Magnetic observatories have traditionally used small buildings or huts to provide stable and temperature controlled

environments for housing sensitive magnetometer instruments. As magnetometer technology has developed, instruments

have reduced in size and become less reliant on mechanical pier stability, whilst still relying on adequate temperature

control. Temperature control in large, older, buildings can be challenging and expensive due to their volume, thermal

losses and undefined thermal properties of construction materials. This report describes a modern instrument housing

comprising a small-scale enclosure and low-power, non-magnetic heating element controlled by a

proportional–integral–derivative (PID) temperature controller. Operating magnetometers in a compact environment

requires careful selection of heating elements and minimising any sources of local interference. The specifications,

thermal calculations, materials and temperature control system for the enclosure are presented with results of long term

temperature stability and overall performance in comparison with traditional observatory housings. The disadvantages

and benefits of operating instruments in small enclosures are also discussed

Flower, S.

Shanahan, T.

Turbitt, C.

Magnetic observatories have traditionally used small buildings or huts to provide a stable, protected and temperature controlled environment to accommodate the sensitive magnetic instruments. As instruments have evolved they have reduced in size and become less reliant on absolute mechanical stability but still require good temperature stability. Maintaining a stable temperature

in large older buildings can be difficult and expensive due to their volume, the substantial thermal losses and undefined thermal properties of the construction materials.



This report describes a modern instrument housing comprising a small-scale enclosure and low-power, non-magnetic heating elements controlled by a proportional–integral–derivative (PID) temperature controller. Operating magnetometers in a compact environment with other equipment requires careful selection of heating elements and minimising any sources of local interference. The specifications and calculations for the enclosure design, materials and temperature control system are presented with results of long term temperature stability performance in comparison with traditional observatory housings. The

disadvantages and benefits of operating instruments in small enclosures are also discussed

