MILL

Abstract

A mill is formed by a plastic rotating part, a high-hardness rotating part, a high-hardness stationary gear, and a plastic stationary part, such that the high-hardness rotating part and the high-hardness stationary gear are provided with a plurality of teeth complementary to one another for the grinding function. The high-hardness gear and the plastic stationary part advantageously have locking means enabling an automatic assembly of the mill, since the mentioned elements are able to easily rest relative to one another in the suitable position and fit together effortlessly.

Claims

1. A mill comprising at least the following elements: a plastic rotating part having an inner surface provided with first anchoring elements, and first support means emerging from an inner central portion of the plastic rotating part; a high-hardness rotating part, provided with second support means, which rest on the first support means and are complementary thereto to prevent rotation of one of the rotating parts with respect to the other; a high-hardness stationary gear having an outer surface provided with first locking means, and a central cavity; a plastic stationary part having an outer surface provided with second anchoring elements along which the first anchoring elements of the plastic rotating part pass; the plastic stationary part being provided with second locking means, which rest on the first locking means of the high-hardness stationary gear and are complementary to the first locking means to prevent the rotation of one of the parts with respect to the other; wherein the high-hardness rotating part has a plurality of teeth on an outer surface and the high-hardness stationary gear has a plurality of teeth on an inner surface, such that when the mill is assembled, a clearance remains between the high-hardness rotating part and the high-hardness stationary gear.

2. The mill according to claim 1, wherein the first support means and the second support means have an arrowhead-like configuration.

3. The mill according to claim 1, wherein the first locking means and the second locking means of the plastic stationary part have an arrowhead-like configuration.

4. The mill according to claim 3, wherein the high-hardness stationary gear has a double stop extending along a perimeter of an upper base.

5. The mill according to claim 1, wherein the high-hardness rotating part rests on the plastic rotating part, by means of a stop to prevent separation of the high-hardness rotating part and the plastic rotating part.

6. The mill according to claim 1, wherein the first anchoring elements are formed by projections, and the second anchoring elements are formed by guiding means.

7. The mill according to claim 1, wherein the high-hardness rotating part and the high-hardness stationary gear are formed by a ceramic material.

8. The mill according to claim 1, wherein the high-hardness rotating part and the high-hardness stationary gear are formed by methacrylate.

9. The mill according to claim 1, wherein the high-hardness rotating part and the high-hardness stationary gear are formed by polycarbonate.

10. The mill according to claim 1, wherein the high-hardness rotating part and the high-hardness stationary gear are formed by metal.

11. The mill according to claim 1, wherein the plastic stationary part has coupling means on its inner surface.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0016] To complement the description that will be provided below and for the purpose of helping to better understand the features of the invention according to a preferred practical embodiment thereof, a set of drawings is attached as an integral part of said description, in which the following has been depicted in an illustrative and non-limiting manner:

[0017] FIG. 1 shows an exploded view of the elements forming the mill according to the preferred embodiment of the invention, where the view is taken from a lower angle to show the inner portion of the plastic rotating part and the plastic stationary part;

[0018] FIG. 2 shows an exploded view of the mill depicted in FIG. 1, where the view is taken from a higher angle;

[0019] FIG. 3 shows a perspective view of the assembly formed by the plastic rotating part and the high-hardness rotating part forming the mill;

[0020] FIG. 4 shows a perspective view of the plastic rotating part; and

[0021] FIG. 5 shows a perspective view of the assembly formed by the high-hardness stationary gear and the plastic stationary part forming the mill.

DETAILED DESCRIPTION OF THE EMBODIMENTS

[0022] The preferred embodiment of the invention is depicted in view of the mentioned figures. Namely, it can be seen in FIGS. 1 and 2 that the mill of the invention is essentially formed by four elements, namely a plastic rotating part (1) formed by a cylindrical cap, a high-hardness rotating part (2) formed by a shaft, a high-hardness stationary gear (3), and a plastic stationary part (4) in the form of a cylindrical base.

