EP3594172A1 - Manifold assembly for a filling machine and method for filling a receptacle with a pourable product - Google Patents
Manifold assembly for a filling machine and method for filling a receptacle with a pourable product Download PDFInfo
- Publication number
- EP3594172A1 EP3594172A1 EP19183758.2A EP19183758A EP3594172A1 EP 3594172 A1 EP3594172 A1 EP 3594172A1 EP 19183758 A EP19183758 A EP 19183758A EP 3594172 A1 EP3594172 A1 EP 3594172A1
- Authority
- EP
- European Patent Office
- Prior art keywords
- coolant fluid
- channel
- manifold assembly
- stator
- wall
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
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Classifications
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B67—OPENING, CLOSING OR CLEANING BOTTLES, JARS OR SIMILAR CONTAINERS; LIQUID HANDLING
- B67C—CLEANING, FILLING WITH LIQUIDS OR SEMILIQUIDS, OR EMPTYING, OF BOTTLES, JARS, CANS, CASKS, BARRELS, OR SIMILAR CONTAINERS, NOT OTHERWISE PROVIDED FOR; FUNNELS
- B67C3/00—Bottling liquids or semiliquids; Filling jars or cans with liquids or semiliquids using bottling or like apparatus; Filling casks or barrels with liquids or semiliquids
- B67C3/02—Bottling liquids or semiliquids; Filling jars or cans with liquids or semiliquids using bottling or like apparatus
- B67C3/22—Details
Definitions
- the present invention relates to a manifold assembly for a filling machine apt to fill a plurality of receptacles, in particular containers such as bottles or the like, with a pourable product, preferably of the food type.
- the present invention further relates to a method for filling a receptacle, in particular a container such as a bottle or the like, with a pourable product, preferably of the food type.
- Rotary filling machines which substantially comprise a carousel, rotatable about a vertical axis, a tank containing the pourable product and a plurality of valve filling devices peripherally carried by the carousel in respective radially outer positions relatively to the aforementioned axis. More specifically, the filling devices are advanced along a circular transfer path defined by the carousel.
- each filling device is configured to feed a pre-set amount of pourable product to a respective receptacle, while the latter advances below the relative filling device along the aforementioned transfer path.
- the known filling machines further comprise a manifold assembly configured to fluidically connect the filling devices to the tank.
- the manifold assembly is provided with a manifold, generally arranged concentrically to the axis of the carousel and comprising:
- the first channel receives the pourable product from the tank through the duct;
- the second channel receives, in use, the pourable product from the first channel and is configured to distribute it to the filling devices through the respective openings and through respective pipes.
- each pipe is rotatable about the axis of the carousel integrally with the respective filling device and is configured to fluidically connect the second channel to a single respective filling device.
- the pourable product can be conveyed from the tank, which is fixed, to the filling devices, which are mobile, and, from the latter to respective receptacles to be filled.
- the manifold enables a fluidic connection to be achieved between fixed components and rotating components.
- the manifolds of the known type further comprise one or more sealing elements, operating in a dynamic manner, configured to enable a fluid-tight coupling between the stator and the rotor.
- said manifolds are further provided with one or more mechanical members configured to allow the rotation of the rotor relatively to the stator, for example, bearings, bushings or the like.
- sealing elements, bearings and bushings mentioned above operate at high speeds and, consequently, are subject to overheating which can cause a significant wear and a reduction of their lifespan.
- this object is achieved by a manifold assembly for a filling machine as claimed in claim 1.
- the present invention further relates to a filling method as claimed in claim 12.
- number 1 indicates as a whole a filling machine adapted to fill a plurality of receptacles 2 (only one schematically illustrated in figure 1 ), in particular containers such as bottles or the like, with a pourable product, preferably a pourable food product.
- the filling machine 1 substantially comprises a carousel 3, rotatable about a vertical axis A, a fixed tank 4 (only schematically shown in figure 1 ) containing the pourable product, and a plurality of filling devices 5, preferably valve filling devices 5.
- each filling device 5 is peripherally carried by the carousel 3 in a respective radially outer position relatively to the axis A.
- Each filling device 5 is configured to feed a pre-set amount of pourable product to a respective receptacle 2, while the latter advances below the relative filling device 5 along a circular transfer path defined by the carousel 3.
- each filling device 5 is designed to be selectively moved, according to a known manner and not described in detail, between a closed position, in which it prevents the pourable product from flowing within the respective receptacle 2 and, an open position, in which it allows the outflow of the pourable product within the respective receptacle 2.
