VIMARLOW EHA-L37L37-R01-L1 Thermal energy harvesting demo unit water to water Datasheet

marlow industries, inc. 
Subsidiary of II-VI INCORPORATED
TECHNICAL DATA SHEET
Preliminary
EHA-LXXLXX-R01-L1
Thermal Energy Harvesting Demo Unit
Water to Water
Min ∆Tsys (°C)
N
TYPICAL PERFORMANCE VALUES
2.0
2.3V
3.3V
4.1V
5.0V
0.4
0.6
0.7
0.8
2.9
3.8
4.5
5.1
TI
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P at 5°C ∆Tsys (mW)
P at 35°C ∆Tsys (mW)
C
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D
O
EPR
TYPICAL PERFORMANCE CURVES
Marlow’s EH series offers a range of source-to-application, thermoelectric-based energy harvesting systems for evaluation
and testing. Each system integrates a Marlow electrically-matched, thermally- optimized custom thermoelectric generator
and heat sink with a Linear Technology LTC series voltage step-up converter to provide the customer with tools and
flexibility necessary to evaluate a wide range of test conditions. The EHA-LXXLXX-R01-L1 is designed to harvest power
from the temperature difference between warm and cool fluid streams.
ORDERING OPTIONS
Model Number
EHA-L37L37-R01-L1
EHA-L50L50-R01-L1
Description
For pipe
diameter
9.5mm[.375”]
For pipe
diameter
12.7mm[0.5”]
PR
CONTACT US:
For customer support or general questions please contact a local office below or consult our website for distributor information.
Marlow Industries, Inc.
10451 Vista Park Road
Dallas Texas 75238-1645
214-340-4900 (tel)
214-341-5212 (fax)
www.marlow.com
Marlow Industries Europe GmbH
Brunnenweg 19-21
64331 Weiterstadt
Germany
Tel.: +49 (0) 6150 5439 - 403
Fax: +49 (0) 6150 5439 - 400
[email protected]
II-VI Japan Inc.
WBG Marive East 17F
2-6 Nakase, Mihama-ku
Chiba-Shi, Chiba 261-7117
Japan
81 43 297 2693 (tel)
81 43 297 3003 (fax)
[email protected]
www.ii-vi.co.jp
II-VI Singapore Pte., Ltd.
Blk. 5012, Techplace II
#04-07 & 05-07/12, Ang Mo Kio Ave. 5
Singapore 569876
(65) 6481 8215 (tel)
(65) 6481 8702 (fax)
[email protected]
www.ii-vi.com.sg
DOC # 102-0389 REV 3 - PAGE 1 OF 4
Marlow Industries China, II-VI Technologies Beijing
A subsidiary of II-VI Incorporated
Rm 202, 1# Lize 2nd Middle Road
Wangjing, Chaoyang District
Beijing 100102 China
010-64398226 ext 105 (tel)
010-64399315 (fax)
[email protected]
For more information please see:
http://www.marlow.com/power-generators/energyharvesting-solutions/
EHA-L37L37-R01-L1 or EHA-L50L50-R01-L1
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IMPORTANT NOTE:
Output from the EH-A-LXXLXX-R01-L1 is strongly a
function of heat source, ambient temperature, and
electrical load downstream of the converter.
Data
given on this sheet is representative of typical system
performance under steady-state flow and thermal
conditions and is intended for selecting the appropriate
EH series assembly. The data should not be taken as
comprehensive or representative of every operating
condition. For further information about or questions
regarding the EHA-LXXLXX-R01-L1, please contact a
Marlow applications engineer.
AVAILABLE MODIFICATIONS
Marlow can custom design the EH system to maximize power
output, or to meet size, form factor, or temperature
constraints for any thermal energy harvesting application. In
special cases, Marlow can customize units to accommodate
DOC # 102-0389 REV 3 - PAGE 2 OF 4
9.5
34.4
EHA-L37L37-R01-L1
12.7
40.4
EHA-L50L50-R01-L1
TI
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PIN FUNCTIONS
WIRE HARNESS PINOUT
OPERATION CAUTIONS:
For maximum reliability, continuous operation below
85°C is recommended. Do not attempt to disassemble
without contacting a Marlow engineer. Doing so could
result in permanent damage to the TG or other system
components.
Model Number
alternating temperature difference or a reverse temperature
difference. Contact an application engineer for more
information.
