Simulation Research on Hot Bulb Anemometer Under Low Pressure

Xiyuan Li

1,2

, Xiaofang Yin

, Qinghua Gao

, Qiong Li

and Jing Wang

Beijing Institute of Spacecraft Environment Engineering, Beijing 100094, China

Beihang University, Beijing 100191, China

lxy_422@msn.com

Keywords: Low pressure, CFD, Hot bulb anemometer, Convection heat transfer.

Abstract: In the Mars exploration, the atmosphere and wind speed on the surface of Mars result in the difference in heat

transfer between Mars rover and general earth orbit spacecraft. In addition to solar radiation and infrared

radiation, surface heat conduction and convection heat transfer of the atmosphere are the primary heat transfer

forms on the surface of Mars. In order to correct the thermal model of Mars rover and verify the ability of

thermal control system to maintain the system at working temperature under extreme thermal environment,

the low pressure and wind speed environment of Mars surface should be simulated in the Mars rover test.

Therefore, the wind speed should be measured on multiple positions in the thermal test under low pressure.

The dynamic, thermal and ultrasonic anemometers have the problems such as small signal, low precision and

need to be recalibrated under low pressure. A numerical simulation model for constant heat flow hot bulb

anemometer under low pressure has been established by CFD method. The response characteristics at low

pressure are analyzed by the model. A test system was built in space environment simulation chamber to

verify the simulation. Test and CFD method reach a similar result, which proves the validity of the analysis.

1 INTRODUCTION

The atmospheric pressure on the surface of Mars is

about 700Pa, and the gas is dominated by carbon

dioxide, with a surface temperature of about -120~20 ℃

. At the same time, there is a 0-15m/s wind speed on

the surface of Mars, which causes the heat exchange

environment on the surface of Mars being different

from that of the earth orbit environment. To achieve

the purpose of thermal model correction, early fault

screening, and performance testing in extreme

environment, hardware developer usually prefers to

test the rover in a more realistic simulation

environment The pressure, thermal boundary and

wind speed is required to be simulated in thermal

test(Ransome et al., 2001, Johnson). The simulation

of low pressure and thermal boundary can be

achieved by the space environment simulation

chamber and its inner heat sink. Meanwhile, the wind

speed should be simulated and measured under low

pressure. The commonly used methods of wind speed

measurement in the industry include dynamic

pressure measurement, thermal measurement, and

ultrasonic measurement.

The dynamic pressure measurement calculates the

dynamic pressure via the difference between the total

pressure and the static pressure of the fluid. The

dynamic pressure is only related to the density of the

gas and the fluid velocity. The advantage of dynamic

pressure wind speed measurement is that the velocity

conversion formula is explicit. However, its

limitation is also very obvious. With the decrease of

gas density, the dynamic pressure will decrease

rapidly correspondingly. When measuring the 0-

15m/s wind speed in the 700Pa environment, the

resolution of pressure measurement should reach at

least 0.1Pa. Although the laboratory micro pressure

sensor can meet the requirements of its measurement

accuracy, its volume and weight are often challenging

to achieve the requirement of measuring the

multipoint wind speed in the limited space of the

space environment simulation chamber(Wilson,

2003). The principle of the thermal anemometer is

that the convection heat transfer coefficient increases

gradually with the rise of the wind speed (Bruun,

Li, X., Yin, X., Gao, Q., Li, Q. and Wang, J.

Simulation Research on Hot Bulb Anemometer Under Low Pressure.

In 3rd International Conference on Electromechanical Control Technology and Transportation (ICECTT 2018), pages 487-491

ISBN: 978-989-758-312-4

487

1995). Thermal anemometer has serval advantages

including simple structure and lightweight(Numata et

al., 2011, Chamberlain et al., 1976). Its disadvantage,

however, is that the exact analytical solution of

convection heat transfer characteristics can hardly be

obtained. Thus, the thermal anemometer can be

measured accurately only when it has been fully

recalibrated under the operating environment.

Thermal anemometer has been carried on a variety of

Mars lander and rover while all of them are

customized products (Seiff et al., 1997). The central

principle of ultrasonic wind speed measurement is

that the sound velocity is only related to the local gas

composition and temperature. However, the

ultrasonic signal highly attenuates at low

pressure(Kapartis, 1999). As a result, industrial

products cannot be directly used for wind speed

measurement under low pressure. It is often essential

to optimize the ultrasonic anemometer from software

and hardware(Banfield et al., 2012) .

To sum up, in the field of Mars and stratospheric

wind speed measurement, the sensors used are all

customized products. This paper aims to use

industrial products in wind speed measurement under

low pressure. A constant heat flow hot bulb heat

transfer model has been established by CFD method,

which was used to analyses probe response under

different pressure. The result has been verified by a

test system which was built in space environment

simulation chamber. The simulation analysis and test

have obtained a similar result, which demonstrates

the correctness of the analysis and provides a

reference for future related test.

