Multipoint Thermocouple

Multipoint Thermocouple

What is Multi-Point Thermocouple?

• Multi-point thermocouples are used to measure more than one temperature point through a single access point. The sensor has multiple temperatures input along the length of the sensor to calculate an accurate temperature profile. This sensor can be equipped with up to 60 points along the length with a single penetration point. These sensors are mostly used in chemical and petroleum industries for temperature profiling of reactors, crackers, and liquefied gas in tanks.
• The design and dimensions of the multi-point thermocouples differ depending on the shape and size of the container, position of the sensors, service required, pressure, temperature and ambient environment of where the thermocouple has to be installed and where the output is required.

What are the features of Multi-point thermocouple?

• Multiple sensing points with only a single accessing point.
• Effectively measures temperature profile for various applications.
• The individual sensor can be replaced without affecting the whole.
• Cost-efficient as compare to placing individual sensors.
• Customizable design available according to
different temperature range and signal accuracies.
• All sensors are fully metal sheathed with mineral insulation.
• Some designs are available with resistance elements as the primary sensor to provide more accurate results.

Application Areas
•Chemical and petrochemical industries
• Reactors and Distillation fractionators
• Fuel depots,hydrocrackers and
• Fluid catalytic cracking unit
• Crude oil distillation
• Catalytic reforming process

Multi-Point Thermocouple Installation

Technical Specification

Element K, N, E, Pt100
No. of sensors Depending on desing (Up to 60 points)
Hot junction Grounded, Ungrounded
Sheath material SS 316, SS 310, Inconel 600
Sheath diameter 12.6, 10, 8, 6 etc.
Response Time Less Than 10 sec.
Temperature Range Depending on material
Process Connection As per requirement

Sensor Design

Tempsens Instruments provides endless type of design for multi-point thermocouples, depending
on the requirements and application of the thermocouples. To illustrate the basic idea of different
types of multi- point thermocouples, couples of design has been illustrated:

Freely Suspended Multi-Point thermocouple

Flexible Suspended sensors provide a flexible design with greater
coverage for temperature measurement. The sensors are routed
around the circumference of the reactors and then inwards to the
required measuring point. The individual sensor can be routed
according to the requirement of the applications. They can be coiled for
shipment and can be supplied without an outer protection tube.

Multi-point thermowell with heat transfer block

In this design, the measuring sensor is integrated with heat transfer
block to provide dual protection. The heat shrink block is welded with
the vessel body where the measuring sensor has to be attached. The
design allows for replacement and removal of the individual sensor
during operation if required. The sensor rests against the heat transfer
block in order to provide shorter response time.

Spring loaded multi-point thermocouple

The design is equipped with a bimetal spring-loaded device to an
individual measuring sensor to provide positive contact between the
measuring sensor and protection tube. The bimetallic spring is installed
into the protection tube in the unloaded position, and the connection is
achieved when the heat is applied during the process.

Multi-point thermocouple with a guiding tube

Guide tubes are provided for each sensor so that accurate positing of
the sensor can be ensured. This design allows the thermocouple to be
replaced without the need to perform any re-welding on the process
tube. The design allows the welded part to be attached to the protection
tube in the absence of the sensor. These guide tubes can be springloaded to make sure the sensor is in contact with the inner wall.

Multi-point thermocouple with Radial arrangement

The design allows individual sensors to arrange in radial pattern to fit
any cylindrical chamfer across the inner surface. The design allows
routing of the radial elements to have the lowest possible influence on
the function of the catalyst. Shorter response time can be achieved
which leads to fast information delivery about the change in the