HAFUHM0050L4AXT - Honeywell Sensing and Control

FEATURES

• Fast response time (1 ms) allows the customer’s application

to respond quickly to a change in airflow, important in

critical medical (e.g., anesthesia) and industrial (e.g., fume

hood) applications.

• High stability reduces errors due to thermal effects and

null shift, providing accurate readings over time and often

eliminating the need for system calibration after PCB mount

and periodically over time.

• High sensitivity at very low flows provides a fast response

time at the onset or cessation of flow.

• High 12-bit resolution increases the ability to sense small

airflow changes, allowing customers to more precisely

control their application.

• Wide airflow range: The industry’s broadest airflow range

measures mass flow with standard flow ranges of 0 to10,

0 to 15, 0 to 20, 0 to 50, 0 to 100, 0 to 200 and 0 SLPM to

300 SLPM, or custom flow ranges, increasing the options to

integrate the sensor into the application.

• Choice of port styles: Manifold mount, 22 mm OD tapered

male fitting, and G 3/8 female threaded fitting provide

flexibility to choose the pneumatic connection that is best

for the customer’s application.

• Linear output provides a more intuitive sensor signal than

the raw output of basic airflow sensors, which can help

reduce production costs, design, and implementation time.

• Wide supply voltage range (3 Vdc to 10 Vdc) provides a

flexible regulated power circuit which allows the designer the

flexibility to choose the supply voltage that works best in the

system.

• ASIC-based I2C digital output simplifies integration

to microprocessors or microcontrollers, reducing PCB

complexity and component count.

• RoHS-compliant materials Meet Directive 2002/95/EC.

POTENTIAL APPLICATIONS

• Medical: Anesthesia delivery machines, ventilators,

ventricular assist devices (heart pumps), spirometers,

laparoscopy

• Industrial: Analytic instrumentation (spectrometry,

chromatrography), air-to-fuel ratio, fuel cells, fume hoods,

gas leak detection, process control gas monitoring, vacuum

pump monitoring

PORTFOLIO

The Honeywell Zephyr Digital Airﬂow Sensors join an

extensive line of airﬂow sensors for potential use in medical,

industrial, and consumer applications.

Sensing and Internet of Things

DESCRIPTION

Honeywell Zephyr™ HAF Series sensors provide a digital

interface for reading airﬂow over speciﬁed full-scale ﬂow and

compensated temperature ranges. The thermally isolated

heater and temperature sensing elements help these sensors

provide a fast response to air or gas ﬂow. Zephyr sensors are

designed to measure mass ﬂow of air and other non-corrosive

gases. Standard ﬂow ranges are 10 SLPM, 15 SLPM, 20

SLPM, 50 SLPM, 100 SLPM, 200 SLPM and 300 SLPM,

with custom ﬂow ranges available. The sensors are fully

calibrated and temperature compensated with an onboard

Application Speciﬁc Integrated Circuit (ASIC). The HAF Series

>10 SLPM is compensated over the calibrated temperature

range of 0°C to 50°C [32°F to 122°F]. The state-of-the-art

ASIC-based compensation provides digital (I2C) outputs with

a response time of 1 ms. These sensors operate on the heat

transfer principle to measure mass airﬂow. They consist of

a microbridge Microelectronic and Microelectromechanical

System (MEMS) with temperature-sensitive resistors

deposited with thin ﬁlms of platinum and silicon nitride.

The MEMS sensing die is located in a precise and carefully

designed airﬂow channel to provide repeatable response to

ﬂow. Zephyr sensors provide the customer with enhanced

reliability, high accuracy, repeatable measurements and the

ability to customize sensor options to meet many speciﬁc

application needs. The combination of rugged housings with

a stable substrate makes these products extremely robust.

They are designed and manufactured according to ISO 9001

standards.

VALUE TO CUSTOMERS

• Precise measurement: The industry’s smallest Total Error

Band, fast response time, and high accuracy provide precise

measurement and high performance in the customer’s

application.

