Automatic capping equipment, provided with a sterilizing device

Information

  • Patent Grant
  • 6684603
  • Patent Number
    6,684,603
  • Date Filed
    Friday, May 24, 2002
    22 years ago
  • Date Issued
    Tuesday, February 3, 2004
    20 years ago
Abstract
An automatic capping equipment comprises at least a rotary screwing head (10) able to screw a cap (19) onto the mouth of a container (9) fed below said screwing head (10). The screwing head (10) operates in a sterile area (23) of the equipment (1) and is supported by a related sliding support shaft (12) destined to be animated with an alternating motion, whereto are associated heating means. the heating means (25) are positioned in correspondence with an operating part (12a) of each support shaft (12) proximate to said sterile area (23) and are able to perform a heating action that is localised to said operating part (12a) of the shaft (12) to maintain it at such a temperature as to guarantee its sterile condition and in such a way that the remaining part of each shaft (12) is not substantially heated by the heating means (25).
Description




BACKGROUND OF THE INVENTION AND PRIOR ART




The present invention relates in general to automatic capping equipment.




Automatic capping equipment are machines that allow tightly to close threaded caps or stoppers on the mouth of containers to be packaged, for instance of the kind destined to contain food substances such as drinks. Although capping equipment are known which allow to close a single container at a time, capping machines are widely used which accomplish the operation of closing multiple caps on respective containers that travel along a circular trajectory, which capping machines are known as carrousel machines. More specifically, the invention relates to an automatic capping equipment provided with sterilisation means, having at least a rotary screwing head able to screw a cap onto the mouth of a container fed below the screwing head, in which the screwing head operates in a sterile area of the equipment and is supported by a related sliding support shaft, destined to be animated by an alternating motion, heating means being associated to each support shaft.




When capping equipment needs to be employed for packaging food substances susceptible to being contaminated as a result of contact with the outside environment, such as fruit juice based drinks or vegetable preserves, particularly in the case of products that do not contain preserving additives, the operation of closing the containers housing the product to be packaged must be performed under sterile conditions.




In the past, this was achieved by heating the product to be packaged to such a temperature as to allow its pasteurisation in order to guarantee its sterility.




However, it is well known that heating food products above a determined temperature can cause an alteration thereof, which leads to a reduction of their quality and of their nutritional characteristics.




To overcome this drawback, use is preferred of “cold” packaging equipment in which the product to be packaged is only subjected to a fast heating, with a subsequent cooling, so as not to compromise its nutritional characteristics.




This is due to the fact that the containers with the product to be packaged are fed in an area in which a controlled atmosphere, pressurised with sterile air and previously sterilised with disinfectant substances such as peracetic acid 2% in solution, is present. The screwing head is immersed in this controlled atmosphere, which is usually located in a lower part of the capping equipment, so that it also remains under sterile conditions. However, the shaft that supports the screwing head, due to its alternating motion, can drag into the sterile area impurities coming from the upper part of the equipment (which is not immersed in the controlled atmosphere) in which are located the mechanical devices for the actuation of the screwing heads and the electrical and electronic control sets of the system. These impurities, penetrating into the sterile area where the containers are closed, could compromise the preservation of the sterility and integrity of the product to be packaged.




For this purpose, equipment has been devised that comprises a pressurised system able to supply steam at a temperature of about 120° C. in correspondence with the support shafts in order to maintain them under sterile conditions to prevent impurities coming from other areas of the machine and dragged by the alternating motion of the support shaft from penetrating into the sterile area where the containers are closed, contaminating it.




Capping equipment provided with this steam supplying system, which requires the presence of a steam generator and pipelines to transport the steam to the areas to be sterilised, have a rather complex structure, hence costly to produce. Moreover, the pressurised steam used for heating the support shaft, after exiting the pipelines, does not remain localised in correspondence with the parts of the support shaft that penetrate into the sterile area, but is dispersed towards other parts of the equipment. In particular, after the steam performs its heating action on the shafts, it penetrates in the areas where the mechanical actuation devices and the equipment control sets are present, heating them. Such heating causes thermal expansions of the mechanical organs of the equipment, which can lead to warping in said organs with the consequent reduction of the operational reliability of the equipment and the need to perform more frequent maintenance operations with additional operating costs.




