METHOD FOR CLEANING DIE PLATES FOR THE PRODUCTION OF PASTA OR SNACKS AND MACHINE FOR ITS EXECUTION

Abstract

A method for cleaning die plates for the production of pasta or snacks includes:

a first step in which a working fluid is placed in contact with one of two end faces of the die plate to be cleaned, and

a second step, in which the pressure of the working fluid is increased to force the working fluid to penetrate the holes of the die plate in order to push the residue of the mixture, present in the holes, so that it exits from the opposite end face of the die. A machine for cleaning the die plates includes a jacket that internally defines a chamber, an opening, a component for introducing a working fluid into the chamber, and a component for increasing the pressure of the working fluid to force it to pass through the holes of the die plate which are occupied by the mixture to be removed.

Claims

1. A method for cleaning die plates for the production of pasta or snacks, comprising the following steps: a first step, in which a working fluid is placed in contact with one of two end faces of a die plate to be cleaned; and a second step, in which the pressure of said working fluid is increased so as to force said working fluid to penetrate the holes of the die plate in order to push the a residue of a mixture, present in the holes, so that the residue exits from the opposite end face of the die.

2. The method according to claim 1, wherein said working fluid is constituted by a shear thickening fluid.

3. The method according to claim 2, wherein said shear thickening fluid includes a mixture of starch and water.

4. The method according to claim 1, wherein said die plate is arranged so as to close a chamber into which said working fluid is introduced and pressurized.

5. The method according to claim 1, wherein said die plate is arranged so as to close a chamber into which said working fluid is introduced under pressure.

6. A machine for cleaning die plates for the production of pasta or snacks, comprising: a jacket that internally defines a chamber; an opening which is defined in one of the walls of said chamber and is coupled to a die plate to be cleaned which is configured such that one of the end faces is connected to the inside of said chamber; means for introducing a working fluid into said chamber; means adapted to increase the pressure of said working fluid in order to force it to pass through the holes of the die plate which are occupied by the mixture to be removed.

7. The machine according to claim 6, wherein said working fluid includes a shear thickening fluid.

8. The machine according to claim 6, wherein said chamber is substantially cylindrical, said opening being defined at one of the end faces of said jacket, there being means of retaining the die plate so as to close said opening in contrast with the action of said working fluid.

9. The machine according to claim 6, wherein said chamber is delimited, on the opposite side with respect to the opening designed to be occupied by the die plate to be cleaned, by a piston which divides the inside of said jacket into two chambers said chamber or first chamber and a second chamber which is arranged on the opposite side from said first chamber with respect to said piston, said piston being arranged coaxially to said chambers.

10. The machine according to claim 6, wherein said means adapted to increase the pressure of said working fluid comprise means for pumping an actuation fluid under pressure into said second chamber.

11. The machine according to claim 6, comprising means for moving said piston away from the end face of said chamber designed to be occupied by the die plate.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0019] Further characteristics and advantages of the disclosure will become better apparent from the detailed description that follows of a preferred, but not exclusive, embodiment of the method according to the disclosure, as well as of a machine for its execution, which is illustrated for the purposes of non-limiting example in the accompanying drawings wherein:

[0020] FIG. 1 schematically illustrates a machine for executing the method according to the disclosure, in an axially cross-sectional view at the start of the method; and

[0021] FIG. 2 schematically illustrates the machine of FIG. 1 at the end of the method.

DETAILED DESCRIPTION OF THE DRAWINGS

[0022] With reference to the figures, a machine for executing the method according to the disclosure, generally designated by the reference numeral 1, comprises a jacket 2 which defines, internally, a substantially cylindrical chamber 3.

[0023] In one of the walls that delimit the chamber 3, an opening 4 is defined that can be coupled with a die plate 5 to be cleaned so that one of the two end faces of the die plate 5 is connected to the inside of the chamber 3.

[0024] The machine according to the disclosure comprises means 6 of introducing a working fluid into the chamber 3 and means adapted to increase the pressure 7 of the working fluid so as to force it to pass through the holes 8 of the die plate 5 which are occupied by the mixture 9 to be removed.

[0025] Conveniently, the working fluid is constituted by a shear thickening fluid and that is to say by a non-Newtonian fluid the density of which increases as the speed of deformation increases.

[0026] This shear thickening fluid, in consideration of the fact that it is used in the food sector, is preferably constituted by a mixture of starch or potato starch and water.

[0027] In more detail, the chamber 3 is substantially cylindrical and the opening 4, which is intended to receive the die plate 5 to be subjected to cleaning, is defined at one of the two end faces of the chamber 3. At the opening 4 intended to receive the die plate 5, there are means 10 of retaining the die plate 5 so as to close the opening 4 in contrast with the action exerted by the working fluid.

[0028] The means 10 of retaining the die plate 5 comprise a ring 11 which is held in place by a clamping band 12.

[0029] The clamping band 12 engages with a flanging 13 defined at one axial end of the jacket 2 and with a flanging 14 of the ring 11 so as to adequately oppose the pressure exerted by the working fluid on the die plate 5.

[0030] Preferably, the chamber 3 is delimited, on the opposite side from the opening 4 intended to be occupied by the die plate 5, by a piston 15 which is arranged coaxially with the chamber 3.