• Saves time: Configurable and customizable with a choice of

port styles simplifies design and reduces production time.

• Cost-effective: Reduces printed circuit board (PCB) size and

overall design and production costs.

Datasheet

Honeywell ZephyrTM Digital Airﬂow Sensors

HAF Series—High Accuracy: 10 SLPM, 15 SLPM, 20 SLPM,

50 SLPM, 100 SLPM, 200 SLPM, 300 SLPM

008268

Issue 5

2Sensing and Internet of Things

Honeywell ZephyrTM Digital Airﬂow Sensors

HAF Series—High Accuracy: 10, 15, 20, 50, 100, 200, 300 SLPM

TOTAL ERROR BAND (TEB)*

Honeywell specifies TEB, the most comprehensive, clear,

and meaningful measurement that provides the sensor’s

true accuracy (see Figure 1). TEB allows for precise airflow

measurement, often ideal for demanding applications with high

accuracy requirements for precise airflow measurement.

• 10, 15, 20, 50, 100, 200 SLPM:

– 0%FS to 12.5%FS = 0.5%FS

– 12.5%FS to 100%FS = 4.0%reading

• 300 SLPM only:

– 0%FS to 12.5%FS = 0.5%FS

– 12.5%FS to 66.7%FS = 4.0%reading

– 66.7%FS to 100%FS = 7.0%reading

Figure 1. Total Error Band vs. Accuracy

Other airflow sensor manufacturers only report on accuracy, while Honeywell reports Total Error Band.

Table 1. Absolute Maximum Ratings1

Characteristic Parameter

Supply voltage -0.3 Vdc to 11.0 Vdc

Voltage on digital I/O output pins -0.3 Vdc to 3.0 Vdc2

Storage temperature range -40°C to 100°C [-40°F to 212°F]

Maximum flow change 10,000 SLPM/s

Maximum common mode pressure 4 bar | 60 psi at 25°C [77°F]

Maximum flow 350 SLPM

1Absolute maximum ratings are the extreme limits that the device will withstand without damage to the device. However, the electrical and

mechanical characteristics are not guaranteed as the maximum limits (above recommended operating conditions) are approached, nor will

the device necessarily operate at absolute maximum ratings.

2Digital I/O pins are diode protected at this voltage up to 2 mA. Digital bus voltage may exceed this value if the maximum digital bus current is

limited to 2 mA or less. The maximum bus current is generally determined by the bus pull-up resistors

HIGH ACCURACY

Ideal for use in demanding applications that require high

accuracy.

– 0%FS to 14.3%FS = 0.5%FS

– 14.3%FS to 100%FS = 3.5%reading

Total

Error

Band

Accuracy

BFSL

Sources of Error

Thermal Hysteresis

Thermal Effect on Offset

Thermal Effect on Span

Pressure Non-Linearity

Pressure Hysteresis

Full Scale Span

Offset

Pressure Non-Repeatability

CAUTION

IMPROPER USE

Do not use these products to sense liquid flow.

Failure to comply with these instructions may result in

product damage.

CAUTION

PRODUCT DAMAGE

Do not dissamble these products.

Failure to comply with these instructions may result in

product damage.

Sensing and Internet of Things

Honeywell ZephyrTM Digital Airﬂow Sensors

HAF Series—High Accuracy: 10, 15, 20, 50, 100, 200, 300 SLPM

Table 2. Operating Specifications

Characteristic Parameter

Supply voltage 3 Vdc to 10 Vdc

Supply current 20 mA max.

Power:

3 Vdc

10 Vdc

60 mW max.

200 mW max.