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CONTENTS:
1 EHA-LXXLXX-R01-L1 Assembly, 1
Wire Harness
B
(mm)
U
Dimensions are in Millimeters
INSTALLATION:
Assembly should be mounted to hot and cold fluid lines
using the provided mounting brackets and M 3 bolts
with a maximum torque of 5.0 in-lbs.
A layer of
graphite has been adhered to the pipe mounting surface
on the EHA-LXXLXX-R01-L1 to ensure a good thermal
contact between the mounting pipe and the EHA
assembly. Performance will vary greatly with ambient
conditions. For best results, insulate the fluid lines
feeding into the assembly. During installation, observe
precautions for handling electrostatic sensitive devices.
A
(mm)
N
MECHANICAL
DRAWING
MECHANICAL DRAWING
WIRE
COLOR
FUNCTION
PIN
RED
VOUT
1
BLACK
GND1
2
WHITE
VLDO
3
BROWN
GND2
4
GREY
PGD
5
GREEN
VSTORE
6
BLUE
TCOLD
7
ORANGE
TCOLD
8
YELLOW
THOT
9
PURPLE
THOT
10
VOUT (PIN 1)
Main output of the converter. The voltage at this pin is
regulated to the voltage selected by VS1 and VS2. To select
an output voltage, change the jumper locations at VS1 and
VS2 on the board according to the VOUT Options table below.
Pin 1 may be connected to an auxiliary capacitor. A 220μF
capacitor is already connected to this pin. See Application
Notes sections of this datasheet for more information.
EHA-L37L37-R01-L1 or EHA-L50L50-R01-L1
of the TEG can affect temperatures. It is recommended that
the
user
place
and
monitor
external
thermocouples/thermisters/RTD’s on both the heat source
and heat sink (or ambient conditions) in addition to
monitoring the on-board thermistors.
Vout OPTIONS
VS1
VS2
VOUT
GND
GND
2.35V
VAUX
GND
3.3V
GND
VAUX
4.1V
VAUX
VAUX
5V
T 
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PGD (PIN 5)
Power good output that monitors the VOUT voltage. The PGD
output is designed to drive a microprocessor or other chip I/O
and is not intended to drive a higher current load such as an
LED. When VOUT is within 7.5% of its programmed value, PGD
will be pulled up to VLDO through a 1MΩ resistor. If VOUT
drops 9% below its programmed value PGD will go low.
Manufacturer: GE Industrial Sensing (Thermometrics)
PN: A040A-UBCF16XF103X-A
Resistance at 25°C: 10 KOhm +/- 0.20%
β 25/100: 3992 K +/- 1%
298K  3992K 
 3992K

ln 10k  R  
 298K 
 ln 10k  R 



C
VLDO (PIN 3)
Output of the 2.2V Low Drop Out (LDO). The LTC3108
includes a low current LDO to provide a regulated 2.2V output
for powering low power processors and other low power ICs.
The LDO output is current limited to 4mA.
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GND1 (PIN 2), GND2 (PIN 4)
Ground pin.
U
where R is the resistance of the thermistor that you want to
measure and T is the temperature of the thermistor.
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VSTORE (PIN 6)
Output for the storage capacitor or battery. The VSTORE
output can be used to charge a large storage capacitor or
rechargeable battery. The storage element on VSTORE can
be used to power the system in the event that the input
source is lost or is unable to provide the current demanded by
VOUT and LDO output. A large capacitor may be connected
from this pin to GND for powering the system in the event the
input voltage is lost. It will be charged up to 5.25V. Note
that it may take a long time to charge a larger capacitor,
depending on the input energy available and the loading on
VOUT and VLDO. Since the maximum current from VSTORE is
limited to a few milliamps, it can safely be used to tricklecharge NiCd or NiMH rechargeable batteries for energy
storage when the input voltage is lost. Note that the VSTORE
capacitor cannot supply large pulse currents to VOUT. Any
pulse load on VOUT must be handled by the VOUT capacitor. If
not used, this pin should be left open.
THOT, TCOLD (PINS 7-10)
Thermistor leads for hot side and cold side TEG temperatures.