- the filling machine 1 further comprises a manifold assembly 6 including, in turn, a manifold 7, the latter having a substantially cylindrical configuration, being arranged concentric to the axis A and being configured to fluidically connect the tank 4 to the filling devices 5.
- a manifold assembly 6 including, in turn, a manifold 7, the latter having a substantially cylindrical configuration, being arranged concentric to the axis A and being configured to fluidically connect the tank 4 to the filling devices 5.
- the manifold 7 comprises:
- the rotor 10 comprises, at one upper end portion 13 thereof, a plurality of radial openings 14, in particular having a circular shape.
- each opening 14 is fluidically connected to the channel 11 on one side and, on the opposite side, it is connected to a respective filling device 5 through a relative pipe 15 extending from the manifold 7 in a substantially radial manner towards the outside relatively to the axis A.
- each pipe 15 is rotatable about the axis A in an integral manner to the respective filling device 5 and to the rotor 10, whereas the duct 4a is fixed and integral to the stator 8.
- the manifold 7 enables a fluidic connection to be achieved between fixed components, namely the tank 4 and the duct 4a, and rotating components, namely the filling devices 5 and the relative pipes 15.
- the rotor 10 comprises:
- the rotor elements 16, 19 and 22 are coaxial to the axis A and have respective cylindrical flanged shapes.
- each rotor element 16, 19 and 22 comprises a hollow cylindrical portion and a flange also being hollow and axially extending from the cylindrical portion.
- the upper flange of the cylindrical element 16 defines the upper portion 13 of the rotor.
- the interface elements are radially interposed between the stator 8 and the rotor 10.
- the bearings 17, 20 and 23 are configured to allow the rotation of the rotor elements 16, 19 and 22 respectively, with respect to the relative portions of the stator 8 with which they cooperate.
- the sealing elements 18, 21 and 24 are carried by the stator 8 and comprise at least an operating portion configured to cooperate in contact, in a dynamic manner, with the rotor 10.
- the sealing elements 18, 21 and 24 are housed in respective dedicated radial grooves obtained in the stator 8 and are configured to cooperate in contact, in a dynamic manner, with the rotor elements 16, 19 and 22, respectively.
- the sealing element 18 is configured to prevent the leaking of the pourable product when the product flows from the channel 9 of the stator 8 to the channel 11 of the rotor 10.
- sealing elements 21 and 24 are configured to prevent the leaking of gas (for example, carbon dioxide or air) from fluidic connection portions, between the stator 8 and the rotor 10, of the pressurisation/discharge and decompression ducts (partially illustrated in figures 1 and 2 and known per se and not described in detail).
- gas for example, carbon dioxide or air
- said connection portions are defined, respectively, by the rotor elements 19 and 22.
- the sealing elements 18, 21 and 24 could be carried by the rotor 10, in respective dedicated radial grooves made in respective rotor elements 16, 19 and 22 and, could comprise at least an operating portion configured to cooperate in contact, and in a dynamic manner, with the stator 8.
- the interface elements namely the bearings 17, 20 and 23 and, the sealing elements 18, 21 and 24 are subjected to overheating, due to the friction to which they are subjected to during their sliding onto the rotor 10 and due to the high operating speeds.
- the manifold assembly 6 further comprises feeding means 50 configured to feed a coolant fluid to at least a heat exchange area 51 between at least one of the aforementioned interface elements, namely the bearings 17, 20 and 23 and the sealing elements 18, 21 and 24 and the coolant fluid.
- the coolant fluid is water.
- the heat exchange area 51 is arranged in a radially outer position relatively to the channel 9 and to the channel 11, with respect to the axis A.
- the manifold 7 comprises at least a wall 25 carried by the stator 8 and defining the heat exchange area 51.
- the coolant fluid is configured to lap, preferably externally, the wall 25 in order to remove an amount of heat that the wall 25 absorbs, in use, from the interface element and therefore to cool the latter.
- the manifold 7 comprises two walls 25 and 26 of the type described above, carried by the stator 8.
- the wall 25 defines the heat exchange area between the coolant fluid and: the bearings 20 and 23; one of the sealing elements 21 (the one axially interposed between the bearings 20 and 23); the sealing element 24. Therefore, the wall 25 absorbs the amount of accumulated heat, due to the friction, from said interface elements.
- the wall 26 defines the heat exchange area 51 between the coolant fluid and: the bearing 20; the other sealing element 21. Therefore, the wall 26 absorbs the amount of accumulated heat, due to friction, from these interface elements.