Shanahan, Thomas

Turbitt, Christopher

Flower, Simon

NERC Open Research Archive

XVth IAGA WORKSHOPON GEOMAGNETIC OBSERVATORY INSTRUMENTS,DATA ACQUISITION AND PROCESSING (San Fernando, Cádiz, Spain, June 4th – 14th, 2012)Experiences in Designing a Low-cost Temperature Controlled Variometer EnclosureThomas Shanahan (tjgs@bgs.ac.uk), Christopher Turbitt, Simon FlowerBritish Geological Survey, West Mains Road, Edinburgh EH9 3LA, United KingdomAbstractAcknowledgments ReferencesRalph Plastics Fabrication Services - Construction of the fibre-glass Enclosure  [1] Requirements for Electrical Installations, Wiring Regulations 16th  Edition (BS7671:2001), The Institution of Electrical Engineers and British Standards Institute, The IEE, London, 2004. [2] Eurotherm 2404 Installation & Operation Handbook, Issue 10.0, Eurotherm, 2004.ConclusionsMagnetic observatories have traditionally used small buildings or huts to provide a stable, protected and temperature controlled environment to accommodate the sensitive magnetic instruments. As instruments have evolved they have reduced in size and become less reliant on absolute mechanical stability but still require good temperature stability. Maintaining a stable temperature in large older buildings can be difficult and expensive due to their volume, the substantial thermal losses and undefined thermal properties of the construction materials. This report describes a modern instrument housing comprising a small-scale enclosure and low-power, non-magnetic heating elements controlled by a proportional–integral–derivative (PID) temperature controller. Operating magnetometers in a compact environment with other equipment requires careful selection of heating elements and minimising any sources of local interference. The specifications and calculations for the enclosure design, materials and temperature control system are presented with results of long term temperature stability performance in comparison with traditional observatory housings. The disadvantages and benefits of operating instruments in small enclosures are also discussed.Temperature StabilityTo assess the performance of the enclosure, both the short-term and long-term temperature stability of the system has to be considered. Figure 2 shows the 2011 variation in the enclosure measured at the sensor head (green trace). The lower traces show the external temperature extremes for each day ( . This long-term plot shows the PID controller is maintaining the temperature over the year to within about 2 °C of the set-point and that this variation is manifest as a long-period deviation.Figure 3 is a statistical view of the daily (or short-term) temperature stability of the system. The histogram indicates that for 358 days of the year (98%) the temperature in the enclosure (1-minute samples) did not deviate by more than 1 °C from the set-point. This was during a period where, the average daily external variation was 4.2 °C and the maximum daily variation was 11.0 °C. annual range of 21.1 °C)Enclosure ConstructionIntroductionPID Temperature ControllerThe British Geological Survey (BGS) operates three UK magnetic observatories and five overseas. The UK observatory buildings were originally designed to accommodate larger instruments and as a result have become an inefficient use of space and heat for housing modern instruments; Eskdalemuir observatory requires over 4 kW of heating to maintain the temperature in the building that houses the primary instrument. The BGS operates Danish Meteorological Institute (DMI) FGE fluxgate magnetometers for all of its variometers.BGS has developed a new low-cost enclosure which is currently used to operate backup variometer systems at Lerwick, Hartland and Eskdalemuir. This type of enclosure is also used to house the variometer at the re-established observatory in South Georgia. To quantify performance of the new enclosure, a comparison was carried out between the primary (GDAS1) variometer at Lerwick (which continues to use the older style of building) and the new enclosure that houses a backup variometer (GDAS2), for 2011 data.  Design of the new enclosure focussed on minimising the volume and heating requirements whilst still ensuring a stable & magnetically clean operating environment for long-term magnetic recordings. FoundationsThe foundations for the enclosure are formed from a shallow raft (0.2 m) of non-magnetic cement. This construction provides adequate stability providing the fluxgate sensor has tilt-compensation.Enclosure Materials The enclosure is fabricated from a two layer fibre-glass wall with a 15 mm polystyrene core for insulation. This combination gives the structure strength and durability whilst still remaining light enough to transport by hand.  