User Manual

ManualsBrandsFLIR Systems ManualsCamera & PhotoInfrared Camera

171

172

173

174

175

176

177

178

179

180

Table Of Contents

1 Disclaimers
- 1.1 Legal disclaimer
- 1.2 Usage statistics
- 1.3 Changes to registry
- 1.4 U.S. Government Regulations
- 1.5 Copyright
- 1.6 Quality assurance
- 1.7 Patents
- 1.8 Third-party licenses
2 Safety information
3 Notice to user
- 3.1 User-to-user forums
- 3.2 Calibration
- 3.3 Accuracy
- 3.4 Disposal of electronic waste
- 3.5 Training
- 3.6 Documentation updates
- 3.7 Important note about this manual
- 3.8 Note about authoritative versions
4 Customer help
- 4.1 General
- 4.2 Submitting a question
- 4.3 Downloads
5 Introduction
- 5.1 General description
- 5.2 Key benefits
6 Quick start guide
- 6.1 Procedure
7 A note about ergonomics
- 7.1 General
- 7.2 Figure
8 Camera parts
- 8.1 View from the right
  - 8.1.1 Figure
  - 8.1.2 Explanation
- 8.2 View from the left
  - 8.2.1 Figure
  - 8.2.2 Explanation
- 8.3 View from the bottom
  - 8.3.1 Figure
  - 8.3.2 Explanation
- 8.4 View from the rear
  - 8.4.1 Figure
  - 8.4.2 Explanation
- 8.5 Neck strap attachment points
  - 8.5.1 Figure
- 8.6 Battery condition LED indicator
  - 8.6.1 Figure
  - 8.6.2 Explanation
- 8.7 Power LED indicator
  - 8.7.1 Figure
  - 8.7.2 Explanation
- 8.8 Laser pointer
9 Screen elements
- 9.1 Figure
- 9.2 Explanation
- 9.3 Status icons and indicators
- 9.4 Image overlay information
10 Navigating the menu system
- 10.1 General
- 10.2 Navigating using the joystick
11 Handling the camera
- 11.1 Charging the battery
  - 11.1.1 Using the power supply to charge the battery
  - 11.1.2 Using the stand-alone battery charger to charge the battery
- 11.2 Turning on the camera
  - 11.2.1 Procedure
- 11.3 Turning off the camera
  - 11.3.1 Procedure
- 11.4 Adjusting the viewfinder’s dioptric correction
  - 11.4.1 Figure
  - 11.4.2 Procedure
- 11.5 Adjusting the angle of the lens
  - 11.5.1 Figure
- 11.6 Adjusting the infrared camera focus manually
  - 11.6.1 Figure
  - 11.6.2 Procedure
- 11.7 Autofocusing the infrared camera
- 11.8 Continuous autofocus
  - 11.8.1 General
  - 11.8.2 Procedure
- 11.9 Operating the laser pointer
  - 11.9.1 Figure
  - 11.9.2 Procedure
- 11.10 Using the digital zoom function
- 11.11 Assigning functions to the programmable buttons
  - 11.11.1 General
  - 11.11.2 Procedure
- 11.12 Using the camera lamp as a flash
  - 11.12.1 General
  - 11.12.2 Procedure
- 11.13 Changing lenses
- 11.14 Using the close-up lens
- 11.15 Changing the viewfinder eyecup
- 11.16 Calibrating the compass
  - 11.16.1 Procedure
12 Saving and working with images
- 12.1 About image files
- 12.2 Saving an image
  - 12.2.1 General
  - 12.2.2 Procedure
- 12.3 Previewing an image
  - 12.3.1 General
  - 12.3.2 Procedure
- 12.4 Opening a saved image
  - 12.4.1 General
  - 12.4.2 Procedure
- 12.5 Editing a saved image
- 12.6 Creating a PDF report in the camera
- 12.7 Deleting an image
  - 12.7.1 General
  - 12.7.2 Procedure
- 12.8 Deleting multiple images
  - 12.8.1 General
  - 12.8.2 Procedure
- 12.9 Deleting all images
  - 12.9.1 General
  - 12.9.2 Procedure
- 12.10 Resetting the image counter
  - 12.10.1 General
  - 12.10.2 Procedure
13 Achieving a good image
- 13.1 General
- 13.2 Adjusting the infrared camera focus
- 13.3 Adjusting the infrared image
- 13.4 Changing the temperature range
  - 13.4.1 General
  - 13.4.2 Procedure
- 13.5 Changing the color palette
  - 13.5.1 General
  - 13.5.2 Procedure
- 13.6 Changing the object parameters
- 13.7 Calibrating the camera
  - 13.7.1 General
  - 13.7.2 Manual calibration
- 13.8 Hiding all overlay
  - 13.8.1 General
  - 13.8.2 Procedure
14 Working with image modes
- 14.1 General
- 14.2 Image examples
- 14.3 Selecting the image mode
15 Working with measurement tools
- 15.1 General
- 15.2 Adding/removing measurement tools
- 15.3 Working with user presets
  - 15.3.1 General
  - 15.3.2 Procedure
- 15.4 Resizing or moving a measurement tool
  - 15.4.1 General
  - 15.4.2 Procedure
- 15.5 Changing object parameters
- 15.6 Displaying values in the result table and displaying a graph
  - 15.6.1 General
  - 15.6.2 Procedure
- 15.7 Creating and setting up a difference calculation
  - 15.7.1 General
  - 15.7.2 Procedure
- 15.8 Setting a measurement alarm
16 Working with color alarms and isotherms
- 16.1 Color alarms
  - 16.1.1 General
  - 16.1.2 Image examples
- 16.2 Setting up above, below, and interval alarms
- 16.3 Building isotherms
17 Annotating images
- 17.1 General
- 17.2 Adding a note
  - 17.2.1 General
  - 17.2.2 Procedure
- 17.3 Adding a table
  - 17.3.1 General
  - 17.3.2 Procedure
- 17.4 Adding a voice annotation
  - 17.4.1 General
  - 17.4.2 Procedure
- 17.5 Adding a sketch
  - 17.5.1 General
  - 17.5.2 Procedure
18 Programming the camera (time lapse)
- 18.1 General
- 18.2 Procedure
19 Recording video clips
- 19.1 General
- 19.2 Procedure
20 Screening alarm
- 20.1 General
- 20.2 Procedure
21 Pairing Bluetooth devices
- 21.1 General
- 21.2 Procedure
22 Configuring Wi-Fi
- 22.1 General
- 22.2 Setting up a wireless access point (most common use)
- 22.3 Connecting the camera to a wireless local area network (less common use)
23 Changing settings
- 23.1 General
- 23.2 Procedure
24 Technical data
- 24.1 Online field-of-view calculator
- 24.2 Note about technical data
- 24.3 Note about authoritative versions
- 24.4 FLIR T1020 12°
- 24.5 FLIR T1020 28°
- 24.6 FLIR T1020 45°
- 24.7 FLIR T1030sc 12°
- 24.8 FLIR T1030sc 28°
- 24.9 FLIR T1030sc 45°
- 24.10 FLIR T1040 12°
- 24.11 FLIR T1040 28°
- 24.12 FLIR T1040 45°
- 24.13 FLIR T1050sc 12°
- 24.14 FLIR T1050sc 28°
- 24.15 FLIR T1050sc 45°
25 Mechanical drawings
26 Cleaning the camera
- 26.1 Camera housing, cables, and other items
- 26.2 Infrared lens
- 26.3 Infrared detector
  - 26.3.1 General
  - 26.3.2 Procedure
27 Application examples
- 27.1 Moisture & water damage
  - 27.1.1 General
  - 27.1.2 Figure
- 27.2 Faulty contact in socket
  - 27.2.1 General
  - 27.2.2 Figure
- 27.3 Oxidized socket
  - 27.3.1 General
  - 27.3.2 Figure
- 27.4 Insulation deficiencies
  - 27.4.1 General
  - 27.4.2 Figure
- 27.5 Draft
  - 27.5.1 General
  - 27.5.2 Figure
28 About FLIR Systems
- 28.1 More than just an infrared camera
- 28.2 Sharing our knowledge
- 28.3 Supporting our customers
- 28.4 A few images from our facilities
29 Glossary
30 Thermographic measurement techniques
- 30.1 Introduction
- 30.2 Emissivity
  - 30.2.1 Finding the emissivity of a sample
- 30.3 Reflected apparent temperature
- 30.4 Distance
- 30.5 Relative humidity
- 30.6 Other parameters
31 History of infrared technology
32 Theory of thermography
- 32.1 Introduction
- 32.2 The electromagnetic spectrum
- 32.3 Blackbody radiation
- 32.4 Infrared semi-transparent materials
33 The measurement formula
34 Emissivity tables
- 34.1 References
- 34.2 Tables