- the wall 25 is arranged in contact with the bearings 20 and 23 and with the sealing elements 21 and 24, in order to absorb the amount of accumulated heat from said interface elements by heat conduction.
- the wall 26 is arranged in contact with the bearing 20 and with the sealing element 21, in order to absorb the amount of accumulated heat from these latter interface elements by heat conduction.
- the aforementioned feeding means 50 comprise two chambers 27, 28 delimited, respectively, and at least partly, by the walls 25, 26.
- the chamber 27 is delimited by a further radially outermost wall 29 parallel and facing the wall 25, and by another two walls 30 facing one another and orthogonal to the walls 25 and 29.
- the chamber 27 has, therefore, a rectangular cross-section and annularly develops about the axis A.
- the chamber 28 is delimited by a further radially outermost wall 31 parallel and facing the wall 26, and by another two walls 32 facing one another and orthogonal to the walls 26 and 31.
- the chamber 28 has, therefore, rectangular cross-section and annularly develops about the axis A.
- the chamber 27 is arranged above the chamber 28 in respect to the axis A.
- the chambers 27 and 28 are configured to be supplied in a continuous manner with a coolant fluid, through respective inlet openings I, and to be emptied (from the coolant fluid) through respective outlet openings 0.
- the feeding means 50 further comprise a circuit 33 ( figure 3 ) configured to supply the coolant fluid in a continuous manner within the chambers 27 and 28 through the respective inlet openings I, and configured to extract the coolant fluid in a continuous manner from the same chambers 27 and 28, through the respective outlet openings 0.
- a circuit 33 figure 3
- the feeding means 50 further comprise a circuit 33 ( figure 3 ) configured to supply the coolant fluid in a continuous manner within the chambers 27 and 28 through the respective inlet openings I, and configured to extract the coolant fluid in a continuous manner from the same chambers 27 and 28, through the respective outlet openings 0.
- the circuit 33 comprises:
- the cooler 36 ensures an optimal adjustment of the coolant fluid temperature, in order to obtain a effective heat exchange, in particular a cooling, between the interface elements and the coolant fluid itself.
- the rotor 10 rotates about the axis A at a given speed and the interface elements are, therefore, subjected to an overheating caused by friction, due to the sliding of the same onto the respective outer surfaces of the rotor elements 16, 19 and 22.
- the coolant fluid is conveyed, by means of the circuit 33, to the inside of the cooler 36 and, subsequently to the inside of the chambers 27 and 28, so as to lap the walls 25 and 26, respectively.
- the coolant fluid removes the heat absorbed by the walls 25 and 26.
- the heated coolant fluid exits the chambers 27 and 28 through the respective outlet openings 0 and is recirculated inside the cooler 36, in order to lower the temperature.
- the cooled coolant fluid is again, redirected towards the chambers 27 and 28 and the cooling process is repeated.
- the circuit 33 is a closed circuit.
- number 106 indicates as a whole, a second preferred embodiment of the manifold assembly according to the present invention.
- manifold assembly 106 Since the manifold assembly 106 is similar, in terms of its operation, to the manifold assembly 6, the description that follows will be limited to the structural differences between the two manifold assemblies 6, 106; the parts of the manifold assembly 106 that are the same or correspond to parts already described, in relation to the manifold assembly 6, will be indicated by using, whenever possible, the same references.
- the manifold 7 of the manifold assembly 106 comprises a thrust bearing plate 117 that operates in the same manner as the bearing 17 of the manifold 7 of the manifold assembly 6.
- the manifold assembly 106 comprises feeding means 150 including, in turn, three spraying members, preferably three nozzles 108 configured to spray the coolant fluid directly on radially outer surfaces 25a and 26a of the walls 25 and 26, respectively, defining the heat exchange area 51.
- the feeding means 150 further comprise, a circuit 133 configured to supply the coolant fluid in a continuous manner to the spraying members 108.
- the circuit 133 of the manifold assembly 106 is similar to the circuit 33 of the manifold assembly 6. Even more in particular, the circuit 133 differs from the circuit 33 due to the fact that it is an open circuit.
- the manifold assembly 106 is different from the manifold assembly 6 due to the fact that the stator 8 of the manifold 7 of the manifold assembly 106 comprises a hollow cylindrical stator element 110, radially interposed between the rotor element 16 and the rotor element 19 and coaxial to the axis A.
- stator element 110 externally cooperates with the rotor element 19 by means of a further sealing element 111, carried by the stator element 110 itself in a dedicated radial groove.
