The present invention relates to a levelling device for materials in powder or granule form.
In a preferred but not exclusive manner, the levelling device according to the present invention can be used in systems for pressing ceramic tiles or slabs.
The invention relates in particular to systems for pressing ceramic slabs of large dimensions. These systems substantially envisage the pressing of a layer of soft material previously spread on a conveyor plane that, for at least a section of its path, passes through a press.
The spreading of the material is often irregular because of difficulties related to managing the motion of the powder conveyor plane, due to the irregularity of the plane itself caused by vibrations and oscillations of the system. Even if the thickness of the deposited layer is constant, in any case a more precise adjustment does not allow avoiding the formation of streaks or depressions on the surface of the deposited layer, or differences in the density of the layer of soft material.
The aim of the present invention is to offer a levelling device that makes it possible to overcome the limits and drawbacks of the known devices.
One advantage of the device according to the present invention is that it allows the spreading of a layer of soft material that is homogeneous and of constant thickness, regardless of the advancement velocity of the conveyor plane or the irregularities of the surface itself or the vibrations or oscillations of the system.
Another advantage of the device according to the present invention is that it produces a layer whose surface is free of irregularities.
Further characteristics and advantages of the present invention will become more apparent in the following detailed description of an embodiment of the present invention, illustrated by way of non-limiting example in the attached figures, wherein:
The levelling device according to the present invention comprises a rest plane (2), mobile in advancement along a longitudinal direction (X). Both the rest plane (2) and the longitudinal direction (X) are preferably horizontal.
In a preferred, non-exclusive embodiment, the rest plane (2) comprises a motorised belt which is slidable along a predetermined path that has a main section parallel to the longitudinal direction (X).
The deposit of a layer (L) of a material in powder or granule form on the rest plane (2) can be carried out, for example, by means of a feeding device known in the art, which comprises, for example, at least one hopper (3), arranged above the rest plane (2) and equipped with a discharge opening (4), positioned at a predetermined height above the rest plane (2), as shown in
In a possible alternative embodiment, the rest plane (2) is stationary, while the feeding device is mobile with respect to the rest plane (2) along the longitudinal direction (X).
The soft material, spread on the rest plane with the device briefly described above, or with other known techniques in the field, is arranged in a continuous or discontinuous layer (L) of thickness (S). Thickness (S) is substantially intended as the height of the surface of the layer (L) with respect to the rest plane (2).
The levelling device according to the present invention comprises a leveller (5,6), positioned above the rest plane (2).
The leveller (5,6) is provided with a first element (5), arranged at a first height (H1) that is lower than the thickness (S) of the layer (L). The first element (5) is arranged to interfere with a surface layer (L1) of the layer (L), or with an upper layer of the layer (L). The first element (5) is further arranged to raise the surface layer (L1) to a height that is greater than the thickness (S) thereof.
The leveller (5,6) is further provided with a second element (6), positioned downstream of the first element (5) with respect to the advancement direction and placed at a second height (H2). The second height (H2) is greater than or equal to the first height (H1).
Preferably the second height (H2) is also greater than or equal to the thickness (S) of the layer (L). More preferably, the second height (H2) is greater than the thickness (S) of the layer (L).
The first element (5) is substantially arranged to interfere with a surface layer (L1) of a predetermined thickness of the layer (L) and to rise such surface layer (L1) above the thickness (S).
The device according to the present invention is predisposed to create a relative motion along the longitudinal direction (X) between the rest plane (2) and the leveller (5,6).
Preferably, the layer (L) is brought forward from the rest plane (2) at a velocity suitable to produce a projection or diversion upwards of the surface layer (L1), when the latter comes into contact with the first element (5). In substance, by coming into contact with the first element (5) at a given velocity, the material of the surface layer (L1) is diverted upwards, assuming a velocity directed along a direction which is inclined upwards at a certain angle. This also applies in the case wherein the rest plane (2) is stationary and the leveller (5,6) is translated horizontally along the longitudinal direction (X) with respect to the rest plane (2).
In addition to rising the surface layer (L1), the first element (5) also performs the action of turning and/or unseating an upper layer of the layer (L), or the surface layer (L1), the thickness of which can be adjusted by varying the height of the first element (5). In substance, the first element (5) moves the surface layer (L1), rendering its compactness homogeneous and breaking up any lumps or accumulations that have been further compacted between them.
The first element (5) is structured in such a way as to not retain, or retain only a limited quantity, of surface material of the layer (L), substantially without forming an accumulation of material. To this end, the first element (5) preferably has a limited thickness in the direction perpendicular to the rest plane (2).