Theory of thermography

Figure 32.2 Gustav Robert Kirchhoff (1824–1887)

The construction of a blackbody source is, in principle, very simple. The radiation charac-

teristics of an aperture in an isotherm cavity made of an opaque absorbing material rep-

resents almost exactly the properties of a blackbody. A practical application of the

principle to the construction of a perfect absorber of radiation consists of a box that is

light tight except for an aperture in one of the sides. Any radiation which then enters the

hole is scattered and absorbed by repeated reflections so only an infinitesimal fraction

can possibly escape. The blackness which is obtained at the aperture is nearly equal to

a blackbody and almost perfect for all wavelengths.

By providing such an isothermal cavity with a suitable heater it becomes what is termed

a cavity radiator. An isothermal cavity heated to a uniform temperature generates black-

body radiation, the characteristics of which are determined solely by the temperature of

the cavity. Such cavity radiators are commonly used as sources of radiation in tempera-

ture reference standards in the laboratory for calibrating thermographic instruments,

such as a FLIR Systems camera for example.

If the temperature of blackbody radiation increases to more than 525°C (977°F), the

source begins to be visible so that it appears to the eye no longer black. This is the incipi-

ent red heat temperature of the radiator, which then becomes orange or yellow as the

temperature increases further. In fact, the definition of the so-called color temperature of

an object is the temperature to which a blackbody would have to be heated to have the

same appearance.

Now consider three expressions that describe the radiation emitted from a blackbody.

32.3.1 Planck’s law

Figure 32.3 Max Planck (1858–1947)

Max Planck (1858–1947) was able to describe the spectral distribution of the radiation

from a blackbody by means of the following formula:

where:

#T559954; r.28105/28105; en-US

166