- the coolant fluid sprayed by the nozzles 108 laps the surfaces 25a and 26a, removing the heat accumulated by the interface elements and absorbed by the walls 25 and 26 and, therefore, cools said interface elements.
- the coolant fluid runs axially, due to gravity, firstly along the surface 25a and then along the surface 26a, until lapping the area of the manifold 7 of the manifold assembly 106 at which the sealing element 18 and the thrust bearing plate 117 are axially arranged.
- the coolant fluid after having been sprayed by the nozzles 108, is not reintroduced in the circuit 133. Therefore, a new amount of coolant fluid is added in a continuous manner within the circuit 133, drawn from the relative tank 34.
- feeding means 50, 150 for the coolant fluid allows an efficient cooling of the interface elements 17, 18, 20, 21, 23, 24, 111, 117 interposed between the stator 8 and the rotor 10, limiting in this manner, the wear and increasing their lifespan.
- the feeding means 50, 150 could comprise, simultaneously, both the chambers 27 and 28, as well as the nozzles 108, or any one of their combinations, for example, a single chamber 27, 28 and two nozzles 108, or two chambers 27, 28 and one nozzle 108 apt to spray coolant fluid in the area of the sealing element 18 and of the bearing 17/thrust bearing plate 117.
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- Motor Or Generator Cooling System (AREA)
Abstract
Description
- The present invention relates to a manifold assembly for a filling machine apt to fill a plurality of receptacles, in particular containers such as bottles or the like, with a pourable product, preferably of the food type.
- The present invention further relates to a method for filling a receptacle, in particular a container such as a bottle or the like, with a pourable product, preferably of the food type.
- Rotary filling machines are known, which substantially comprise a carousel, rotatable about a vertical axis, a tank containing the pourable product and a plurality of valve filling devices peripherally carried by the carousel in respective radially outer positions relatively to the aforementioned axis. More specifically, the filling devices are advanced along a circular transfer path defined by the carousel.
- In detail, each filling device is configured to feed a pre-set amount of pourable product to a respective receptacle, while the latter advances below the relative filling device along the aforementioned transfer path.
- Typically, the known filling machines further comprise a manifold assembly configured to fluidically connect the filling devices to the tank.
- In detail, the manifold assembly is provided with a manifold, generally arranged concentrically to the axis of the carousel and comprising:
- a stator having substantially cylindrical configuration and defining a first channel for the pourable product fluidically connected to the tank by means of a duct; and
- a rotor also having a substantially cylindrical configuration, which defines a second channel fluidically connected to the first channel, is rotatable, relatively to the stator, about the axis of the carousel, and comprises a plurality of openings, each fluidically connected to the second channel and to a respective filling device.
- In detail, the first channel receives the pourable product from the tank through the duct; the second channel receives, in use, the pourable product from the first channel and is configured to distribute it to the filling devices through the respective openings and through respective pipes.
- In particular, each pipe is rotatable about the axis of the carousel integrally with the respective filling device and is configured to fluidically connect the second channel to a single respective filling device.
- In this way, the pourable product can be conveyed from the tank, which is fixed, to the filling devices, which are mobile, and, from the latter to respective receptacles to be filled.
- Therefore, the manifold enables a fluidic connection to be achieved between fixed components and rotating components.
- The manifolds of the known type further comprise one or more sealing elements, operating in a dynamic manner, configured to enable a fluid-tight coupling between the stator and the rotor.
- Generally, said manifolds are further provided with one or more mechanical members configured to allow the rotation of the rotor relatively to the stator, for example, bearings, bushings or the like.
- In particular the sealing elements, bearings and bushings mentioned above operate at high speeds and, consequently, are subject to overheating which can cause a significant wear and a reduction of their lifespan.
- It is therefore an object of the present invention to provide a manifold assembly for a filling machine, which allows to overcome the above-mentioned drawback in a straightforward and low-cost manner.
- According to the invention, this object is achieved by a manifold assembly for a filling machine as claimed in claim 1.