[0023] It should be pointed out that the high-hardness rotating part (2) and the high-hardness stationary gear (3) are preferably formed from a ceramic material.

[0024] Nevertheless, said parts can also be made from other high-hardness materials such as methacrylate, polycarbonate, or metal.

[0025] It can thereby be observed in FIGS. 1 and 3 that the plastic rotating part (1) is provided with anchoring elements (11), preferably made up of projections, on its inner surface, and support means (5) in the form of protrusions emerging from the inner central portion of the plastic rotating part (1).

[0026] In this sense, the high-hardness rotating part (2) is provided with complementary support means (6) in the form of recesses to enable resting on the support means (5) of the plastic rotating part (1), thereby preventing the rotation of one rotating part with respect to the other.

[0027] In this sense, it is also necessary for the high-hardness rotating part (2) to be associated with the plastic rotating part (1), without one being able to separate from the other during grinding. To that end, the high-hardness rotating part (2) rests on the support means (5) arranged in the central portion of the plastic rotating part (1), and the separation between them is additionally prevented by the presence of a stop (9), which is preferably made up of a barrier-like rivet for preventing the disengagement of the high-hardness rotating part (2) with respect to the plastic rotating part (1).

[0028] As can be observed in FIGS. 2 and 4, the support means (5) arranged in the central portion of the plastic rotating part (1) and the complementary support means (6) arranged on the inner surface of the high-hardness rotating part (2) are preferably formed by an arrowhead-like configuration of complementary protrusions and recesses. The presence of the mentioned support means with a surface having an arrowhead-like configuration advantageously enables surfaces being supported on other surfaces in a complementary manner when the high-hardness rotating part (2) rests on the plastic rotating part (1), generating a complete fit and coupling between them which prevents the rotation of one element with respect to the other. To that end, it is necessary for the arrowhead-like configuration to be arranged with an opposite orientation between parts in order to allow one part to pass over the other while they are being coupled together.

[0029] It should be pointed out that the mill of the invention has complementary anchoring elements (10), preferably made up of guiding means in the form of ribs, located on the outer surface of the plastic stationary part (4), such that when the plastic rotating part (1) is coupled with the plastic stationary part (4), the anchoring elements (11) present on the inner surface of the plastic rotating part (1) pass over the complementary anchoring elements (10).

[0030] It can be observed in FIGS. 1 and 4 that the high-hardness stationary gear (3) has locking means (7) in the form of protrusions on the outer surface and a central cavity.

[0031] Namely, the locking means (7) present in the high-hardness stationary gear (3) rest on complementary locking means (8) in the form of recesses present in the plastic stationary part (4) for the purpose of preventing the rotation of one element with respect to the other.

[0032] It can thereby be observed in FIGS. 1 and 2 that the locking means (7) arranged on the outer surface of the high-hardness stationary gear (3) and the complementary locking means (8) of the plastic stationary part (4) preferably have an arrowhead-like configuration of protrusions and recesses arranged with an opposite orientation to enable them passing over each other.

[0033] It should be pointed out that the arrowhead-shaped configuration of the support means (5) and (6) and of the locking means (7) and (8) enables an automatic assembly of the mill, since the mentioned elements are able to easily rest relative to one another in the suitable position and fit together effortlessly.

[0034] Likewise, the locking means (7) present in the high-hardness stationary gear (3) preferably include a double stop (7′) of additional protrusions extending along the perimeter of its upper base to facilitate the coupling and locking between the high-hardness stationary gear (3) and the plastic stationary part (4).

[0035] It must be stressed that the high-hardness rotating part (2) has a plurality of teeth (13) on its outer surface, whereas the high-hardness stationary gear (3) has a plurality of teeth (14) on its inner surface, such that all the elements of the mill are coupled together when they are assembled, leaving a clearance between the high-hardness rotating part (2) and the high-hardness stationary gear (3).

[0036] The plastic stationary part (4) advantageously has coupling means (12) in the form of threads on its inner surface for the suitable positioning on the neck of a container or vessel which preferably contains spices, which is not depicted in the figures attached to this specification.