Liquid capsule having thermochromic and photochromic properties

Abstract

The invention relates to a capsule comprising a shell containing a transparent and thermally conducting liquid, particles having a thermochromic coating and particles having a photochromic coating, the thermochromic particles being bulkier than photochromic particles, the liquid being such that, within a first range of temperatures, its density is greater than the density of the thermochromic particles and than the density of the photochromic particles, and such that, within a second range of temperatures greater than those of the first range, the density of the photochromic particles is less than the density of the liquid, which is itself less than the density of the thermochromic particles.

Claims

1. A capsule comprising a shell containing a transparent and thermally conducting liquid, particles having a thermochromic coating and particles having a photochromic coating, the thermochromic particles being bulkier than photochromic particles, the liquid being such that, within a first range of temperatures, the density of the liquid is greater than the density of the thermochromic particles and than the density of the photochromic particles, and such that, within a second range of temperatures greater than those of the first range, the density of the liquid is greater than the density of the photochromic particles, and less than the density of the thermochromic particles.

2. The capsule according to claim 1, the liquid being an oily mixture of liquid paraffin and glycerol.

3. The capsule according to claim 1, the thermochromic particles and the photochromic particles being of spherical shape.

4. The capsule according to claim 1, the thermochromic particles and the photochromic particles having a diameter of between 100 and 500 microns.

5. The capsule according to claim 1, the shell additionally comprising photoluminescent particles.

6. A timepiece or item of jewellery comprising a wall comprising capsules according to claim 1 thereon.

Description

BRIEF DESCRIPTION OF THE FIGURES

(1) Other distinguishing features and advantages will emerge clearly from the description which is made below thereof, by way of indication and without any limitation, with reference to the appended figures, representing:

(2) In FIG. 1, a capsule according to an embodiment of the invention, when its temperature lies within a first range of temperatures.

(3) In FIG. 2, the capsule of FIG. 1, when its temperature lies within a second range of higher temperatures.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

(4) FIG. 1 represents a capsule (CS) comprising a transparent leaktight shell (CQ). The shell (CQ) includes a transparent liquid (L) which does not form a barrier to ultraviolet rays, which is thermally conducting and which has a high thermal expansion at a preferred temperature, which will be denoted Tx. It can, for example, be an oily mixture of a liquid paraffin having a melting point Tx and glycerol. The shell (CQ) also includes two types of particles. The first particles are coated with a thermochromic coating; they will be referred to as thermochromic particles (A). The second particles are coated with a photochromic coating; they will be referred to as photochromic particles (B). These particles are provided in the form of spheres and can thus more easily sink (in contrast to particles in strip form). The thermochromic and photochromic coatings are chosen so as to withstand the oily medium. They are also selected so as to have a coloured transition threshold which makes it possible to give advantageous information, in particular to a wearer of a timepiece or item of jewellery, in the case where the capsule is placed on a wall of said timepiece or item of jewellery. This information can be a temperature, a light intensity, a level of ultraviolet radiation dangerous to the health, and the like.

(5) The thermochromic particles (A) and the photochromic particles (B) have, for example, a diameter of between 100 and 500 microns. Furthermore, the volume of the thermochromic particles (A) is greater than the volume of the photochromic particles (B). Finally, the density of the thermochromic particles (A) is higher than the density of the photochromic particles (B).

(6) Within a first range of temperatures, for example between 0° C. and 10° C., the density of the liquid (L) is greater than the density of the thermochromic particles (A) and than the density of the photochromic particles (B). Thus, the thermochromic particles (A) and the photochromic particles (B) are in suspension in the liquid (L). However, the photochromic particles (B) are masked by the thermochromic particles (A), which have a larger volume and consequently a greater chromatic power. Thus, the dominant aesthetic effect in the capsule (CS) is thermochromism.

(7) Within a second range of temperatures comprising higher temperatures than those of the first range, for example from 10° C. to 30° C., the liquid (L) has a lower density than that which it had in the first range of temperatures. The density of the liquid (L) is such that it is greater than the density of the photochromic particles (B) but lower than the density of the thermochromic particles (A). Thus, the thermochromic particles (A), which are denser, settle out, that is to say sink and are deposited at the bottom of the shell (CQ). On the other hand, the photochromic particles (B) remain in suspension. The dominant aesthetic effect in the capsule (CS) is thus photochromism.

(8) It should be noted that, in one embodiment, the shell (CQ) additionally contains particles of a third type, photoluminescent particles, which make it possible to see coloured transitions by night.

(9) Of course, the present invention is not limited to the example illustrated but is capable of various alternative forms and modifications which appear to a person skilled in the art.