InsulationThe inside walls and floor of the enclosure are clad with 75 mm, foil-backed polyure-thane insulation panels to further reduce heat loss and all seams are sealed with sili-cone rubber to minimise heat loss through air exchange. LayoutThe fluxgate electronics and heater are located at the opposite end of the enclosure from the sensor to provide maximum separa-tion and promote a more stable temperature gradient across the sensor. The sensor is mounted directly on the concrete raft through a gap in the insulation to provide better stability from wind vibration on the main structure. External DimensionsHeight: 1.5 m, Width:  1.0  m, Length: 2.0 m (tapered sides to reduce wind vibration).QualityExperience from operating the temperature control system shows the PID controller typically drives the heater load with a duty cycle of between 30-60 % over most of the year. This equates to roughly 50-100 Watts nominal power consumption which roughly agrees with the predicted thermodynamic performance of the system and the observed external temperature gradients for 2011 at Lerwick. The data quality analysis establishes that the new enclosure successfully provides a low noise environment for making high quality magnetic recordings and that any long-term temperature variations are being adequately modelled by the  baselines used to produce final data.Observationshe concrete raft can be susceptible to tilt in locations where the soil is particularly soft and this was seen at Lerwick when a fault developed with the fluxgate sensor tilt-compensator. Daily drift was seen primarily in the H and D components until the sensor suspension system was repaired. Due to the low thermal mass of the enclosure, temperature over-ranging can occur in the summer months; a solution to this would be to bank earth around the sides of the enclosure which would also allow a lower set-point to be used.In general, suspended magnetometer sensors don’t require pillars mounted on bedrock and a shallow raft of concrete provides sufficient stability, reducing the cost and installation time. However, tThermal Loss CalculationsPerformanceControl SystemThe enclosure temperature is regulated using a Eurotherm 2404 PID process controller. The controller proportions power to a non-magnetic heating element in the enclosure via a TE10S solid state relay and 220 VAC to 48 VAC step down transformer (Figure 1). Switching RelayThe TE10S relay employs zero-volt switching to ensure that the AC supply is only triggered on and off at zero points in the sine-wave cycle. This prevents harmonics of the supply frequency being generated (a possible source of noise in the variometer) and also extends the operating life of the heater element by reducing high-frequency currents. For optimal performance, the three PID control parameters need to be tuned to the operating environment and the response time of the system. The Eurotherm 2404 does this by initiating a tuning cycle that forces the temperature in the enclosure to oscillate, allowing it to determine the ideal PID settings [2].Low-voltage SupplyThe 48V AC supply is used to implement Separated Extra Low Voltage (SELV) protection from electric shock [1]. SELV permits un-armored power cables, due to the lower voltage and electrical isolation offered by the transformer. This relaxes the power cable specifications and prevents introducing magnetic contamination due to steel armouring. Due to the lower voltage, low resistance 2cables have to be used (minimum of 2.5 mm ) to reduce line losses.(on set-up) Given the simple construction and materials of the enclosure, it is possible to estimate the thermal loss characteristics of the system. Here heat loss is dominated by a combi-nation of conduction and natural ventilation (air change). Radiation losses are negligible due to the low emissivity foil on all inside surfaces.Conductive LossesThe rate of heat lost due to conduction (dQc/dt) is related to the material thermal con-ductivity (k), surface area (A), temperature gradient (∆T) & material thickness (x) by equation 1. For a wall construction using a combination of different materials and thick-nesses, a total thermal resistance (R-value) can be determined by combining the individ-ual thermal resistance values for each layer of material (equation 2 & 3). The total ther-mal resistance of the enclosure walls and floor is summarised in Table 1.The total thermal transmittance (U ) for the enclosure construction is the reciprocal of the t2 2total thermal resistance (0.243 W/m K and 0.290  W/m K for the walls and floor respec-tively). The thermal transmittance values allow calculation of the combined conductive losses using equation 4. Air ExchangeThe heat lost via natural ventilation (dQv/dt) is calculated  as the rate of ther-mal energy lost due to air exchanges (N), for the volume of space being heated (V), volu-metric heat capacity of air at 20 °C (C ) and the temperature gradient (∆T). vAssuming a set-point temperature of 20 °C, winter external temperature of -10 °C,  3  2 2enclosure volume of approximately 3 m ,wall area of 11 m , floor area of 2 m , 3C = 1.297 kJ/m /K and a conservative 1 air exchange per hour, the total predicted vthermal losses can be summarised in Table 2. Due to the low thermal losses, a low-power heating system can be designed to run from lower voltages, simplifying many aspects of the enclosure design.