- The present invention further relates to a filling method as claimed in
claim 12. - For a better understanding of the present invention, two preferred non-limiting embodiments will be described in the following, purely by way of example and with the aid of the attached figures, wherein:
-
Figure 1 is a schematic side view, partially sectioned and with parts removed for clarity, of a filling machine comprising a manifold assembly implemented according to a first preferred embodiment of the present invention; -
Figure 2 is a larger-scale section view with parts removed for clarity of part of the manifold assembly offigure 1 ; -
Figure 3 schematically illustrates some of the components of the manifold assembly offigure 2 ; -
Figure 4 is a section view, with parts removed for clarity, of a manifold assembly implemented according to a second preferred embodiment of the present invention; and -
Figure 5 schematically illustrates some of the components of the manifold assembly offigure 4 . - With reference to the attached figures, number 1 indicates as a whole a filling machine adapted to fill a plurality of receptacles 2 (only one schematically illustrated in
figure 1 ), in particular containers such as bottles or the like, with a pourable product, preferably a pourable food product. - The filling machine 1 substantially comprises a
carousel 3, rotatable about a vertical axis A, a fixed tank 4 (only schematically shown infigure 1 ) containing the pourable product, and a plurality offilling devices 5, preferablyvalve filling devices 5. - In particular, each
filling device 5 is peripherally carried by thecarousel 3 in a respective radially outer position relatively to the axis A. - Each
filling device 5 is configured to feed a pre-set amount of pourable product to arespective receptacle 2, while the latter advances below therelative filling device 5 along a circular transfer path defined by thecarousel 3. - Preferably, each
filling device 5 is designed to be selectively moved, according to a known manner and not described in detail, between a closed position, in which it prevents the pourable product from flowing within therespective receptacle 2 and, an open position, in which it allows the outflow of the pourable product within therespective receptacle 2. - The filling machine 1 further comprises a
manifold assembly 6 including, in turn, amanifold 7, the latter having a substantially cylindrical configuration, being arranged concentric to the axis A and being configured to fluidically connect the tank 4 to thefilling devices 5. - As can be seen in
figure 2 , themanifold 7 comprises: - a
hollow stator 8, substantially cylindrical and internally defining achannel 9 coaxial to the axis A and fluidically connected to the tank 4 by means of aduct 4a (illustrated infigure 1 ); and - a
rotor 10, also being hollow, substantially cylindrical and coaxial to thestator 8, defining achannel 11 coaxial to thechannel 9 and fluidically connected thereto by means of anaxial opening 12, and rotatable about the axis A relatively to thestator 8. - Preferably, the
rotor 10 comprises, at oneupper end portion 13 thereof, a plurality ofradial openings 14, in particular having a circular shape. - In detail, each
opening 14 is fluidically connected to thechannel 11 on one side and, on the opposite side, it is connected to arespective filling device 5 through arelative pipe 15 extending from themanifold 7 in a substantially radial manner towards the outside relatively to the axis A. In particular, eachpipe 15 is rotatable about the axis A in an integral manner to therespective filling device 5 and to therotor 10, whereas theduct 4a is fixed and integral to thestator 8. - In light of what has been described above, the
manifold 7 enables a fluidic connection to be achieved between fixed components, namely the tank 4 and theduct 4a, and rotating components, namely thefilling devices 5 and therelative pipes 15. - According to the preferred and non-limiting embodiment illustrated in
figure 2 , therotor 10 comprises: - a
first rotor element 16 arranged, at least partly, within thestator 8 and externally cooperating with the latter by means of first interface elements, in particular abearing 17 and asealing element 18; - a
second rotor element 19 surrounding at least part of therotor element 16 arranged, at least partly, within thestator 8 and cooperating externally with the latter by means of second interface elements, in particular a radial bearing 20 and twosealing elements 21, arranged on axially opposite sides of thebearing 20; - a
third rotor element 22 surrounding at least part of therotor elements stator 8 and cooperating externally with the latter by means of third interface elements, in particular aradial bearing 23 and asealing element 24. - Preferably, the
rotor elements - In detail, each
rotor element cylindrical element 16 defines theupper portion 13 of the rotor. - As can be seen in
figure 2 , the interface elements are radially interposed between thestator 8 and therotor 10. - In particular, the
bearings rotor elements stator 8 with which they cooperate. - Preferably, the
sealing elements stator 8 and comprise at least an operating portion configured to cooperate in contact, in a dynamic manner, with therotor 10. - In the specific case described herein, the
sealing elements stator 8 and are configured to cooperate in contact, in a dynamic manner, with therotor elements - According to a known manner not described in detail, the sealing
element 18 is configured to prevent the leaking of the pourable product when the product flows from thechannel 9 of thestator 8 to thechannel 11 of therotor 10. - In addition, the
sealing elements stator 8 and therotor 10, of the pressurisation/discharge and decompression ducts (partially illustrated infigures 1 and2 and known per se and not described in detail). In particular, said connection portions are defined, respectively, by therotor elements - According to a possible alternative not illustrated herein, the
sealing elements rotor 10, in respective dedicated radial grooves made inrespective rotor elements stator 8. - In use the interface elements, namely the
bearings sealing elements rotor 10 and due to the high operating speeds. - Advantageously, the
manifold assembly 6 further comprises feeding means 50 configured to feed a coolant fluid to at least aheat exchange area 51 between at least one of the aforementioned interface elements, namely thebearings sealing elements - Preferably the coolant fluid is water.