PROBLEM TO BE SOLVED AND MEANS FOR SOLVING THE PROBLEM




The aim of the present invention is to eliminate the aforesaid drawbacks and this is achieved by the equipment of the present invention, which is characterised by the content of the claims set out below and in particular in that the heating means are associated to each support shaft in correspondence with an operating part thereof which is proximate to the sterile area and are able to perform a heating action that is localised to said operating part of the shaft to maintain it at such a temperature as to guarantee its sterile condition and in such a way that the remaining part of each shaft is not substantially heated by the heating means.




The present invention concentrating heat on the area to be protected, unlike the steam that heats the whole turret as in the prior art, allows the application on the turret itself of electronic systems for controlling the capping operation, which allow for instance the automatic ejection of any bottles capped incorrectly.




Thanks to these characteristics, an effective sterility is guaranteed for the equipment area in which the operation of tightly closing the caps onto the related containers takes place, in a simple and reliable manner, without undesired impacts on the operation of other elements of the equipment.




Advantageously, the heating means include at least a resistive organ able to be connected with a source of electrical energy.




Preferably, the equipment further comprises temperature sensor means, the heating means and the temperature sensor means being associated to control means able to regulate in feedback the supply of electrical energy to the resistive organs by said source, according to the temperature measured by the sensor means.




In this way, the temperature of the part of the shaft that supports the related screwing head and that comes in contact with the sterile area of the equipment, can be controlled in optimal fashion so as to remain within a predetermined range, sufficient to guarantee the sterility of this part of the shaft. Thanks to this control which allows to optimise the quantity of heat supplied to each shaft, there is no generation of excess heat which, in addition to constituting a waste and hence an undesired cost, could be transmitted to other parts of the equipment with harmful consequences.











MODES OF EXECUTION




This and other characteristics shall become more readily apparent in the following description of a preferred embodiment illustrated, purely by way of non limiting example, in the accompanying drawing tables in which:





FIG. 1

is a sectioned front elevation view of an automatic capping equipment of the carrousel type, according to the invention,





FIG. 2

is an enlarged view of a part indicated with arrow II in

FIG. 1

,





FIG. 3

is an enlarged view of a detail indicated with arrow III in

FIG. 2

, and





FIG. 4

is a block diagram illustrating in schematic form the main elements of a system for controlling the equipment according to the invention and their operative relationship.











With reference to

FIGS. 1 through 3

, the number


1


globally indicates a capping equipment according to the invention.




Although the accompanying figures and the description that follows consider a carrousel capping equipment, i.e. one that is able simultaneously to accommodate a plurality of containers set in motion on a circular trajectory of the machine to close them by means of caps subjecting the various containers to mutually staggered closing phases, the invention can be indifferently applied to a simpler capping equipment, able to close only a container at a time, individually fed thereto.




The equipment


1


comprises a stationary base structure


2


including pillars


4


. Between the pillars


4


is present a tubular upright


6


so mounted as to be able to revolve about a cylindrical guide


7


whose axis


3


constitutes the main axis of the equipment


1


. The upright


6


is set in rotation as a result of the operation of a motor set not shown herein as it is well known.




To the upright


6


are associated organs


8


for gripping and supporting a plurality of containers


9


, for instance bottles, which are fed to the equipment


1


in usual fashion, typically by means of a conveyor belt and a worm screw feeder. The containers


9


can also be set to bear down onto a rotating platform not shown in the figures.




To the upright


6


is associated a plurality of screwing heads


10


(whereof only two are visible in

FIG. 1

) in such a way as to be able to rotate together with the upright


6


on a circular trajectory concentric with the axis


3


.