Calibrated temperature range10°C to 50°C [32°F to 122°F]

Operating temperature range -20°C to 70°C [-4°F to 158°F]

Full scale (FS) flow210, 15, 20, 50, 100, 200, 300 SLPM

Calilbrated flow range 0 to 10, 0 to 15, 0 to 20, 0 to 50, 0 to 100, 0 to 200, 0 SLPM to 300 SLPM

Calibration gas clean, dry air

Accuracy3

0%FS to 14.3%FS

14.3%FS to 100%FS

0.5%FS

3.5%reading

Total Error Band:4

10, 15, 20, 50, 100, 200 SLPM:

0%FS to 12.5%FS

12.5%FS to 100%FS

300 SLPM only:

0%FS to 12.5%FS

12.5%FS to 66.7%FS

66.7%FS to 100%FS

0.5%FS

4.0%reading

0.5%FS

4.0%reading

7.0%reading

Null accuracy5±0.5%FS

Flow response time61 ms

Warm up time735 ms

Resolution:

10 SLPM

15 SLPM

20 SLPM

50 SLPM

100 SLPM

200 SLPM

300 SLPM

0.002 SLPM

0.003 SLPM

0.008 SLPM

0.015 SLPM

0.029 SLPM

0.043 SLPM

Proof pressure 10.3 bar | 150 psig

Burst pressure 13.7 bar | 200 psig

Bus standards8I2C fast mode (up to 400 kHz)

Reverse polarity protection no

1 Custom and extended temperature compensated ranges are possible. Contact Honeywell for details.

2 Honeywell standard for mass flow rate units is SLPM, which has reference conditions of 0°C and 1 atm. Custom units are given as LPM with listed

reference conditions at the first mention.

3 Accuracy is the maximum deviation in output from nominal over the entire calibrated flow range at 25ºC. Errors include Offset, Full Scale Span,

Linearity, Flow Hysteresis, and Repeatability.

4 Total Error Band (TEB) is the maximum deviation in output from nominal over the entire calibrated flow range and temperature range. Total Error

Band includes all Accuracy errors, as well as all temperature effects over the compensated temperature range, including Temperature Offset,

Temperature Span and Thermal Hysteresis.

5 Null Accuracy is the maximum deviation in output from nominal at null flow over the entire calibrated temperature range.

6 Response time: time to electrically respond to any mass flow change at the microbridge airflow transducer (response time of the transducer may be

affected by the pneumatic interface).

7 Warm-up time: time to the first valid flow measurement after power is applied.

8 Refer to the Technical Note “I2C Communications with Honeywell Digital Airflow Sensors” for I2C protocol information.

4Sensing and Internet of Things

Honeywell ZephyrTM Digital Airﬂow Sensors

HAF Series—High Accuracy: 10, 15, 20, 50, 100, 200, 300 SLPM

Table 3. Environmental Specifications

Characteristic Parameter

Humidity 0% to 95% RH, non-condensing

Shock 30 g, 6 ms

Vibration 1,33 g at 10 Hz to 500 Hz

ESD ESD IEC6100-4-2 air discharge up to 8 kV, or direct contact discharge up to 4 kV

Radiated immunity:

20 , 50, 100 , 200, 300 SLPM

10, 15 SLPM

Level 3 from 80 MHz to 1000 MHz per IEC61000-4-3

1 m shielded cable with 3 cm exposed leads at connector

1 m shielded cable with 3 cm exposed leads at connector and 280 Ohm at MHz ferrite bead

Table 4. Materials Specifications

Characteristic Parameter

Wetted materials glass reinforced (GR) thermoplastic polymer, gold, silicon, silicon dioxide, silicon nitride, epoxy,

PCB epoxy composite

Housing GR thermoplastic polymer

Substrate PCB

Adhesives epoxy

Electronic components silicon, gold

Compliance RoHS, WEEE

Table 5. Recommended Mounting and Implementation

Characteristic Parameter

Mounting screw size 10-32

Mounting screw torque 1,13 N m [20 in-lb]

Electrical connection 6 pin SIP connector

Pneumatic connection manifold mount, 22 mm OD tapered male fitting, G 3/8 female threaded fitting

