The invention provides a method of selecting the suitability of a lighting device (100) for use in cheese lighting, the method comprising (a) defining a normalization factor (k) for a spectral power distribution (SPD()) of lighting device light (101) of said lighting device (100) in a wavelength range of 380-780 nm, (b) defining the lighting device (100) suitable for use in cheese lighting when a cheese damage function value (CDFV) is equal to or below 2, wherein the cheese damage function value (CDFV) is defined as: (I) wherein: (II) wherein y () is a 2-degree color matching function, and wherein DF()=1 for 380 nm<410, and wherein for 410780: (III).

[00001]$\begin{array}{cc}\mathrm{CDFV}=k\underset{}{\overset{}{.Math.}}.Math.\mathrm{SPD}\left(\right).Math.\mathrm{DF}\left(\right).Math.& \left(I\right)\\ k=\frac{100}{\underset{}{\overset{}{.Math.}}.Math.\mathrm{SPD}\left(\right).Math.\stackrel{\_}{y}\left(\right).Math.}& \left(\mathrm{II}\right)\\ \mathrm{DF}\left(\right)=0.95e^{-{\left(\frac{-410}{22}\right)}^2}+0.05e^{-{\left(\frac{-410}{105}\right)}^2}& \left(\mathrm{III}\right)\end{array}$

A method of producing cheese, more particularly to a method for producing pierced cheese, and more particularly to a method for producing pierced cheese for slicing.

A transverse cutting roller 1 for the transverse cutting of a flat product moving in a transport direction, in particular a viscous foodstuff, such as industrially produced cheese 14, wherein a transverse cutting blade 3, which bridges the product, which is intended to be cut, transversely to the transport direction, is held on a carrier shaft 2 by a plurality of axially spaced blade carriers 4 mounted on the carrier shaft 2, wherein each blade carrier has at least one carrier element 7, which extends radially outward with respect to the rotational axis A of the carrier shaft 2 when the blade carrier 4 is installed, wherein provided on the outer end of each carrier element 7 is a blade attachment section 5, on which the strip-type blade is detachably attached so as to be radially spaced from the carrier shaft 2.

A transverse cutting roller 1 for the transverse cutting of a flat product moving in a transport direction, in particular a viscous foodstuff, such as industrially produced cheese 14, wherein a transverse cutting blade 3, which bridges the product, which is intended to be cut, transversely to the transport direction, is held on a carrier shaft 2 by a plurality of axially spaced blade carriers 4 mounted on the carrier shaft 2, wherein each blade carrier has at least one carrier element 7, which extends radially outward with respect to the rotational axis A of the carrier shaft 2 when the blade carrier 4 is installed, wherein provided on the outer end of each carrier element 7 is a blade attachment section 5, on which the strip-type blade is detachably attached so as to be radially spaced from the carrier shaft 2.

Equipment for the production of stuffed cheeses, particularly burrata cheese, the equipment (1) comprising: one base frame (2); supporting means (3) of a cheese (C) of the fresh pasta filata type associated with the base frame (2); gripping means (6) of the cheese (C) adapted to retain one portion (P) of the cheese (C); filling means (7) adapted to inject a stuffing inside the cheese (C) through the portion (P) to obtain a stuffed cheese (S); one mutual movement unit (20) between the supporting means (3) and the gripping means (6); and one mutual movement assembly (21) between the gripping means (6) and the filling means (7); wherein the gripping means (6) comprise at least one blade element (34) adapted to cut the portion (P) from the stuffed cheese (S).

Equipment for the production of stuffed cheeses, particularly burrata cheese, the equipment (1) comprising: one base frame (2); supporting means (3) of a cheese (C) of the fresh pasta filata type associated with the base frame (2); gripping means (6) of the cheese (C) adapted to retain one portion (P) of the cheese (C); filling means (7) adapted to inject a stuffing inside the cheese (C) through the portion (P) to obtain a stuffed cheese (S); one mutual movement unit (20) between the supporting means (3) and the gripping means (6); and one mutual movement assembly (21) between the gripping means (6) and the filling means (7); wherein the gripping means (6) comprise at least one blade element (34) adapted to cut the portion (P) from the stuffed cheese (S).