(equation 5)Material x (mm) km (W/mK) Rv (m2K/W) Fibre-glass 03 mm 0.04 0.075 Polystyrene 15 mm 0.03 0.500 Fibre-glass 03 mm 0.04 0.075 Insulation board 75 mm n/a 3.450  Total walls: 96 mm n/a 4.100 Total floor: 75 mm n/a 3.450  Data Quality ComparisonTo quantify the quality of the new enclosure (GDAS2), a comparison of the final data was carried out using the primary recording system at Lerwick observatory (GDAS1). Comparing the variometers in this way gives a measure of the total system performance taking into account any possible sources of contamination, noise or instability at the new enclosure. Figures 4, 5 & 6 show the final data quality of this system compares well to the primary system. Over 95% of minute samples from 2011 differ by less than +/- 0.5 nT in the Horizontal (H) and Vertical (V) magnetic components.Type Rate of Thermal Loss Conductive (walls) 80.5 W Conductive (floor) 17.4 W Ventilation 32.4 W Total: 130.3 W      (1)        (2)   (3)      (4)      (5) Table 1 Thermal Resistance of Enclosure MaterialsTable 2 Thermal Losses Summary050000100000150000200000250000051015202530354045-0.40 -0.35 -0.30 -0.25 -0.20 -0.15 -0.10 -0.05 0.00 0.05 0.10 0.15 0.20 0.25 0.30 0.35 0.40No. of 1-min Samples% of Samples (2011 Data)Component Difference (arc -mins)D Differences (LER GDAS1-GDAS2) - 2011Declination Differences050000100000150000200000250000051015202530354045-1.0 -0.9 -0.8 -0.7 -0.6 -0.5 -0.4 -0.3 -0.2 -0.1 0.0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1.0No. of 1-min Samples% of Samples (2011 Data)Component Difference (nT)H Difference (GDAS1-GDAS2) - 2011H Difference (GDAS1 -GDAS2)050000100000150000200000250000051015202530354045-1.0 -0.9 -0.8 -0.7 -0.6 -0.5 -0.4 -0.3 -0.2 -0.1 0.0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1.0No. of 1-min Samples% Samples (2011 Data)Component Difference (nT)Z Differences (GDAS1-GDAS2) - 2011Z Differences (GDAS1 -GDAS2)01020304050600501001502002503000.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5 6.0 6.5 7.0 7.5 8.0 8.5 9.0 9.5External No. of DaysEnclosure No. of DaysDaily Range (Deg. C)Lerwick (LER) Daily Temperature Ranges (2011)Enclosure RangeExternal Range-15-10-5051015202530Jan-2011 Feb-2011 Mar-2011 Apr-2011 May-2011 Jun-2011 Jul-2011 Aug-2011 Sep-2011 Oct-2011 Nov-2011 Dec-2011Temperature (Deg. C)DateLerwick Daily Temperature Variations (2011)External (maximum)External (minimum)Enclosure (daily average)240 VAC to 48 VACTransformerPt100Temp.Sensor160 W HeaterElementEurothermTE10SSSREurotherm 2404 PIDControllerController 19” Rack Variometer Enclosure48 VAC (50 Hz)240 VAC (50 Hz)Low Voltage DC~ 80 m Cable RunDC Duty Cycle (PID)AC Duty Cycle (SSR)Figure 1 Enclosure Temperature Control System SchematicFigure 5 Declination Comparison Histogram for 2011Figure 2 Long-term Temperature Stability Figure 3 Daily Temperature StabilityRequirementsA non-magnetic and non-inductive heater is essential when the magnetometer and heater are in such close proximity. Sourcing commercial non-magnetic, low-voltage, heaters is a common problem so BGS chose to construct bespoke heater elements specifically for this application. ConstructionThe heating element comprises four Vishay 50 W (56 Ohm) thick-film power resistors mounted on 1.3 °C/W  anodised aluminium heat sinks. The heat sinks are then mounted in a standard 19” aluminium rack vented rack enclosure with all magnetic parts removed. The use of standard parts simplified fabrication and future proofs availability of components whilst keeping the cost of the system low.Driving the heating element at 48 VAC and with small line losses produces a maximum power output of approximately 160 Watts. The magnetic ‘signature’ of the heater is undetectable at distances > 0.5 m from the variometer sensor. This type of heater has proved to be very reliable over the long-term, having been operated at several of the BGS observatories for a number of years without failure.Non-magnetic HeaterFigure 6 Vertical Comparison Histogram for 2011Figure 4 Horizontal Comparison Histogram for 2011