[0031] Substantially, the piston 15 subdivides the inside of the jacket 2 into two chambers, respectively: the chamber 3, or first chamber, which is axially delimited by an end face of the jacket 2 in which the opening 4 intended to receive the die plate 5 is defined and by a face of the piston 15, and a second chamber 16 which is axially delimited by the opposite face of the piston 15 and by the opposite end face of the jacket 2.

[0032] The means adapted to increase the pressure 7 of the working fluid comprise means of pumping an actuation fluid under pressure into the second chamber 16.

[0033] Preferably these pumping means can be constituted simply by a conventional pump 17, for example a piston pump, a centrifugal pump, a gear pump or other type of pump.

[0034] The chamber 3 is connected to a duct 18 along which is arranged a valve 19 which can be opened in order to actuate the filling of the chamber 3 with the working fluid.

[0035] The machine is further provided with means 20 of moving the piston 15 away from the end face of the jacket 2 which is occupied by the die plate 5 at the end of the method, as will be better described hereinafter.

[0036] More specifically, the piston 15 is provided with a stem 21 which is connected to the face of the piston 15 which delimits the second chamber 16 and which exits from the opposite end face of the jacket 2 with respect to the end face intended to receive the die plate 5.

[0037] The movement means 20 of the piston 15 can be constituted, as illustrated, by two or more fluid-operated actuation cylinders 22 which are mounted with their body on the jacket 2 and which are oriented with their axis parallel to the axis 3a of the chamber 3. The fluid-operated actuation cylinders 22 are pivoted, with the end of the stem of their pistons, to a plate 23 which is fixed to the stem 21 of the piston 15.

[0038] For the sake of completeness of the description it should be noted that, between the die plate 5 subjected to cleaning and the side walls of the chamber 3, there is a sealing gasket 24, just as there are sealing gaskets 25 between the stem 21 of the piston 15 and the jacket 2. Alternatively, the seal between the die plate 5 and the jacket 2, instead of by way of a radial gasket as illustrated, can be provided by way of an axial gasket conveniently forming the part of the jacket 2 that mates with the die plate 5.

[0039] The jacket 2, or preferably the clamping band 12, can be supported by a trolley 26.

[0040] In the embodiment shown, the chamber 3 is arranged with its axis 3a vertical, which appears to be the rationally most correct arrangement, but it can be oriented differently according to requirements.

[0041] Operation of the machine described above in carrying out the method according to the disclosure is the following.

[0042] Initially, the piston 15 is raised completely, as illustrated in FIG. 1, the chamber 3 is empty and the die plate 5 to be subjected to cleaning is coupled with the open lower end face of the chamber 3 and locked by way of the ring 11 and the clamping band 12.

[0043] With the die plate 5 to be subjected to cleaning thus positioned, the chamber 3 is filled with the working fluid by way of opening the valve 19. The air present inside the chamber 3 is progressively evacuated, for example through valves, which are conventional and not shown for the sake of simplicity.

[0044] Once the chamber 3 has been filled with the working fluid, the pump 17 is actuated and introduces an actuation fluid under pressure, for example water, into the second chamber 16 thus causing the descent of the piston 15 and therefore increasing the pressure of the working fluid which progressively penetrates all the holes 8 of the die plate 5, propelling the mixture 9 contained in them outward until all the holes 8 of the die plate 5 are completely cleared, as illustrated in FIG. 2.

[0045] It should be noted that, since the working fluid is constituted preferably by a shear thickening fluid, if one or more holes 8 of the die plate 5 should be cleared of the mixture 9 before the others, at these holes 8 the fluid would undergo a rapid deformation and therefore its viscosity would increase considerably, braking its dispersion outward and therefore maintaining a pressure of the working fluid inside the chamber 3 which is such as to ensure the expulsion of the mixture 9 through the holes 8 of the die plate 5 that are still occluded.

[0046] At the end of the expulsion of the mixture 9 from the holes 8 of the die plate 5, such holes 8 will be occupied by the working fluid which however is much less thick than the mixture 9 and therefore can be removed with great ease, for example with a jet of water.

[0047] After the removal of the die plate 5 from the machine, the piston 15, by way of actuation of the fluid-operated actuation cylinders 22, is lifted and returned to the initial position, while the actuation fluid is evacuated from the second chamber 16, for example by way of a reverse operation of the pump 17.

[0048] In the embodiment shown, the pressure of the working fluid in the chamber 3 is increased by way of the introduction of a fluid under pressure into the second chamber 16; however, the pressure of the working fluid in the chamber 3 could also be increased by mechanically actuating the piston 15, or the piston 15 could be absent and the pressure of the working fluid could be increased directly by introducing the working fluid into the chamber 3 by way of a press, for example a screw press.

[0049] It should be noted that the method according to the disclosure makes it possible to perform the cleaning of die plates using a reduced quantity of water and especially by avoiding an excessive washout of the mixture removed. Thanks to this fact, the method according to the disclosure makes it possible to considerably reduce the quantity of sticky discharge deriving from the operation to clean the die plates compared to the techniques used currently.

[0050] In practice it has been found that the method and the machine according to the disclosure fully achieve the set aim and objects in that, by reducing the quantity of sticky discharge deriving from the cleaning of die plates, it reduces the problems associated with its disposal, avoids the projection of fractions of the waste deriving from cleaning, and reduces the unpleasant-smelling emissions, thus improving the environmental conditions in the rooms used for washing die plates.

[0051] In practice, the materials employed, except where otherwise specified above, as well as the dimensions, may be any according to requirements and to the state of the art.