The equipment (1) comprises: supporting means (3) of at least one cheese (C) of the fresh pasta filata type; gripping means (6) adapted to retain at least one portion (P) of the cheese (C); filling means (7) adapted to inject a stuffing inside the cheese (C) to obtain a stuffed cheese (S); one mutual movement unit (20) between the supporting means (3) and the gripping means (6); and one mutual movement assembly (21) between the gripping means (6) and the filling means (7);
wherein the supporting means (3) comprise at least a first container element (51) defining a first housing (51a) adapted to contain the cheese (C) and at least a second container element (52) defining a second housing (52a) adapted to contain the stuffed cheese (S), wherein said housings (51a, 52a) have a relative radius of curvature, the radius of curvature of the second housing (52a) being greater than the radius of curvature of the first housing (51a).

The equipment (1) comprises: supporting means (3) of at least one cheese (C) of the fresh pasta filata type; gripping means (6) adapted to retain at least one portion (P) of the cheese (C); filling means (7) adapted to inject a stuffing inside the cheese (C) to obtain a stuffed cheese (S); one mutual movement unit (20) between the supporting means (3) and the gripping means (6); and one mutual movement assembly (21) between the gripping means (6) and the filling means (7);
wherein the supporting means (3) comprise at least a first container element (51) defining a first housing (51a) adapted to contain the cheese (C) and at least a second container element (52) defining a second housing (52a) adapted to contain the stuffed cheese (S), wherein said housings (51a, 52a) have a relative radius of curvature, the radius of curvature of the second housing (52a) being greater than the radius of curvature of the first housing (51a).

A method of smoke-infusing proteinaceous foods comprises the following sequential steps: a) enclosing the proteinaceous foods in a vacuum-treating zone; b) introducing smoke directly or indirectly from a smoke generation zone into the vacuum-treating zone; c) subjecting the proteinaceous foods to vacuum purging at a negative pressure in the vacuum-treating zone, thereby infusing smoke into the proteinaceous foods; d) repeating the steps of introducing smoke directly or indirectly from the smoke generation zone into the vacuum-treating zone; subjecting the proteinaceous foods to vacuum purging at a negative pressure in the vacuum-treating zone at least fifty times in pulsed sequences of smoke introduction stage/vacuum purging stage/vacuum release stage for the efficient infusion of smoke into the proteinaceous foods; and e) a post-chill resting cycle of the smoke-infused proteinaceous foods at a suitable temperature and for a suitable period of time. An optional modification to the smoke-infusing process is the addition of Cannabis plant material in order to enable the deposition of Cannabis-derived compounds on the surface of the smoke-infused food.

A method of smoke-infusing proteinaceous foods comprises the following sequential steps: a) enclosing the proteinaceous foods in a vacuum-treating zone; b) introducing smoke directly or indirectly from a smoke generation zone into the vacuum-treating zone; c) subjecting the proteinaceous foods to vacuum purging at a negative pressure in the vacuum-treating zone, thereby infusing smoke into the proteinaceous foods; d) repeating the steps of introducing smoke directly or indirectly from the smoke generation zone into the vacuum-treating zone; subjecting the proteinaceous foods to vacuum purging at a negative pressure in the vacuum-treating zone at least fifty times in pulsed sequences of smoke introduction stage/vacuum purging stage/vacuum release stage for the efficient infusion of smoke into the proteinaceous foods; and e) a post-chill resting cycle of the smoke-infused proteinaceous foods at a suitable temperature and for a suitable period of time. An optional modification to the smoke-infusing process is the addition of Cannabis plant material in order to enable the deposition of Cannabis-derived compounds on the surface of the smoke-infused food.