- In particular, the
heat exchange area 51 is arranged in a radially outer position relatively to thechannel 9 and to thechannel 11, with respect to the axis A. - In detail, the
manifold 7 comprises at least awall 25 carried by thestator 8 and defining theheat exchange area 51. - In greater detail, the coolant fluid is configured to lap, preferably externally, the
wall 25 in order to remove an amount of heat that thewall 25 absorbs, in use, from the interface element and therefore to cool the latter. - According to the preferred yet non-limiting embodiment described and illustrated herein, the
manifold 7 comprises twowalls stator 8. - In particular the
wall 25 defines the heat exchange area between the coolant fluid and: thebearings bearings 20 and 23); thesealing element 24. Therefore, thewall 25 absorbs the amount of accumulated heat, due to the friction, from said interface elements. - The
wall 26 defines theheat exchange area 51 between the coolant fluid and: thebearing 20; theother sealing element 21. Therefore, thewall 26 absorbs the amount of accumulated heat, due to friction, from these interface elements. - In particular, the
wall 25 is arranged in contact with thebearings sealing elements - In the same manner, the
wall 26 is arranged in contact with thebearing 20 and with the sealingelement 21, in order to absorb the amount of accumulated heat from these latter interface elements by heat conduction. - Preferably, the aforementioned feeding means 50 comprise two
chambers walls - In detail, the
chamber 27 is delimited by a further radiallyoutermost wall 29 parallel and facing thewall 25, and by another twowalls 30 facing one another and orthogonal to thewalls chamber 27 has, therefore, a rectangular cross-section and annularly develops about the axis A. - In the same manner, the
chamber 28 is delimited by a further radiallyoutermost wall 31 parallel and facing thewall 26, and by another twowalls 32 facing one another and orthogonal to thewalls chamber 28 has, therefore, rectangular cross-section and annularly develops about the axis A. - In particular, the
chamber 27 is arranged above thechamber 28 in respect to the axis A. - In detail, the
chambers respective outlet openings 0. - For this purpose, the feeding means 50 further comprise a circuit 33 (
figure 3 ) configured to supply the coolant fluid in a continuous manner within thechambers same chambers respective outlet openings 0. - As can be seen in
figure 3 , thecircuit 33 comprises: - a source, preferably a
tank 34, containing the coolant fluid; -
ducts 35, configured to convey the coolant fluid from thetank 34 inside therespective chambers - a cooler 36 configured to lower the temperature of the coolant fluid, in respect to a given network temperature, before the latter laps the
walls - In detail, the cooler 36 ensures an optimal adjustment of the coolant fluid temperature, in order to obtain a effective heat exchange, in particular a cooling, between the interface elements and the coolant fluid itself.
- The operation of the
manifold assembly 6 according to the present invention will be described in the following, with reference to a regime operating condition wherein the pourable products flows from thechannel 9 of thestator 8 towards thechannel 11 of therotor 10 and from the latter towards each fillingdevice 5 through therelative opening 14 and the correspondingpipe 15. - In this condition, the
rotor 10 rotates about the axis A at a given speed and the interface elements are, therefore, subjected to an overheating caused by friction, due to the sliding of the same onto the respective outer surfaces of therotor elements - With the aim of removing the accumulated heat from the interface elements, the coolant fluid is conveyed, by means of the
circuit 33, to the inside of the cooler 36 and, subsequently to the inside of thechambers walls - Therefore, the coolant fluid removes the heat absorbed by the
walls - Subsequently, the heated coolant fluid exits the
chambers respective outlet openings 0 and is recirculated inside the cooler 36, in order to lower the temperature. - Therefore, the cooled coolant fluid is again, redirected towards the
chambers - In order to tackle the possible loss of coolant fluid, a new amount of coolant fluid, drawn from the
tank 34, is periodically added. Therefore, thecircuit 33 is a closed circuit. - In
figure 4 ,number 106 indicates as a whole, a second preferred embodiment of the manifold assembly according to the present invention. - Since the
manifold assembly 106 is similar, in terms of its operation, to themanifold assembly 6, the description that follows will be limited to the structural differences between the twomanifold assemblies manifold assembly 106 that are the same or correspond to parts already described, in relation to themanifold assembly 6, will be indicated by using, whenever possible, the same references. - In particular, the