Sensing and Internet of Things

Honeywell ZephyrTM Digital Airﬂow Sensors

HAF Series—High Accuracy: 10, 15, 20, 50, 100, 200, 300 SLPM

Figure 2. Nomenclature and Order Guide1

Figure 3. All Available Standard Configurations

Manifold mount 22 mm OD tapered male ﬁtting G 3/8 female threaded ﬁtting

HAF

Product Series

0020

Flow Range

Unidirectional

Flow Direction

For example, HAFUHM0020L4AXT deﬁnes a Honeywell Zephyr

Airﬂow Sensor, unidirectional ﬂow, long port, manifold mount, 20 SLPM, I

C output with

custom 0x49 address, 10% to 90% transfer function, 3 Vdc to 10 Vdc supply voltage.

HAF Series—

High Accuracy

Airﬂow Sensor

Manifold

mount

22 mm OD

tapered male

ﬁtting per

ISO 5356

Port Style

Unit

SLPM

Reserved for

Future Use

XXXXX

Transfer

Function

10% to 90% of input

Supply Voltage

3 Vdc to 10 Vdc

0010

0015

Output Format

Digital I2C address:

0x29

G 3/8 female

threaded

ﬁtting per

ISO 1179

Digital I2C address:

0x39

Digital I2C address:

0x49

Digital I2C address:

0x59

Digital I2C address:

0x69

Digital I2C address:

0x79

0020

0050

0100

100

0200

200

0300

300

1Apart from the general configuration required, other customer-specific requirements are also possible. Please contact Honeywell.

6Sensing and Internet of Things

Honeywell ZephyrTM Digital Airﬂow Sensors

HAF Series—High Accuracy: 10, 15, 20, 50, 100, 200, 300 SLPM

Figure 5. Accuracy and Total Error Band

10, 15, 20, 50, 100, 200 SLPM 300 SLPM only

Figure 4. Nominal Digital Output: 10, 15, 20, 50, 100, 200, 300 SLPM

Error (%FS)

%FS

10 100

Ideal

Accuracy:

0%FS to 14.3%FS = 0.5%

14.3%FS to 100%FS = 3.5%

20 50 90700

4.00%

3.00%

2.00%

1.00%

30 40 60 80

Total Error Band:

0%FS to 12.5%FS = 0.5%

12.5%FS to 100%FS = 4.0%

-1.00%

-2.00%

-3.00%

-4.00% 0

%FS

10 10020 50 90700

4.00%

3.00%

2.00%

1.00%

-1.00%

-2.00%

-3.00%

30 40 60 80

Ideal

Accuracy:

0%FS to 14.3%FS (0 SLPM to 43 SLPM) = 0.5%

14.3%FS to 100%FS (43 SLPM to 300 SLPM) = 3.5%

Total Error Band:

0%FS to 14.3%FS (0 SLPM to 43 SLPM) = 0.5%

14.6%FS to 66.7%FS (44 SLPM to 200 SLPM) = 4.0%

66.7%FS to 100%FS (200 SLPM to 300 SLPM) = 7.0%

-4.00%

-5.00%

-6.00%

-7.00%

-8.00%

8.00%

7.00%

6.00%

5.00%

Error (%FS)

TEB = 2.65%

at 200 SLPM

TEB = 7.00%

at 300 SLPM

TEB = 4.67%

at 200 SLPM

TEB = 0.5%

at 43 SLPM

Digital Output (Counts)

Full Scale Flow (%)

0 100

3276

4914

6552

8190

9828

11466

13104

14742

16380

18018

1638

Sensing and Internet of Things

Honeywell ZephyrTM Digital Airﬂow Sensors

HAF Series—High Accuracy: 10, 15, 20, 50, 100, 200, 300 SLPM

Digital Interface

For additional details on the use of Zephyr with digital output see the Technical Note “I2C Communications with Honeywell

Digital Airflow Sensors”.