English

Experiences in designing a low-cost temperature controlled variometer enclosure

65   EXPERIENCES IN DESIGNING A LOW-COST TEMPERATURE CONTROLLED VARIOMETER ENCLOSURE  T. Shanahan (1), C. Turbitt (1), S. Flower (1)  (1) British Geological Survey, Murchison House, West Mains Road, Edinburgh, EH9 3LA, UK, tjgs@bgs.ac.uk SUMMARY Magnetic observatories have traditionally used small buildings or huts to provide stable and temperature controlled environments for housing sensitive magnetometer instruments. As magnetometer technology has developed, instruments have reduced in size and become less reliant on mechanical pier stability, whilst still relying on adequate temperature control. Temperature control in large, older, buildings can be challenging and expensive due to their volume, thermal losses and undefined thermal properties of construction materials. This report describes a modern instrument housing comprising a small-scale enclosure and low-power, non-magnetic heating element controlled by a proportional–integral–derivative (PID) temperature controller. Operating magnetometers in a compact environment requires careful selection of heating elements and minimising any sources of local interference. The specifications, thermal calculations, materials and temperature control system for the enclosure are presented with results of long term temperature stability and overall performance in comparison with traditional observatory housings. The disadvantages and benefits of operating instruments in small enclosures are also discussed.   1. INTRODUCTION The British Geological Survey (BGS) operates three magnetic observatories in the UK and four overseas. The original observatory buildings were designed to accommodate larger instruments and as a result have become inefficient for housing modern instruments; Eskdalemuir observatory requires over 4 kW of heating to maintain the temperature in the building that houses the primary instrument.  The BGS operates Danish Technical University (DTU) FGE fluxgate magnetometers for all of its variometers. BGS has developed a new low-cost enclosure which is currently used to house backup variometer systems at Lerwick, Hartland and Eskdalemuir. This type of enclosure is also used at the recently re-established observatory on the island of South Georgia. To quantify performance of the new enclosure, a comparison was carried out between the primary variometer (GDAS1) at Lerwick (which continues to use the old-style of building for instruments) and the new enclosure that houses a backup variometer (GDAS2), for 2011 data. Design of the new enclosure focussed on minimising the volume and heating requirements whilst still ensuring a stable, magnetically clean and low-noise environment for long-term magnetic recordings. 2. CONSTRUCTION The foundations for the enclosure are formed from a shallow raft (0.5 m) of non-magnetic concrete (all materials were tested for magnetic ‘hygiene’ before construction). This construction provides adequate stability, providing the fluxgate sensor has a tilt-compensation system. The enclosure is fabricated from a two-layer fibre-glass wall with a 15 mm polystyrene core of insulation. This combination gives the structure strength and durability whilst still remaining light enough to transport by hand. The inside walls and floor of the enclosure are clad with 75 mm, foil-backed polyurethane insulation panels to further reduce heat loss and all seams are sealed with silicone rubber to minimise heat loss through air exchange. The fluxgate electronics and heater are located at the opposite end of the enclosure from the sensor to reduce interference and promote a more stable temperature gradient across the sensor block. The fluxgate sensor is mounted directly on the concrete raft through a gap in the insulation to de-couple any wind vibration on the main structure from the instrument. The external dimensions of the enclosure are: Height: 1.5 m, Width: 1.0 m, Length: 2.0 m (tapered sides to reduce wind vibration). 66   3. THERMAL STABILITY Given the simple construction and materials of the enclosure, it is possible to calculate the thermal loss characteristics of the system. The thermal characteristics are dominated by a combination of conductive and convective (air change) heat losses. Radiation losses are negligible due to the low emissivity foil on all inside surfaces. The rate of heat lost due to conduction (dQc/dt) is related to the material thermal conductivity (k), surface area (A), temperature gradient (ΔT) & material thickness (x) by equation 1. For a wall construction using a combination of different materials and thicknesses, a total thermal resistance (R-value) can be determined by combining the individual thermal resistance values for each layer of material (equation 2 & 3). The total thermal resistance of the enclosure walls and floor is summarised in Table 1 (the R-value for the insulation board was provided by the manufacturer’s specifications).  xTAkdtdQ mc Δ= (1) mv kxR = (2) vnvv RRR ++= ...1 (3) Table 1 – Total Thermal Resistance Value Material Usage x (mm) km (W/mK) Rv (m2K/W) Fibre-glass Wall 03 0.040 0.075 Polystyrene Wall 15 0.030 0.500 Fibre-glass Wall 03 0.040 0.075 Insulation board Wall & floor 75 - 3.450 Total walls: - 96 - 4.100 Total floor: - 75 - 3.450  The total thermal transmittance (Ut) for the enclosure construction is the reciprocal of the total thermal resistance (0.243 W/m2K and 0.290 W/m2K for the walls and floor respectively). The thermal transmittance values allow calculation of the combined conductive losses (equation 4). The heat lost via convection or natural ventilation (dQv/dt) is calculated (equation 5) as the rate of thermal energy lost due to air exchanges (N), for the volume of space being heated (V), volumetric heat capacity of air at 20 °C (Cv) and the temperature gradient (ΔT). TAUdtdQtc Δ= (4) TNVCdtdQvv Δ= (5)  Assuming a set-point temperature of 20 °C, winter external temperature of -10 °C, enclosure volume of approximately 3 m3, wall area of 11 m2, floor area of 2 m2, Cv = 1.297 kJ/m3/K