Each screwing head


10


is supported by the lower operating part


12




a


of a support shaft


12


, also called piston, able to translate in alternating fashion as a result of the rotation of the upright


6


. For this purpose the upper part


12




b


of each shaft


12


, opposite to the related screwing head


10


, is provided with a roller


14


able to rotate about an axis perpendicular to that of the related shaft


12


. The roller


14


engages a cam track


15


formed on a cylindrical stationary body


16


according to a plane that is inclined relative to the axis


3


in such a way as to exhibit a descending part and an ascending part relative to a horizontal plane perpendicular to the axis


3


.




Each shaft


12


, and hence the related screwing head


10


which is integral in rotation therewith, is also able to rotate about its own axis in such a way that the related screwing head


10


is also animated with rotary motion. Normally, the rotating motion of each shaft


12


is derived from the rotating motion of the upright


6


relative to the base structure


2


by means of known gear wheel transmission organs.




To the base structure


2


is also associated a device


18


for feeding caps


19


between each screwing head


10


and the related container


9


. As a result of the downward motion of each of the screwing heads


10


, i.e. towards the related container


9


, and of the rotation of the screwing head


10


about its own axis, the caps


19


fed by the device


18


are screwed onto the mouth of the containers


19


.




To allow each shaft


12


to move in alternating fashion and simultaneously to rotate about its own axis, to the upright


6


is fastened a pair of annular flanges


21




a


and


21




b


, respectively lower and upper, in which are formed respective through holes aligned in pairs in correspondence with the shafts


12


. To the flanges


21




a


and


21




b


are associated guiding bushings to guide the sliding and the rotation of the shafts


12


.




Below the lower flange


21




a


is defined an area


23


, substantially closed to the outside environment, into which during the sterilisation phase is fed a sterilising agent (for instance a solution containing about 2% of peracetic acid, known also as “Oxonia”, at a temperature of about 40° C.), and during the production phases sterile air is fed, in order to create a controlled atmosphere to maintain under sterile conditions the environment that comes in contact with the product contained in the containers


9


during the closing of the caps


19


.




The part of the equipment


1


above the flange


21




a


is not immersed in the controlled atmosphere present in the area


23


to that, because of the alternating motion of the shafts


12


, impurities present in the part of the equipment above the flange


21




a


can be dragged to the sterile area


23


, which could contaminate it.




To prevent this from occurring, between shelves, hence in proximity to the area


23


, preferably stationary heating means


25


are associated to each shaft


12


, which heating means are destined to perform a heating action localised only to the part


12




a


of the shaft that is proximate to the related screwing head


10


, i.e. to its part that penetrates in alternating fashion into the area


23


, to maintain it at such a temperature as to guarantee its sterility.




These heating means


25


advantageously comprise for each shaft


12


an assembly that comprises a metallic sleeve


26


surrounding a portion of the part


12




a


and fastened, for instance, to the annular flange


21




a


. To the sleeve


26


is externally associated a resistive organ


27


provided with at least an electrical resistance element. Preferably, each resistive organ


27


is armband-shaped and comprises to semi-circular arched portions articulated about a shared axis parallel to the general axis of the sleeve


26


, each of the two arched portions being provided with a resistance element. The two arched portions can assume a mutually approached configuration in which they are in contact with the outer surface of the sleeve


26


, and a mutually distanced configuration in which it is possible to remove the armband-shaped resistive organ


27


from the sleeve


26


transversely to the axis of the shaft


12


.




For instance, each resistance element of a resistive organ


27


is constructed in such a way as to be able to output a thermal power of about 140 W, once connected by means of conductors


27




a


to a source of electrical energy, so that the thermal power supplied to each part


12




a


of a shaft


12


is about 280 W, sufficient to maintain this part at a temperature ranging between about 100° C. and 140° C., during normal operations.




