The GL-3349-M-WR Magnetic Mount Remote Controlled Thermal Imaging Infrared Camera systemÂ with a 6 inchÂ LCD monitor is a small thermal sensing camera mounted in aÂ remote controlledÂ frame that can detect heat differentials between 32Â°- 240Â° F.Â TheÂ remote controlledÂ thermal imaging camera has a 1500` detecting range,Â a field of view thatÂ measures 35Â° horizontally by 27Â° vertically, andÂ canÂ rotate 370Â° with aÂ 135Â° tilt. It also comes in two speeds, fast and slow (turtle and hare).Â The infrared camera has sensor type of 320 x 240 uncooled micro bolometer. A 2.4 GHz transmitter facilitates wireless signals between the light and the screen, with a maximum distance of 100 feet.
The LCDÂ monitor is supported by aÂ flexible neck andÂ can be mounted to a dashboard or aÂ windowÂ with its suction cup base,Â or mountedÂ anywhere else with simple installation. With this particular unit, the white color indicates a hot substance, whereas the black color indicates a cold subject.
TheÂ remote controlledÂ thermal imaging infrared camera systemÂ withÂ 6 inchÂ LCD monitorÂ is availableÂ with (2) wireless remote controls for the camera, one wireless handheld and one wireless dash mount.Â Both controllers offer left, right, up and down motor control as well as fast and slow motor speed control.Â The operator can also turn the camera on and off from the controller. Additionally, the LCD monitor includes a wireless remote control.
The remote controlled, pan/tilt thermalÂ imaging cameraÂ also comes equipped with an internal core heater that prevents the lens of the cameraÂ from icing up. Due to it`s high resolution camera, this thermal imaging cameraÂ can display images up to 1,500 feet inÂ any direction that it is pointed, through fog, smoke and precipitation.
The remote control camera is magnetically mounted. The magnet is water tight and has a 100 pound grip base and is tested to 60 mph. The magnetic base is encapsulated in soft rubber to adapt to uneven vehicle surfaces and prevent scratches on vehicle paint. A wrap around base seal prevents dirt from entering the base of the light.
The Remote Controlled Thermal Imaging Infrared Camera runs off 12V DC and has a frequency of 30 hertz. It is equipped with a 16 foot, outdoor rated cord with a cigarette plug. Weather tight connector enables operators to disconnect cord at 12 inches from the light for storage or vehicle portability. Larson Electronics offers an alternative 24V DC setup for military applications. At 6.75" L x 7.25" W x 8" D and weighing only 4lbs, the thermal imaging camera can be mounted practically anywhere from cars to trailers. The thermal camera comes with various options including color and wireless/wired remote setup.
The signal between the light and the screen is wireless, which is facilitated by a 2.4 GHz wireless transmitter. The device operates on 100V-240V and sends out a frequency range of 2,414 MHz to 2,468 MHz. A directional antenna helps transmit a signal capable of reaching up to 100 feet.
Including with Light:
Helios 3349 motorized thermal camera
Magnetic mounting kit for 3349
Gooseneck suction cup mount for LCD monitor
Adhesive-back tilt mount for LCD monitor
AV cables for connecting Helios 3349 to LCD monitor
(1) Handheld wireless remote for Helios 3349 - batteries included
(1) Dash Mount wireless remote for Helios 3349 - batteries included
(1) Remote for LCD monitor - batteries included
(1) 2.4 GHz Wireless Transmitter
Heated objects are displayed as white hot on the LCD screen.
How Does Thermal Imaging Work?
Thermal energy is a part of the electromagnetic spectrum. It makes up the upper portion of the infrared light spectrum. You cannot see thermal energy because it is emitted from objects as heat, not reflected as light. The hotter an object is, the more thermal energy it emits. Hotter objects will appear whiter on the monitor. However, all objects even inanimate ones, such as buildings, or even ice cubes, emit some form of thermal energy. Infrared thermal imaging cameras are able to capture this thermal energy and transform it into an image you can see. Objects producing less thermal energy will be a duller white, while objects generating more thermal energy (higher temperature) will produce a brighter white image.
The process by which a thermal imaging camera transforms thermal energy into visible light consists of five basic steps. These steps are:
|The picture above demonstrates a set of boxes taken from a regular digital camera.
||Viewing the same set of boxes through the GL-3349-M-WR reveals hand prints on the boxes that have been briefly touched.
Since thermal imaging cameras work solely by capturing infrared radiation given off from an object, no light at all is required for the device to function. A thermal imaging camera can function optimally no matter what the surrounding lighting conditions, bright or dim.