The temperature readings from the on-board thermistors
monitor the hot side and cold side of the embedded TEG. In
application, these temperatures will be different than the
source and sink temperatures used to define the system
temperature difference included in the performance plot. The
following figure shows how thermal resistance on either side
DOC # 102-0389 REV 3 - PAGE 3 OF 4
APPLICATION CIRCUIT
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APPLICATION NOTES
VSTORE
CUSTOMER
ADDITION
+
TEG
VLDO
2.2µF
Converter
VOUT
+
+
220µF
µP
SENSORS
PGD
RF LINK
GND
VOUT and VSTORE Capacitor
For pulsed load applications, the VOUT capacitor should be
sized to provide the necessary current when the load is
pulsed on. The capacitor value required will be dictated by
the load current, the duration of the load pulse, and the
amount of voltage drop the circuit can tolerate. The capacitor
must be rated for the voltage selected for VOUT by VS1 and
VS2.
Cout   F  
ILoad  mA  tPulse  ms 
VOUT V 
∆ VOUT is the maximum allowable voltage drop on VOUT. Note
that there must be enough energy available from the input
voltage source for VOUT to recharge the capacitor during the
interval between load pulses. Reducing the duty cycle of the
EHA-L37L37-R01-L1 or EHA-L50L50-R01-L1
load pulse will allow operation with less input energy.
The VSTORE capacitor may be a very large value (thousands
of microfarads or even Farads), to provide holdup at times
when the input power may be lost. Note that this capacitor
may charge to 5.25V (regardless of the settings for VOUT), so
ensure that the holdup capacitor has a working voltage rating
of at least 5.5V at the temperature for which it will be used.
The VSTORE capacitor can be sized using the following:
In many pulsed load applications, the duration, magnitude
and frequency of the load current bursts are known and fixed.
In these cases the charge current required from the LTC3108
to support average load must be calculated, by the following:
IBurst t
T
N
U
ICHG  IQ 
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O
where 6μA is the quiescent current of the LTC3108, IQ is the
load on VOUT in between bursts, ILDO is the load on the LDO
between bursts, IBURST is the total load during the burst, t is
the duration of the burst, f is the frequency of the burst,
TSTORE is the storage time required, and VOUT is the output
voltage required. Note that for a programmed output voltage
of 5V, the VSTORE capacitor cannot provide any beneficial
storage time. Storage capacitors requiring voltage balancing
are not recommended due to the current draw of the
balancing resistor.
To evaluate operation under electrical load conditions use the
following procedure:
1. Connect the load/battery/capacitor/resistor between
pins 1 and 2 (See image below).
2. Connect a voltmeter across the load.
3. If possible, connect a small resistor or current shunt
in
series
between
pin
1
and
the
load/battery/capacitor/resistor between pins 1 and 2.
Use this shunt to calculate current out of VOUT.
4. Bring the hot side of the assembly to the desired
temperature by raising the source temperature and
monitoring the hot side thermistor via pins 9 and 10
on the wire harness.
5. Measure the voltage drop across the load
device/resistor and the current from the shunt. Use
voltage and current to calculate power.
6. Check the calculated power against the performance
curve plot on page 1.
C
6  A  IQ  ILDO   IBurst t  f  TStore

CStore  
5.25  VOUT
SET-UP TIPS
O
D
where IQ is the sleep current on VOUT required by the external
circuitry in between bursts (including cap leakage), IBURST is
the total load current during the burst, t is the time duration
of the burst and T is the period of the transmit burst rate
(essentially the time between bursts).
The EHA-LXXLXX-R01-L1 is now ready for further evaluation
in your application. If you have any questions on this test
procedure or how to test the unit in your application, please
contact a Marlow application engineer for further assistance.
For more information, please refer to the Contact Us section
of this datasheet.
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To assess your thermal interface between the EHA-LXXLXXR01-L1 and your hot and cold fluid lines and estimate your
expected maximum current, follow these procedures to
measure your short circuit current:
1. Connect a 200Ω resistor in series between pins 1 and
2.
2. Connect a voltmeter across the 200Ω resistor.
3. Bring the hot side of the assembly to the desired
temperature by raising the source temperature and
monitoring the hot side thermistor via pins 9 and 10
on the wire harness.
Note that pins 9 and 10
measure the hot side of the TEG and not the source
temperature.
There could be several degrees
difference between TSOURCE and THOT, so Marlow
recommends mounting a thermocouple to the source
to independently monitor TSOURCE. If the discrepancy
is greater than 5°C, there may be thermal interface
or mounting issues and Marlow recommends
remounting the EHA-LXXLXX-R01-L1.
4. Allow the assembly temperature to stabilize and
measure the voltage drop across the resistor.
5. Convert the voltage to a current using I=V/R.
6. Check that the short circuit current matches closely
with the performance curve plot on page 1.
DOC # 102-0389 REV 3 - PAGE 4 OF 4
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