As already indicated, by coming into contact with the first element (5) at a given velocity, the material of the surface layer (L1) is diverted upwards, assuming a velocity directed along a direction which is inclined upwards at a certain angle. In the absence of the second element (6), the material of the surface layer (L1) would follow a parabolic trajectory and would be again deposited on the underlying layer (L). In the present invention, before depositing on the layer (L) again, the material of the surface layer (L1) meets the second element (6) and is levelled downwards from the second element (6) which renders its thickness perfectly uniform. In fact, the second element (6) operates on a surface layer which has been shaken and made less compact by the first element (5). The second element (6) distributes the material in a uniform manner and smooths the surface layer (L1) raised by the first element (5), defining a flat surface free of significant irregularities for the subsequent pressing.
The second height (H2) of the second element (6) is also greater than or equal to the thickness (S) of the layer (L). Preferably, the second height (H2) is greater than the thickness (S), and is such as to intercept the surface layer (L1) projected or diverted upwards from the first element (5). The second element (6) equalises and redistributes the material of the surface layer (L1), previously raised by the first element (5). This makes it possible to obtain, downstream of the leveller (5,6), a constant thickness of the layer (L), substantially equal to the thickness (S) of the layer (L) upstream of the leveller (5,6) and a flat and uniform surface. Part of the surface material that comes into contact with the second element (6) is distributed in a transverse direction with respect to the longitudinal direction (X), equalising and compensating all the surface irregularities of the layer (L).
In one possible embodiment, illustrated in
The wire-shaped element (51) can have the shape of a steel bar or wire, the shape of a cable or of a thin sheet or other still.
In one possible embodiment, the second element (6) comprises a lower edge (61), positioned at the second height (H2) above the rest plane (2). For example, the second element (6) comprises a barrier (60) equipped with a lower edge (61), positioned at the second height (H2). The barrier (60) intercepts and redistributes the material of the surface layer (L1) projected upwards from the contact with the first element (5). Downstream of the lower edge (61), the layer of soft material has a constant thickness and a flat surface free of irregularities. Preferably, but not necessarily, the barrier (60) lies on a plane whose inclination is adjustable with respect to a plane that is perpendicular to the rest plane (2). In other words, the barrier (60) can be tilted forward or backwards with respect to the advancement direction of the rest plane (2). The possibility to adjust the inclination of the barrier (60) makes it possible to adapt its action in relation to materials with different compositions and grain sizes, and/or to variations in the speed of the rest plane (2). The barrier (60) can be associated for example with the supporting frame of the rest plane (2), or, in the version wherein the leveller (5,6) is mobile, with a frame that is mobile with respect to the rest plane (2).
The first element (5) and the lower edge (61) of the second element (6) are horizontal, or they lie on horizontal planes. In one possible embodiment, the first element (5) and the lower edge (61) are arranged perpendicularly to the longitudinal direction (X). In another possible embodiment, the first element (5) and the lower edge (61) are inclined with respect to the longitudinal direction (X) on respective horizontal lying planes, with an inclination which is not perpendicular with respect to the longitudinal direction (X). An inclination which is not perpendicular to the longitudinal direction (X), or a diagonal inclination with respect to the longitudinal direction (X), favours the action of the first element (5) and the second element (6) in the creation of a flat surface free of significant irregularities on the surface layer (L1). In the embodiment illustrated herein, the first and second element (5,6) are associated with a supporting frame (T). The leveller (5,6) can be equipped with the possibility of translating in a direction perpendicular to the rest plane (2), to allow the adjustment of the first and of the second height (H1,H2). Means for adjusting which are available to a person skilled in the art can be used to allow the displacement of the leveller (5,6) in a direction perpendicular to the rest plane (2) and/or to vary the orientation or inclination of the first element (5) and the lower edge (61) on the respective horizontal lying planes. Preferably, the first element (5) and the second element (6) are vertically and/or horizontally mobile independently from one another. For example, in the illustrated embodiment, the first and the second element (6) are slidable and lockable in position with respect to the supporting frame (T) independently from one another.
The leveller (5,6) can be further equipped with vibrating means. The use of vibrating means makes it possible to maintain fluid and uniformly distributed material. In particular, in the embodiment comprising the barrier (60), it is possible to arrange vibrating means which act on the barrier (60) itself. This makes it possible to uniformly distribute the material along the entire width of the layer (L).
Number | Date | Country | Kind |
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102018000005064 | May 2018 | IT | national |
Filing Document | Filing Date | Country | Kind |
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PCT/IB2019/053265 | 4/19/2019 | WO | 00 |