In addition to the ability to function in a wide array of lighting conditions, thermal imaging cameras can be used to reveal aspects about ones surroundings where no visible sign of evidence exists. For example, a thermal imaging camera might reveal an area of ground that has been dug up to bury something. Another example could include an area of a wall that has been painted or repaired recently. It will appear slightly darker through a thermal imaging camera. This unique ability to detect and gather evidence that would have previously gone undetected makes thermal imaging cameras invaluable devices for law enforcement and military personnel.
Thermal imaging cameras were first designed for use by the military to help locate enemy targets. As improvements were made to the technology, these camera devices became more and more practical for commercial uses such as perimeter surveillance and other security applications. Now more than ever, thermal imaging cameras are continuing to be used on a much broader scale. There are several other applications where thermal imaging technology can be very useful. These include security and surveillance, navigation, hunting, law enforcement, and hidden object detection. Within the commercial space, manufacturing companies, petrochemical companies and utility companies use thermal imaging to inspect equipment and detect problems.
Thermal Imaging Applications
A thermal imaging camera is a reliable non contact instrument which is able to scan and visualize the temperature distribution of entire surfaces of machinery and electrical equipment quickly and accurately. Thermography programs have contributed to substantial cost savings for our customers around the world in a variety of industries. While military and security applications in low light conditions remain paramount, industries ranging from utilities to manufacturing and service companies are using thermal imaging cameras to identify issues, prevent larger problems and save money.
Detect Problem Areas Before the Real Problems Occur
In production plants, office facilities, hospitals or hotels, an infrared camera instantly makes hot spots visible on a clear thermal image. You can scan electrical cabinets and components and survey multiple wires and connections to get an instant picture of potential trouble. Detect the problem area and repair it before real problems occur. Common electrical targets are fuses, electrical panels, bolted connections and switchgear.
For utilities, failure is not an option. Thatâ€™s why infrared thermography has become the core of utility predictive maintenance programs around the world. Utilities depend on thermography to avoid costly failures in power generation, transmission and distribution as infrared cameras help find anomalies before trouble strikes and service is affected.
At manufacturing facilities, thermal imaging cameras are used for inspecting a countless number of production equipment and components as well as the complete electrical power supply system. An infrared image, including accurate temperature data, provides the maintenance expert with important information about the condition of the inspected object. Inspections are done with the production process in full operation. In many cases the use of a thermal imaging camera can help optimize the production process itself.
Some examples of mechanical equipment where thermography is used:
Pumps (overheated connections, fuse problems, overloaded electrical cables, etc)
Process valves (open, closed, leakage)
Storage tanks (sludge levels)
Pipelines (check if and where there are abnormalities, for example locate build up of scale)
Motors (overheating bearings, misalignment, overheated windings)
Conveyor belts (overheated bearings)
Some examples of electrical equipment where thermography is used:
Primary power source (i.e. outdoor high voltage switchyard)
Low voltage installations (i.e. breaker panels, faulty electrical outlets/wall sockets)
Motor Control Centers (MCC)
Energy Efficiency and Green Programs
To get even more out of your camera investment, you can use your infrared camera to audit energy efficiency of your plant environment, including roofing, heating and cooling systems, and building structures.
Oil and Gas
The use of infrared cameras has already become a standard practice in many oil and gas companies. Itâ€™s a proactive way to identify sources of Volatile Organic Compound (VOC) emissions and repair leaking components before it is too late. By using the most advanced VOC detection you will improve safety and productivity and minimize emissions.
Infrared cameras for the oil and gas industry are preventative maintenance solutions that help spot leaks in tanks, pipelines and facilities that will improve safety and profitability and minimize emissions with less risk of business interruption due to actions from regulatory agencies.
Thermal Imaging in Use
- Utilize a specially designed lens to focus the infrared radiation that is given off from all objects within the field of view of the camera lens.
- Infrared detectors are then used to scan this focused radiation. The detectors create what is called a thermogram, or temperature map.
- The thermogram is then translated into electric impulses.
- The electric impulses are then sent to a signal-processing unit where they are translated into data. The signal-processing unit is a tiny chip that is embedded on a circuit board, which is used to translate the electric impulses into usable data.
- Once translated, the signal-processing unit sends the data to the monitor where it then becomes visible to the viewer.
|Click Images to Enlarge
|The picture above shows a suv at night; picture was taken with a digital camera, no flash.
||This picture shows the same suv through the 6" LCD thermal imaging screen. Notice the white from the heat that the vehicle is emitting.
||In this picture, the thermal imaging is used to distinguish the difference between a car completely powered off, to a car sitting idle.