycomb Size (HCSIZE)	Honeycomb Size – Standard choices are 1/32”, 1/16”, and 1/8”. However, it is possible to input a custom honeycomb size. Solver units are inches.
21	Clearance Factor (KFAC)	Clearance factor is the Discharge Coefficient of a single annular orifice or tooth gap. The value is between 0 and 1, usually between 0.6 and 0.9. See Vermes 1961 or Bell-Bergelin.
22	Kinetic Energy Carryover Factor (KEMULT)	Kinetic Energy Carryover Factor is a value from 1 to about 2.4. It accounts for axial momentum and energy that is retained as flow goes around a tooth. A value of 1 means the tooth blocked all kinetic energy. A value higher than 1 implies some kinetic energy was carried over. Please see Vermes 1961, Morrison, and Alexiou for details.
23	Honeycomb Flow Multiplier (HCMULT)	Honeycomb Flow Knockdown Factor is a multiplier that is applied to non-honeycomb leakage flow to calculate the corrected leakage flow with a honeycomb stator. Typical values are from 0.8 to 1.2. Values less than one imply the honeycomb is supplying an additional source of resistance, which is often true for straight seals. Values greater than one imply that the honeycomb is creating a new path for leakage flow, which is often true for stepped seals. Please see Stocker and Schramm for additional details.
24	Slant Flow Multiplier (SLMULT)	Slanted Teeth Flow Knockdown Factor is a multiplier that is applied to straight-tooth leakage flow to calculate the corrected leakage flow with slanted teeth. Typical values are from 0.85 to 1.1. Three-dimension flows in seal pockets are complex, and it is difficult to explain why the factor is sometimes less than one and sometimes greater.
25	Swirl Carryover Factor per Tooth (ETATOOTH)	Swirl Carryover per Tooth is the fraction of tangential fluid velocity (relative to the stator) that passes each tooth and enters the next pocket. This is a calibration parameter that helps to match the correct swirl and windage heating. It is especially useful for stepped honeycomb seals where the air passes over the tooth and immediately impinges on the honeycomb step.
26	Friction and Windage – Rotor: Friction Relation (FRIC_REL_R)	0: Swamee-Jain Approximation to Colebrook-White-Moody Friction (Default) 1: MacGreehan-Ko Rotating Cavity/Pocket Friction 5: Sultanian -1: User supplies FRICF_STATOR, either constant value or calculated using controllers. See FRICF_STATOR details below.
27	Rotor Sandgrain Roughness (ROUGH_ROTOR)	Roughness of the rotor surface. It is assumed to be a sand-grain type roughness, which is consistent with Colebrook-White-Moody.
28	Friction and Windage – Rotor: Friction Multiplier (F_MULT_ROTOR)	Friction multiplier on Rotor is used if you want the friction curve to follow that same basic trend as Swamee-Jain or MacGreehan-Ko but your custom friction curve differs by a multiplication factor.
29	Friction and Windage – Rotor: Friction Coefficient (FRICF_ROTOR)	Fanning Friction Coefficient on Rotor can be supplied as a constant value, or it can be calculated using a controller.
30	Friction and Windage – Rotor: Total Rotor Surface Area (ASR)	Generally, ASR=0 and the rotor friction area is calculated from other geometric inputs such as tooth height, spacing, wedge angle, slant angle, etc. If you enter a non-zero value, your input will override the calculated area. Solver units are sq.in.
31	Friction and Windage – Stator: Friction Relation (FRIC_REL_S)	0: Swamee-Jain Approximation to Colebrook-White-Moody Friction (Default) 1: MacGreehan-Ko Rotating Cavity/Pocket Friction 5: Sultanian -1: User supplies FRICF_STATOR, either constant value or calculated using controllers. See FRICF_STATOR details below.
32	Stator Sandgrain Roughness (ROUGH_STATOR)	Roughness of the stator surface. It is assumed to be a sand-grain type roughness, which is consistent with Colebrook-White-Moody. Estimating a suitable roughness for a honeycomb surface is one challenge, but no advice can be given here.
33	Friction and Windage – Stator: Friction Multiplier (F_MULT_STATOR)	Friction multiplier on Stator is used if you want the friction curve to follow that same basic trend as Swamee-Jain or MacGreehan-Ko but your custom friction curve differs by a multiplication factor.
34	Friction and Windage – Stator: Friction Coefficient (FRICF_STATOR)	Fanning Friction Coefficient on Stator can be supplied as a constant value, or it can be calculated using a controller.
35	Friction and Windage – Stator: Total Land Surface Area (ASS)	Generally, ASR=0 and the rotor friction area is calculated from other geometric inputs such as tooth height, spacing, wedge angle, slant angle, etc. If you enter a non-zero value, your input will override the calculated area. This is especially useful for stepped seals, since the current Vermes Seal element does not have a step height input. However, it could be better to ignore the step height and rely on ETATOOTH – please see above. Solver units are sq.in.
36	(CL_TABLE)	Number of entries in the CL_VALUES table.
37	Groove Depth (GRV_DEPTH)	Depth of the groove (GD) in the honeycomb (or other land material)
38	Groove Width (GRV_WIDTH)	Width of the groove (GW) in the honeycomb (or other land material)
39	Groove Tooth Axial Position (GRV_AX)	Location of the tooth in the groove. 0 = tooth in the center of the groove -1 = tooth hitting left edge of groove 1 = tooth hitting right edge of groove Not used in built-in methods yet but can be useful for controller or custom groove loss correlations.
40	Groove Multiplier (GRV_MULT)	Groove Flow Knockdown Factor is a multiplier that is applied to a no-groove leakage flow to calculate the leakage flow with a groove. Can be greater or less than 1. If the tooth is outside the groove, GRV_MULT should be > 1 indicating more flow through the seal.
41	Groove Method (GRV_METHOD)	Method to use to calculate the groove effect. -1 = User Specified GRV_MULT 1 = Zimmerman Method
42	User Multiplier (USRMULT)	A user supplied flow knockdown factor. Can be used with a controller for general purpose effects if needed.
43	Exit Radius (RAD_EX)	The exit radius for a stepped seal.
Table 1	Individual Tooth Clearances (CL_VALUES)	There is an option to provide an array of individual clearance values, one for each seal tooth. The method uses a curve that is fitted to Tisarev, Falaleev, Vinogradov 2014 data, and computes an effective tooth clearance from the array of individual tooth clearance values. Solver units are inches. The following equation is used to calculate and effective clearance for the entire seal.