2 HEAT TRANSFER MODEL

2.1 CFD model

The hot bulb probe used in this paper is a ceramic

encapsulated sphere with a diameter of 0.6mm. It has

internal heating wire and thermocouple hot junction,

and the cold junction of the thermocouple is located

outside the hot bulb.

Spherical ceramic encapsulated

Thermocouple cold-juction

Thermocouple hot-juction

Heating wire

Support Structure

Support wire

Figure 1: hot ball probe model.

When the hot bulb anemometer works, a constant

heat flow is produced on the ceramic bulb. With

different wind speed, the surface of the sphere also

has a different convective heat transfer coefficient.

When radiation and conduction heat transfer are tiny,

the heat lost through the surface of the sphere

approximately equals to the heat flow of the electric

heating wire

ower

==( ) ( )

se se

QIRShTTS TT

−= −

Where

owerP

is heat generate by the heating

wire(W), can be calculated by the current (A) and

resistance (Ω),

S is bulb surface area(m

is the

sphere temperature (K),

is the ambient

temperature (K),

is convection heat transfer

coefficient (W/m

·C), can be expressed by Nusselt

number, Thermal conductivity

(W/m·℃), and

characteristic length

(m). The Nusselt number can

be expressed by a function of Reynolds number (

), the temperature difference between the hot bulb and

environment can be calculated by a function of the

thermoelectric potential (

), the equation can be

simplified to:

=()()

Nu t

Svl

IR f f V

As shown above, the hot bulb output signal and

the wind speed V can be one-to-one correspondences

when the environment parameters are known

precisely. Through experiments, Kramers, Whitaker,

Yuge, Vilet, Raithby and other scholars have given

various Nu-Re empirical formula for spheres.

However, almost most of the formula has more than

50% of the error in the low Reynolds number range

(0.1-100) (Dennis et al., 2006). Therefore, it is

difficult to predict the response of the hot bulb wind

probe at low pressure by dimensionless number

analysis method.

In this paper, a 2-dimensional model of constant

heat flow hot bulb anemometer under low pressure

has been established by CFD simulation. The

axisymmetric swirl model was selected to simulate

the axisymmetric flow field. The flow field grid is

shown in Figure 2.

Figure 2: CFD simulation mode.

ICECTT 2018 - 3rd International Conference on Electromechanical Control Technology and Transportation

488

Because the whole flow field is low-speed flow,

the Incompressible ideal gas model has been chosen

to calculate the density. The k-omega model and

surface to surface model were selected to simulate the

turbulence flow and radiation heat transfer. The

boundary conditions are shown below:

Table 1: Boundary conditions.

Position Boundary condition

Symmetric axis Axis

Sphere surface Wall，constant heat flux

Inlet Velocity Inlet

Outlet Outflow

Outer boundary Moving Wall

Velocity= Inlet Velocity

2.2 Grid independence analysis

In order to minimize the errors caused by the grid in

the analysis, the multiple cases with different grid

numbers have been calculated in this paper. The

convection heat transfer coefficient and the surface

average Nusselt number are analyzed to evaluate the

grid. The result is shown below:

Table 2 Grid independence analysis.

Cells Convective heat transfer

coefficient(W/

·℃)

Average Nusselt n

umber

1656 98.12764 4054.861

3256 98.64166 4076.101

6346 98.85119 4084.76

12534 98.81493 4083.262

24592 98.86643 4085.39

As shown in the table, when the number of cells

is over 6000, the change of heat transfer results is very

little. In the model with 6000 cells, the errors caused

by mesh can be ignored in the CFD simulation. The

velocity and temperature distribution around the hot

bulb probe are shown below.

Figure 3: the velocity and temperature distribution.

2.3 Test verification

In order to verify the CFD model of the hot bulb

anemometer, a wind speed calibration system based

on rotation has been built in this paper. The rotating

platform and cantilever were installed inside a

medium-size space environment simulation chamber.

The rotating platform drives the cantilever to rotate at

a set speed to simulate the different wind speed

around the probe, and the medium-size space

environment simulation chamber provides the

different pressure environment for the test.

At the same time, the millivolt signal transmitter

installed on the turntable can measure the signal of

the probe and transmit it to the computer outside the

chamber by RS-485. The schematic diagram of the

calibration system is shown below.

Probe

Rotating platform

mV measurement

space environment simulation chamber

cantilever

Figure 4: Calibration system.

The total power of the hot bulb probe used in this

paper is 0.08W, which contains the heat lost on the

bulb and the cables or wires. The relationship

between total power and probe output voltage can be

simplified to:

1ower

=( )

Pse

C Q Sh T T Sh

−=

Where

C is the ratio of the hot bulb power to the

total power. Because the resistance changes little, it

can be considered as a constant.

C is the sensitivity

of the thermocouple (mV/ C),

S is the surface

area(m

owerP

Q is the total power(W). When the

sensitivity of the thermocouple varies little within the

range of use, the convection heat transfer coefficient

should be inversely proportional to the output

thermoelectric potential.

