Send an inquiry

Stainless steel immersion heater enclosure with built-in hexagon for fitting, Y3S4

– High lid
– Bottom side with stamped 61mm hexagon, can be used on orientable fitting with ring or inside nut
– Can be used with 1 ″1/4 or 1 ″1/2 or M45 TIG welded fittings
– Hole for M20 cable gland
– Can receive a standard storage heater immersion heater, with 1/”1/4 brass fitting, with 54mm on flat hexagon

Dimensions 90 × 90 × 82 mm
Ingress protection

Mechanical protection

Housing raw material

, ,

Volume (cm³)

SKU: Y3S4 Categories: , Tags: , , , , , ,

Red dimensions inside rectangular frames on drawings are used for accessories assembly.

Main features

Immersion heater enclosure with built-in hexagon for fitting
– High lid
– Bottom side with stamped 61mm hexagon, can be used on orientable fitting with ring or inside nut
– Can be used with 1 ″1/4 or 1 ″1/2 or M45 TIG welded fittings
– Hole for M20 cable gland
– Can receive a standard storage heater immersion heater, with 1/”1/4 brass fitting, with 54mm on flat hexagon

Size: 90 x 90 x 75 mm

Volume: 392 cm³

Material: Stainless steel deep drawn cover and bottom.

Ingress protection: IP69K

Mechanical impact resistance: IK7

Screws: Stainless Steel.

Cover gasket: Molded Silicone.

 

Basic references

Accessories

 

Internal bracket for inside adjustment thermostat

  

Silicone cap for thermostat adjustment hole

  

PA66, 6 way connection block

  

Brass fittings

 Massive stainless steel fitting, for custom hole drilling  

Deep drawn stainless steel fitting
 

9BBAE1000ELH008A

  

9BBJO1000004078A

  

BE6E6000000MP000

 For full range and references of fittings, nuts and gaskets: immersion heater accessories. Available without holes or drilled upon request. Ask for references Available in 2, 3, 4, 5, 6, 7 holes and M45 or 1″1/2 thread. Ask for references

 

To access download documents, please Login/Register.  Datasheet, drawings (.dwg), 3D models (.stp) and other documents are available.

Downloads

Datasheets

Drawings

Related products

Quick View

Metallic housings

Aluminum enclosure, with polycarbonate cover, for immersion heater with 120 mm offset fitting, Y3J1

Quick View

Metallic housings

Aluminum enclosure, with polycarbonate cover, for immersion heater with 30 mm offset fitting, Y3G1

Quick View

Metallic housings

Stainless steel immersion heater or temperature sensor enclosure, Y3S3

Quick View

Metallic housings

Large size enclosure for immersion heater, finned heaters with external adjustment knob, Y3P6

Quick View

Metallic housings

Round miniature simplified immersion heater enclosure, Y3K1

Quick View

Metallic housings

Aluminum enclosure, black or transparent polycarbonate cover, for immersion heater or solid state relays (SSR) controls, Y3H1

Quick View

Metallic housings

Enclosure for small storage heater immersion heater, Y3L4

Quick View

Metallic housings

Stainless steel Big immersion heater enclosure, with flat cover and stamped hexagon, Y3SB

Technical informations associated to this product

  • Electrical protection classes

    The housings are designed to protect electrical equipment located inside. This protection must be considered in the electrical and environmental angles.)

  • Guide for immersion heater selection

    Figures provided in this section are results of tests made in our laboratory. Charts were smoothened by computer, and are given for specified power and for information only.

  • Overview of immersion heater fittings

    In Europe there are two common types of threads used on immersion heaters fittings. Threads according ISO 228-1, also said BSPP or cylindrical gas thread (G). 2mm pitch metric thread according ISO965-1, little used, which was the subject of an attempt to replace the ISO228-1 in the middle of the 20th
  • Photos du boitier aluminium non peint, après 1000h de brouillard salin et lavage à l’eau

    Surface engineering of metallic housing

    Surface condition is an essential parameter of resistance against atmospheric corrosion. Both aluminum and stainless steel naturally form a protective oxide layer on the surface. Corrosion occurs only when this protective oxide layer is crossed or destroyed. Microcavities of a rough surface allow atmospheric pollutants to initiate local oxidative conditions. This is particularly critical when these pollutants have a different galvanic potential. For example, iron or iron oxide dust can create favourable conditions for perforating corrosion in stainless steel, as well as zinc in the case of aluminum. It is important that the surface of the metal, if exposed to the weather, be smooth so that these pollutants slide and escape naturally.