and a conservative 1 air exchange per hour (N), the total predicted thermal losses can be summarised in Table 2. A result of the low thermal losses (<140 W) is that a low-power heating system can be designed to run from lower voltages, simplifying many aspects of the enclosure design. Table 2 – Total Thermal Losses at 20 °C Internal, -10 °C External Loss Type Rate of Thermal Loss (W) Conductive (walls) 80.5 Conductive (floor) 17.4  Ventilation 32.4  Total: 130.3  67   4. HEATING ELEMENT A non-magnetic and non-inductive heater is essential when the magnetometer and heater are in such close proximity. Sourcing commercial non-magnetic, low-voltage, heaters is a common problem so BGS chose to construct tailored heater elements specifically for this application. The heating element comprises four Vishay 50 W (56 Ohm) thick-film power resistors mounted in parallel on 1.3 °C/W anodised aluminium heat sinks. The heat sinks are then mounted in a standard 19” aluminium vented rack with all magnetic parts removed. The use of standard parts simplifies fabrication and future proofs availability of components whilst keeping the cost low. Powering the heating element at 48 VAC (RMS), produces a maximum power output of 160 Watts. The magnetic susceptibility of the heater is undetectable at distances > 0.5 m from the variometer sensor. This type of heater has proved to be very reliable over the long-term, having been operated at several of the BGS observatories without failure. 5. PID CONTROLLER The enclosure temperature is regulated using a Eurotherm 2404 PID process controller. The controller proportions power to the non-magnetic heating element in the enclosure via a TE10S solid state relay (SSR), and step down (220 VAC to 48 VAC) transformer (Figure 1). The TE10S relay ensures zero-voltage switching to ensure that the supply is switched on and off at zero points in the AC cycle. Zero-voltage switching prevents harmonics of the supply frequency being generated (a common source of noise) and also extends the operating life of the heater element by reducing high-frequency currents. For optimal performance, the PID control parameters are tuned, on installation, to the operating environment and response time of the system. The Eurotherm 2404 does this using a tuning cycle that forces the temperature in the enclosure to oscillate, allowing it to determine the ideal PID settings [2]. The 48V AC supply is chosen for safety to provide Separated Extra Low Voltage (SELV) protection from electric shock [1]. SELV permits un-armored power cables, due to the low voltage and electrical isolation provided by the transformer. This relaxes the power cable specifications and prevents introducing magnetic contamination associated with steel armored cable.    Figure 1 –Temperature Control System for Enclosure 6. PERFORMANCE To assess the performance of the enclosure, both the short-term and long-term temperature stability of the system have to be considered. Figure 2 is a statistical view of the temperature stability of the new enclosure. The histogram shows that for 358 days of the year (98%) the temperature in the enclosure (1-minute samples) did not deviate by more than 1 °C from the chosen set-point. This was during a period where, the average external daily range was 4.2 °C and the maximum daily range was 11.0 °C.  To quantify the quality of the new variometer enclosure (GDAS2), a comparison of the final data was carried out using the primary recording system at Lerwick observatory (GDAS1), with the assumption that this is a low-noise and stable (temperature & baselines) reference system. Comparing the variometer data in this way gives a measure of the total system performance taking into account any possible sources of contamination, noise or instability of the new enclosure. Figures 3 show the final data quality of this system compares well to the primary system with over 95% of minute samples from 2011 differing by less than +/- 0.5 nT in the Horizontal (H) and Vertical (V) components and +/- 0.5 arc-mins in Declination (D). 68    Figure 2 –Daily Temperature Stability of New Enclosure for Lerwick (2011)   Figure 3 –Comparison of Primary & New Enclosure Variometer Systems for Lerwick (2011) 7. CONCLUSIONS In general, tilt-compensated fluxgate sensors don’t require pillars mounted on bedrock, and a shallow raft of concrete provides sufficient stability, reducing the cost and installation time. However, the concrete raft can be susceptible to excessive tilt in locations where the soil is particularly soft, and this was briefly seen at Lerwick when a fault developed with the sensor tilt-compensator; a situation that would not typically affect more traditional installations.  Experience from operating the temperature control system shows the PID controller typically drives the heating element with a duty cycle of between 30-60 % over most of the year and has always been able to deliver sufficient power over the coldest periods. This equates to 50-100 Watts nominal power consumption which agrees well with the modelled thermodynamic performance of the system and the observed temperature variations (external) for 2011 at Lerwick. Due to the low thermal mass of the enclosure, temperature over-ranging can occur in the summer, but this could be reduced by adding more thermal mass to the system by banking earth around the enclosure. The data quality analysis confirms that the low-cost enclosure successfully provides a low-noise environment for making high quality magnetic recordings and that any long-term temperature variations are being adequately removed by the baselines used to produce the final data.  9. REFERENCES [1] British Standards Institute, The IEE. (2004): "Requirements for Electrical Installations". Wiring Regulations 16th Edition (BS7671:2001). [2] Eurotherm. (2004): "Eurotherm 2404 Installation & Operation Handbook, Issue 10.0". 

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Experiences in designing a low-cost temperature controlled variometer enclosure

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