Vermes Seal Theory

Flow Rate Calculation

For a seal with one tooth, KEMULT=1.0, and BETA is calculated using the flow function. See the BETA section for details.

KEMULT

KFAC

SLMULT

HCMULT

GVRMULT

AREA

BETA

.

Calculation of Seal Pocket Pressure

Calculation of Seal Pocket Swirl

Figure 1.

The seal “rotor” surface area is calculated using the following:

${\alpha }_1=\frac{AN}{2}+SL$

${\alpha }_2=\frac{AN}{2}-SL$

$y_1=\frac{HT}{\mathrm{c}\mathrm{o}\mathrm{s}\left({\alpha }_1\right)}$

$y_2=\frac{HT}{\mathrm{c}\mathrm{o}\mathrm{s}\left({\alpha }_2\right)}$

$x=PT-WT-HT*\tan \left({\alpha }_1\right)-HT*\mathrm{t}\mathrm{a}\mathrm{n}\left({\alpha }_2\right)$

$P_{rot\_pkt}=x+WT+y_1+y_2$

Surface area per pocket: $A_{rs}=2*\pi *{Rad}_{pkt}*P_{rot\_pkt}$

Where: ${Rad}_{pkt}={Rad}_{tooth\_tip}-\frac{HT}{2}$

Surface area for all pockets: $A_{rs\_total}=\sum _1^{num pkt}{A}_{rs}$

The vermes seal “stator” surface area is calculated using the following:

$P_{stat\_pkt}=PT$

Surface area per pocket: $A_{ss}=2*\pi *{Rad}_{stat}*P_{stat\_pkt}$

Where: ${Rad}_{stat}={Rad}_{tooth\_tip}+CL$

Surface area for all pockets: $A_{ss\_total}=\sum _1^{num pkt}{A}_{ss}$

Sultanian Friction (ref 9)

Rotor Surface: $F_R=\frac{0.070*{\left|\beta \right|}^{0.65}}{{Re}^{0.2}*{|\beta -XK|}^{0.65}}$

Stator Surface: $F_S=\frac{0.063}{{Re}^{0.2}*{\left|XK\right|}^{0.13}}$

Calculation of Seal Windage Temperature Rise

Vermes Seal Outputs

Outputs in file with “res” extension. Output units controlled by user setting in “Output Control” panel.

Vermes Seal Validation

The Vermes seal results were compared to results from Tipton et.al. (ref 7).

Vermes Seal References