The sensor uses the I2C standard for digital communication with a slave address specified in the Nomenclature and Order Guide

in Figure 2. Following sensor power-up, each of the first two read sequences shown in Figure 7 will respond with 2 bytes of the

unique 4-byte Serial Number. The first read after power-up will respond with the two most significant bytes of the Serial Number,

while the second read will respond with the two least significant bytes of the Serial Number. For reliable performance, allow

sensor to be powered for the sensor startup time before performing the first read, then allow a 10 ms command response time

before performing the second read.

Figure 6. Flow vs Pressure Drop: 10, 15, 20, 50, 100, 200, 300 SLPM

Flow

(SLPM)

Typical Pressure Drop

mbar inH2OkPa

00.000 0.000 0.000

10.103 0.042 0.010

20.206 0.082 0.021

40.396 0.159 0.040

80.803 0.322 0.080

10 1.027 0.412 0.103

12 1.279 0.513 0.128

14 1.549 0.621 0.155

15 1.686 0.676 0.169

16 1.820 0.730 0.182

18 2.126 0.853 0.213

20 2.444 0.980 0.244

25 3.320 1.332 0.332

50 9.314 3.736 0.931

75 17.553 3.736 1.755

100 27. 979 3.736 2.798

125 40.533 3.736 4.053

150 54.881 22.017 5.488

175 71.158 28.546 7.116

200 89.506 35.907 8.951

225 109.363 43.873 10.936

250 131.037 52.568 13.104

275 154.389 61.936 15.439

300 179.235 71.904 17.9 24

Table 6. Ideal Transfer Function

Item Equation

Digital Output Code 16384 * [0.1 + 0.8 * (Flow Applied/Full Scale Flow)]

Flow Applied Full Scale Flow * [(Digital Output Code/16384) - 0.1]/0.8

0.000

3.447

6.895

10.342

13.790

17.237

20.684

050 100150 200250 300350

Pressure Drop (kPa)

Flow (SLPM)

8Sensing and Internet of Things

Honeywell ZephyrTM Digital Airﬂow Sensors

HAF Series—High Accuracy: 10, 15, 20, 50, 100, 200, 300 SLPM

Table 9. Sensor Response Descriptions

Sensor Response

(Hexadecimal) Response Name Response Description

0xCCA5 POSACK non-response command was executed successfully

0xCC99 BadCommand command byte was not recognized

0xCC9A BadParam command sent with incorrect parameter bytes

0xCC9B Failure command failed during execution

0xCC90 BadChecksum checksum did not match stored value

0xCCBB Busy sensor is busy calculating the checksum value

Table 8. User Command Descriptions

Command Byte

(Hexadecimal) Command Name Command Description Command Response Time

(Max.)

0x01 GetSerialNumber Next two read requests will each return two bytes of

the sensor’s unique 4-byte Serial Number. 10 ms

0x02 PowerOnReset Force Power-On reset of sensor microcontroller. 20 ms

0x03 Checksum

Calculates EEPROM Checksum and compares to

production Checksum value. If the values match,

the next read request will respond with 0xCCA5.

Otherwise, the next read will respond with 0xCC90.

1 s

Figure 7. Sensor I2C Read and Write Sequences

Start condition

SA6 A5 A4 A3 A0A2 A1 1SA D7 D6 D5 D3 D2 D1 D0 MA D6 D4 D3 D2 D1 D0

SD4 D5D7

SDA

SCL

SA6 A5 A4 A3 A0A2 A1 1SA D7 D6 D5 D3 D2 D1 D0 SA SD4

SDA

SCL

Stop condition

Address bit

Read/write bit

Data bit

Slave ACK

Master ACK

Master NACK

Master pulls SDA from high to low while SCL remains high

Master allows SDA to ﬂoat from low to high while SCL remains high

I2C Slave Address is the 7 Most Signiﬁcant Bits for the ﬁrst transmitted byte

Read = 1, Write = 0

Slave pulls SDA low

Master pulls SDA low

Master allows SDA to ﬂoat high

I2C Read: Slave responds to Master with data

Data Byte 0 (Most Signiﬁcant) Data Byte 1 (Least Signiﬁcant)