manifold 7 of themanifold assembly 106 comprises athrust bearing plate 117 that operates in the same manner as the bearing 17 of themanifold 7 of themanifold assembly 6. - Furthermore, according to this second preferred embodiment of the present invention, the
manifold assembly 106 comprises feeding means 150 including, in turn, three spraying members, preferably threenozzles 108 configured to spray the coolant fluid directly on radiallyouter surfaces walls heat exchange area 51. - As illustrated in
figure 5 , the feeding means 150 further comprise, acircuit 133 configured to supply the coolant fluid in a continuous manner to the sprayingmembers 108. - In particular, the
circuit 133 of themanifold assembly 106 is similar to thecircuit 33 of themanifold assembly 6. Even more in particular, thecircuit 133 differs from thecircuit 33 due to the fact that it is an open circuit. - Furthermore, as can be seen in
figure 4 , themanifold assembly 106 is different from themanifold assembly 6 due to the fact that thestator 8 of themanifold 7 of themanifold assembly 106 comprises a hollowcylindrical stator element 110, radially interposed between therotor element 16 and therotor element 19 and coaxial to the axis A. - In particular, the
stator element 110 externally cooperates with therotor element 19 by means of afurther sealing element 111, carried by thestator element 110 itself in a dedicated radial groove. - Only the differences between the operation of the
manifold assembly 6 and the operation of themanifold assembly 106 are illustrated hereinafter. - In detail, the coolant fluid sprayed by the
nozzles 108 laps thesurfaces walls - Furthermore, the coolant fluid runs axially, due to gravity, firstly along the
surface 25a and then along thesurface 26a, until lapping the area of themanifold 7 of themanifold assembly 106 at which the sealingelement 18 and thethrust bearing plate 117 are axially arranged. - In this manner, also the latter interface elements are cooled.
- In light of what has been described above, the coolant fluid, after having been sprayed by the
nozzles 108, is not reintroduced in thecircuit 133. Therefore, a new amount of coolant fluid is added in a continuous manner within thecircuit 133, drawn from therelative tank 34. - From an examination of the characteristics of the
manifold - In particular, the presence of feeding means 50, 150 for the coolant fluid according to the present invention allows an efficient cooling of the
interface elements stator 8 and therotor 10, limiting in this manner, the wear and increasing their lifespan. - It is clear that modifications and variations can be made to the
manifold assembly - In particular, the feeding means 50, 150 could comprise, simultaneously, both the
chambers nozzles 108, or any one of their combinations, for example, asingle chamber nozzles 108, or twochambers nozzle 108 apt to spray coolant fluid in the area of the sealingelement 18 and of thebearing 17/thrust bearing plate 117.
Claims (14)
- A manifold assembly (6; 106) for a filling machine (1) apt to fill a plurality of receptacles (2) with a pourable product; said assembly (6; 106) comprising a manifold (7) provided with:- a stator (8) defining a first channel (9) configured to be fed with said pourable product; and- a rotor (10) rotatable in respect to said stator (8) about an axis (A) and defining a second channel (11) fluidically connected to said first channel (9);said rotor (10) comprising at least one opening (14) fluidically connected to said second channel (11) and fluidically connectable, in use, to at least one respective filling device (5) of said filling machine (1);
said manifold (7) further comprising at least one interface element (17, 18, 20, 21, 23, 24; 111, 117) interposed between said stator (8) and said rotor (10) and subject, in use, to overheating;
characterized in that it further comprises feeding means (50, 150) configured to feed a coolant fluid to at least a heat exchange area (51) between said interface element (17, 18, 20, 21, 23, 24; 111, 117) and said coolant fluid. - The manifold assembly according to claim 1, wherein said heat exchange area (51) is arranged in a position radially external to said first channel (9) and said second channel (11).
- The manifold assembly according to claim 1 or 2, wherein said manifold (7) comprises at least a wall (25, 26) defining said heat exchange area (51); said coolant fluid lapping, in use, said wall (25, 26) in order to remove an amount of heat absorbed by said wall (25, 26) and, therefore, to cool said interface element (17, 18, 20, 21, 23, 24; 111, 117).
- The manifold assembly according to claim 3, wherein said wall (25, 26) is arranged in contact with said interface element (17, 18, 20, 21, 23, 24; 111, 117), so that said wall (25, 26) absorbs said amount of heat from said interface element (17, 18, 20, 21, 23, 24; 111, 117) through conduction; and/or wherein said wall (25, 26) is carried by said stator (8).
