ESPRESSO MILK FROTHER PROBE

Abstract

A milk frothing apparatus which includes a steam probe which consists of an inner steam tube surrounded by an outer tube spaced annularly from the inner tube with a nozzle mounted on the end of said outer tube adjacent the outlet end of said inner tube. The air gap between the inner and outer tubes insulates the outer tube from the heat generated in the inner tube during the steam cycle. By using stainless steel the milk does not stick to the cool outer tube surface and no cleaning of the outer surface of the probe is necessary. The steam itself keeps the inner surfaces of the probe clean.

Claims

1. A milk frothing apparatus comprising a steam probe which comprises an outer steam tube, an inner steam tube surrounded by said outer steam tube spaced annularly from the inner steam tube, and a nozzle mounted on an end of said outer steam tube adjacent an outlet end of said inner steam tube to facilitate cleaning of a surface of the outer steam tube.

2. The milk frothing apparatus as claimed in claim 1 in which the steam probe is made from stainless steel.

3. The milk frothing apparatus as claimed in claim 1, further comprising a jug, a jug support, and a non-contact temperature sensor, wherein the non-contact temperature sensor is located adjacent the jug support to monitor a temperature of an external surface of the jug, and wherein a lower portion of jug external surface of the jug is matt black.

4. A steam probe for a milk frothing apparatus, the steam probe comprising: an outer steam tube; an inner steam tube surrounded by said outer steam tube spaced annularly from the inner steam tube; and a nozzle mounted on an end of said outer steam tube adjacent an outlet end of said inner steam tube.

5. The steam probe as claimed in claim 4 in which the steam probe is made from stainless steel.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0009] Preferred embodiments of the invention will now be described with reference to the drawings in which

[0010] FIG. 1 is a schematic view of the tip of the steam probe;

[0011] FIG. 2 illustrates a side view of the milk jug of this invention;

[0012] FIG. 3 illustrates the position of a non-contact temperature sensor.

[0013] The embodiments described may be used in the milk frother as described in WO2014/165911.

[0014] As shown in FIG. 1 the milk probe 10 attaches to the steam line 11 by a screw thread connection. The probe consists of a double wall tube. The inner tube 14 attaches to the steam line and the outer tube 15 is concentric with the inner tube 14 and spaced therefrom by spacers 16. The air space 18 separates and insulates the outer tube 15 from the inner tube 14. This air space may be filled with any insulating material as an alternative insulator to air. The tip 20 is welded or screwed to the end of outer tube 15 adjacent the end of the inner tube 14. The tip 20 incorporates steam outlets 21. Because the temperature of the outer tube is kept low during the steam injection step, the milk does not adhere to the surface of the outer wall and no cleaning of that surface is needed between steam injections. As is conventional in the design of milk probes, it may be curved or serpentine along its length.

[0015] The temperature of the milk in the jug 30 is sensed by an infrared sensor 35 in the body of the milk frother 40. The lower surface 31 of the jug 30 is coated to have a matt black surface to ensure an accurate temperature reading.

[0016] A preferred coating is Black Chromium which is slightly harder than nickel chrome and gives a matte black finish which is able to withstand the normal washing process. The stainless steel jugs can also be spray-painted with matte black epoxy coatings or materials such as ironstone a non-stick coating

[0017] Whatever the material of choice is, it is preferably thin to allow the fastest transfer of heat. Coatings may be applied using Vapour deposition or Plasma enhanced chemical vapour deposition use a direct current. A two-stage process is required for anodizing the surface: Ion Vapour deposition and then anodization in the normal way.

[0018] From the above it can be seen that this invention provides a unique means of increasing barista productivity without losing the quality of milk frothing required for premium espresso coffee products. Those skilled in the art will realise that this invention may be implemented in embodiments other than those described without departing from the core teachings of this invention.