Command Byte

I2C Read: Master sends data to Slave

Bit Name Description

Read = 1, Write = 0

The maximum sink current on SCL or SDA is 2 mA. Therefore, if the pull-up resistors are biased by VDD, and if VDD reaches

the maximum supply voltage of 6 V, then the pull-up resistors for SCL and SDA must be greater than 3.0 kOhm to limit the sink

current to 2 mA. The typical value for SCL and SDA pull-up resistors is 4.7 kOhm (this value depends on the bus capacitance and

the bus speed).

After the power-up read sequence described above, the sensor will respond to each I2C read request with a 16-bit (2 byte)

digital flow reading. Read requests taken faster than the Response Time (1 ms) are not guaranteed to return fresh data. The first

two bits of each flow reading will be ‘00’, while non-flow responses (such as error and status codes) will begin with ‘11’. There

are several user commands available as shown in Table 8. Following an I2C write sequence of a user command, the sensor will

respond to the next I2C read request with a 16-bit response. Possible responses to user commands can be seen in Table 9.

Sensing and Internet of Things

Honeywell ZephyrTM Digital Airﬂow Sensors

HAF Series—High Accuracy: 10, 15, 20, 50, 100, 200, 300 SLPM

Port Style: 22 mm OD Tapered Male Fitting per ISO 5356

Figure 8. Mounting Dimensions (For reference only: mm [in].)

Port Style: Manifold Mount

[2.7]

[1.2]

110

[4.3]

39,5

[1.56]

18,3

[0.72]

[0.6]

21,0

[0.83]

2X 5,70

[0.22]

14,8

[0.58]

2X 21,0

[0.83]

[1.4]

42,4

[1.67]

[2.1]

51,5

[2.03]

18,0

[0.71]

2X 4,50

[0.177]

[2.7]

2X 18,3

[0.72]

14,5

[0.57]

14,8

[0.58]

[0.6]

39.5

[1.56]

2X 5,20

[0.205]

14,5

[0.57] 44,0

[1.73]

54,4

[2.14]

35,1

[1.38]

44,0

[1.73]

54,4

[2.14]

51,5

[2.03]

[2.1]

4X 4,50

[0.177]

[1.3]

42,4

[1.67]

[0.3]

4,0

[0.16]

63,2

[2.49]

[3.4]

4X 15,0

[0.59]

34,5

[1.36]

4,0

[0.16]

63,2

[2.49]

[3.4]

71,2

[2.80]

4X 5,20

[0.205]

[0.3]

16,0

[0.63]

55,2

[2.17]

44,0

[1.73]

54,4

[2.14]

14,5

[0.57]

30,0

[1.2]

14,6

[0.58]

4X 5,60

[0.220]

33,0

[1.30]

44,0

[1.73]

54,4

[2.14]

22,0

[0.87]

30,6

[1.20]

55,2

[2.17]

71,2

[2.80]

2X 13,0 DIA.

[0.51]

22,0

[0.87]

16,0

[0.63]

Mounting Footprint

Pin 1.

2X 10-32 pan head screws 1,13 N m [20 in-lb] torque.

15 mm ID/22 mm OD tapered fitting per ISO 5356.

Pin 1.

4X 10-32 pan head screws 1,13 N m [20 in-lb] torque.

2X Gland for O-Ring AS568-113, 13,94 mm ID x 2,62 mm

[0.549 in ID x 0.103 in W. Two O-rings, AS568A-113 Durometer

A65 to A80 Silicon or Viton, are required to seal sensor to

manifold. O-rings are not included.

Flow channel.