Through the experiments under different

pressures, the output thermal potential of the hot bulb

probe at 1-15m/s has been recorded. The convection

heat transfer coefficient calculated by the CFD

method is multiplied by thermal potential

respectively. The result is shown in Figure 5.

Simulation Research on Hot Bulb Anemometer Under Low Pressure

489

0 2 4 6 8 10 12 14 16

1000

1200

1400

1600

1800

2000

2200

2400

2600

2800

3000

101325Pa

40000Pa

700Pa

Potential×convective heat transfer coefficient

(mV·W/m

·K)

Wind Speed(m/s)

Figure 5: thermal potential·heat transfer coefficient.

As shown in Figure 5, the experimental thermal

potential·CFD calculated heat transfer coefficient is

approximately constant. The fluctuation is less than

10%, and the value in ambient pressure is very close

to the 40000Pa result. However, in the case of 700Pa,

the error is about 20%, which is similar to the result

of literature(Numata et al., 2011), it is mainly because

the Nu-Re empirical correlation will also change

under very low pressure.So that, there is a non-

ignorable error in calculating the output of a thermal

anemometer by simulation, and the result should be

corrected with experimental methods.

After solving the coefficient, the probe signal can

be predicted by the CFD simulation, the predicted

output and test result have been compared, as shown

in Figure 6.

0246810121416

Test Result 101325Pa

Test Result 40000Pa

Test Result 700Pa

CFD Result 101325Pa

CFD Result 40000Pa

CFD Result 700Pa

Thermlelectric Potential(mV)

Wind Speed(m/s)

Figure 6: Test result and CFD calculation.

As shown in Figure 6, the response of the constant

heat flow hot bulb anemometer in the environment

above 40000Pa can be efficiently estimated by CFD

simulation. However, for the incredibly low-pressure

environment, especially for the low wind speed

environment, the model should be corrected by the

experimental data. The main reason of the deviation

includes the deviation of the heat transfer calculation,

the larger error of the pressure measurement under

low pressure, the more significant error of the

turntable at low speed, and the more massive natural

convection caused by the higher temperature.

Meanwhile, the sensitivity of the hot bulb probe is

about 0.01~0.2mv/(m/s). When the test is carried out

at low pressure, the Voltage signal data acquisition

hardware should also meet the accuracy requirement.

3 CONCLUSIONS

This paper aims at the problem of wind speed

measurement under low pressure. A heat transfer

model for constant heat flow hot bulb probe has been

established by CFD simulation method. A test system

has been built in space environment simulation

chamber to verify the probe output model. The

simulation model and the experiment have obtained

the similar result under ambient pressure and

40000Pa. The heat transfer model builds in this paper

can be directly applied to constant heat flow hot bulb

under 40000Pa or higher pressure, and can be used to

700Pa environment through experimental data

correction. The model can be used to evaluate the

output of hot bulb sensors in different environments,

and provide a reference for future related test.

REFERENCES

BANFIELD, D., GIERASCH, P. J., TOIGO, A., DISSLY,

R., DAGLE, W. R., SCHINDEL, D., HUTCHINS, D.

& KHURIYAKUB, B. T. 2012. Mars Acoustic

Anemometer.

BRUUN, H. H. 1995. Hot-Wire Anemometry. Oxford Univ

Pr.

CHAMBERLAIN, T. E., COLE, H. L., DUTTON, R. G.,

GREENE, G. C. & TILLMAN, J. E. 1976. Atmospheric

measurements on Mars - The Viking meteorology

experiment. Bulletin of the American Meteorological

Society, 57.

DENNIS, S. C. R., WALKER, J. D. A. & HUDSON, J. D.

2006. Heat transfer from a sphere at low Reynolds

numbers. Journal of Fluid Mechanics, 60, 273-283.

JOHNSON, K. Simulation of Mars Surface conditions for

Characterization of the Mars Rover Thermal Response.

KAPARTIS, S. S. R. 1999. Wind speed and direction

measurement using Acoustic Resonance airflow

sensing. FT Technologies.

NUMATA, D., ANYOJI, M., SUGINO, Y., NAGAI, H. &

ASAI, K. 2011. Characteristics of Thermal

Anemometers at Low-Pressure Condition in a Mars

Wind Tunnel.

RANSOME, T., PESKET, S. & TOPLIS, G. Thermal

Balance Testing of the Beagle2 Mars Lander.

International Symposium Environmental Testing for

Space Programmes, 2001.

SEIFF, A., TILLMAN, J. E., MURPHY, J. R.,

SCHOFIELD, J. T., CRISP, D., BARNES, J. R.,

LABAW, C., MAHONEY, C., MIHALOV, J. D. &

ICECTT 2018 - 3rd International Conference on Electromechanical Control Technology and Transportation

490

WILSON, G. R. 1997. The atmosphere structure and

meteorology instrument on the Mars Pathfinder lander.

Journal of Geophysical Research Planets, 102, 4045–

4056.

WILSON, C. F. 2003. Measurement of wind on the surface

of Mars. Doctor of Philosophy, Oxford.

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