- The manifold assembly according to any one of the claims 2 to 4, wherein said feeding means (50) comprise at least a chamber (27, 28) delimited, at least partly, by said wall (25, 26) and configured to be fed in a continuous manner with said coolant fluid through an inlet opening (I), and to be emptied via an outlet opening (0).
- The manifold assembly according to claim 5, wherein said feeding means (50) further comprise a circuit (33) configured to feed, in a continuous manner, said coolant fluid to said chamber (27, 28), through said inlet opening (I), and to extract, in a continuous manner, said coolant fluid from said chamber (27, 28), via said outlet opening (0).
- The manifold assembly according to any one of the claims 2 to 4, wherein said feeding means (150) comprise at least one spraying member (108) configured to spray said coolant fluid directly on a radially outer surface (25a, 26a) of said wall (25, 26).
- The manifold assembly according to claim 7, wherein said feeding means (150) further comprise a circuit (133) configured to feed, in a continuous manner, said coolant fluid to said spraying member (108).
- The manifold assembly according to any one of the preceding claims, wherein said interface element (17, 18, 20, 21, 23, 24; 111, 117) defines at least a sealing element (18, 21, 24; 111) comprising at least an operating portion configured to cooperate in contact with one of said rotor (10) and said stator (8).
- A filling machine (1) adapted to fill a plurality of receptacles (2) with a pourable product; said filling machine (1) comprising:- at least a filling device (5) configured to feed said pourable product to a respective receptacle (2);- a fixed tank (4) containing said pourable product and fluidically connectable to said at least one filling device (5); and- a manifold assembly (6; 106) according to any one of the preceding claims.
- The filling machine according to claim 10, when depending from claim 6 or 8, wherein said circuit (33; 133) further comprises a cooler (36) configured to lower the temperature of said coolant fluid, in respect to a given network temperature, before the latter laps said wall (25, 26).
- A method for filling a receptacle (2) with a pourable product, by means of a filling device (5), comprising the steps of:i) feeding said pourable product to a manifold assembly (6; 106) comprising a manifold (7) comprising, in turn:- a stator (8), defining a first channel (9) which can be fed with said pourable product; and- a rotor (10) rotatable, in respect to said stator (8), about a given axis (A) and defining a second channel (11) fluidically connected to said first channel (9);- at least an interface element (17, 18, 20, 21, 23, 24; 111, 117) interposed between said stator (8) and said rotor (10) and subject to heating;ii) feeding said pourable product to said filling device (5) by means of an opening (14) of said rotor (10) fluidically connected to said second channel (11) and fluidically connectable to said filling device (5); andiii) feeding said pourable product to said receptacle (2) by means of said filling machine (5);characterized in that it also comprises the step of:
iv) adducing a coolant fluid to a heat exchange area (51) between said interface element (17, 18, 20, 21, 23, 24; 111, 117) and said coolant fluid. - The method according to claim 12, wherein said heat exchange area (51) is radially external to said first channel (9) and said second channel (11).
- The method according to claim 12 or 13, further comprising the steps of:
v) adducing said coolant fluid to a wall (25, 26) defining said heat exchange area (51); said coolant fluid lapping, in use, said wall (25, 26) so as to remove an amount of heat absorbed by said wall (25, 26) and, therefore, to cool said interface element (17, 18, 20, 21, 23, 24; 111, 117).
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
IT201800007135 | 2018-07-12 |
Publications (1)
Publication Number | Publication Date |
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EP3594172A1 true EP3594172A1 (en) | 2020-01-15 |
Family
ID=63762880
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
EP19183758.2A Withdrawn EP3594172A1 (en) | 2018-07-12 | 2019-07-02 | Manifold assembly for a filling machine and method for filling a receptacle with a pourable product |
Country Status (1)
Country | Link |
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EP (1) | EP3594172A1 (en) |
Citations (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
EP2070865A1 (en) * | 2007-12-14 | 2009-06-17 | KRONES Aktiengesellschaft | Rotary distributor with leakage detection |
WO2019048615A1 (en) * | 2017-09-07 | 2019-03-14 | Krones Ag | Revolving distributor for distributing flowable media |
-
2019
- 2019-07-02 EP EP19183758.2A patent/EP3594172A1/en not_active Withdrawn
Patent Citations (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
EP2070865A1 (en) * | 2007-12-14 | 2009-06-17 | KRONES Aktiengesellschaft | Rotary distributor with leakage detection |
WO2019048615A1 (en) * | 2017-09-07 | 2019-03-14 | Krones Ag | Revolving distributor for distributing flowable media |
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