10 Sensing and Internet of Things

Honeywell ZephyrTM Digital Airﬂow Sensors

HAF Series—High Accuracy: 10, 15, 20, 50, 100, 200, 300 SLPM

Figure 8. Mounting Dimensions (For reference only: mm [in], continued.)

Port Style: G 3/8 Female Threaded Fitting per ISO 1179

[2.1]

51,5

[2.03]

18,0

[0.71]

[1.4]

42,4

[1.67]

[2.8]

14,5

[0.57]

[0.63]

39,5

[1.56]

14,8

[0.58]

35,1

[1.38]

44,0

[1.73]

54,4

[2.14]

2X 1.5

[0.06]

30,0

[1.18]

71,4

[2.81]

34,5

[1.36]

54,4

[2.14]

44,0

[1.73]

14,5

[0.57]

39,5

[1.56]

14,8

[0.58]

2X 18,3

[0.72]

2X 4,50

[0.177]

2X 18,3

[0.72]

2X 5,70

[0.22]

2X 1,5

[0.06]

2X 5,20

[0.205]

[0.63]

Table 7. Pinout (Digital Function)

Pin 1 Pin 2 Pin 3 Pin 4 Pin 5 Pin 6

NC SCL VVDD ground SDA NC

Mounting Footprint

Pin 1.

2X 10-32 pan head screws 1,13 N m [20 in-lb] torque.

ISO 1179 G3/8, recommended torque is 1,7 ±0,6 N m

[15 ±5 in lb]. Electrical connector part number is JST

(Japan Solderless Terminals) B6B-PH-K-S. Mating

connector part numbers are JST PHR-6 (socket) and

JST SPH-002T-P0.5L (crimp terminal).

Honeywell Sensing and Internet of Things

9680 Old Bailes Road

Fort Mill, SC 29707

www.honeywell.com

For more information

Honeywell Sensing and Internet of

Things services its customers through a

worldwide network of sales offices and

distributors. For application assistance,

current specifications, pricing or the

nearest Authorized Distributor, visit

sensing.honeywell.com or call:

Asia Pacific +65 6355-2828

Europe +44 (0) 1698 481481

USA/Canada +1-800-537-6945

WARNING

PERSONAL INJURY

DO NOT USE these products as safety or emergency stop

devices or in any other application where failure of the

product could result in personal injury.

Failure to comply with these instructions could result in

death or serious injury.

WARNING

MISUSE OF DOCUMENTATION

• The information presented in this datasheet is for

reference only. Do not use this document as a product

installation guide.

• Complete installation, operation, and maintenance

information is provided in the instructions supplied with

each product.

Failure to comply with these instructions could result in

death or serious injury.

ADDITIONAL INFORMATION

The following associated literature is available on the

Honeywell web site at sensing.honeywell.com:

• Product line guide

• Product range guide

• Technical Information

– I2C Communications with Honeywell Digital Airflow

Sensors

– Gas Media Compatibility and Correction Factors

• Application Specific Information

008268-5-EN | 5 | 02/18

Warranty/Remedy

Honeywell warrants goods of its manufacture as being free

of defective materials and faulty workmanship during the

applicable warranty period. Honeywell’s standard product

warranty applies unless agreed to otherwise by Honeywell in

writing; please refer to your order acknowledgment or consult

your local sales office for specific warranty details. If warranted

goods are returned to Honeywell during the period of coverage,

Honeywell will repair or replace, at its option, without charge

those items that Honeywell, in its sole discretion, finds defective.

The foregoing is buyer’s sole remedy and is in lieu of all

other warranties, expressed or implied, including those of

merchantability and fitness for a particular purpose. In no

event shall Honeywell be liable for consequential, special, or

indirect damages.

While Honeywell may provide application assistance personally,

through our literature and the Honeywell web site, it is buyer’s

sole responsibility to determine the suitability of the product in

the application.

Specifications may change without notice. The information we

supply is believed to be accurate and reliable as of this writing.

However, Honeywell assumes no responsibility for its use.