The head supplied by each resistive organ


27


, which is transferred to the part


12




a


through the sleeve


26


, remains prevalently localised in correspondence only with the part


12




a


of the involved shaft


12


, so that the remaining part of the shaft


12


is not substantially heated, or is heated only to a negligible extent, by the heat supplied by the resistive organ


27


. The sleeve


26


preferably extends over a length that is substantially equal, or slightly greater, than the stroke of the shaft


12


. Its function is to serve as a thermal diffusion element for the heat supplied by the resistive organ


27


in order to distribute it in nearly uniform fashion over the portion


12




a


of the shaft


12


.




At the axial ends of each shaft


26


, in proximity to the shelves


21


a and


21




b


, are associated respective thermal insulation heads


28


, made for instance of a thermoplastic material able to withstand high temperature, such as a material known under the commercial name “TekaPeek”.




Between the shaft


12


and the related sleeve


26


is obtained a tubular space in which an air gap is present. In this gap projects a sensitive end of a thermostatic thermocouple or sensor probe


29


mounted on the sleeve


26


in such a way as to traverse it.




The information about the heat measured by each probe


29


is transferred by means of conductors


29




a


towards an electronic control unit


36


(shown in

FIG. 4

) to verify whether the generated heat exceeds a threshold value, in which case the electronic control unit


36


commands the opening of a switching device, described farther on, interposed between the resistive organs


27


and a source of electrical energy supply, until the temperature drops below the threshold, in order to perform a feed-back regulating action on the temperature.





FIG. 4

shows, by way of example, a block diagram schematically illustrating the main elements of a system for controlling the temperature of the shafts


12


for carrousel capping equipment


1


provided with ten screwing heads


10


.




At the sides of each screwing head


10


are present, on one side, a resistive organ


27


and, on the other side, a thermostatic sensor


29


.




The information about the temperature measured by each sensor


29


is collected by means of one or more input modules for thermocouples


30


, each serving as a collector, and sent to an adapter module


32


, for instance with ten inputs and ten digital outputs, of the bus type. Through a rotating distribution module


34


, typically of the eight pole mercury type, the signals are then transferred from the rotating part of the equipment


1


to the electronic control unit


36


, of the PLC type, associated to the stationary part of the equipment. The input signals to the electronic control unit


36


are processed, for instance by comparing the temperature values measured by the sensors


29


to a pre-set threshold value, to generate digital control signals which in turn are transmitted to the adapter module


32


, also through the rotating distribution module


34


, and therefrom to modules


40


containing the switching devices. Said switching devices include static relays driven by means of direct current power supply, for instance at 24V, by a source


38


of direct current electrical energy, which also powers the adapter module


32


in a known manner.




The static relays of the modules


40


are operatively interposed between the resistive organs


27


and a source of electrical energy


44


, typically of the alternating type at 220V, the source


44


being connected to the modules


40


by means of a rotating distribution module


42


of the type with brushes and with rings.




The modules


40


that contain the static relays can be four in the present case of equipment with ten screwing heads


10


, to each whereof are connected two or three resistive organs


27


. Each of the static relays of the modules


40


, thanks to the fact that it has a settable minimum current threshold, is also able to generate an alarm signal in case of malfunction of a resistive organ


27


.



Claims
  • 1. Automatic capping equipment provided with sterilisation means, having at least a rotary screwing head (10) able to screw a cap (19) onto the mouth of a container (9) fed below said screwing head (10), in which the screwing head (10) operates in a sterile area (23) of the equipment (1) and is supported by a related sliding support shaft (12) destined to be animated with an alternating motion, heating means being associated to said support shaft (12),wherein the heating means (25) are associated to said support shaft (12) in correspondence with an operating part (12a) thereof that is moved into and out of to said sterile area (23) for performing a heating action that is localised to said operating part (12a) of the shaft (12) to maintain it at such a temperature as to guarantee its sterile condition and in such a way that the remaining part of each shaft (12) is not substantially heated by the heating means (25).
  • 2. Equipment as claimed in claim 1, wherein the equipment is of the carrousel type and has a plurality of screwing heads (10) so mounted as to be able to revolve about a main axis (3) of the equipment (1) distanced from the axes of the support shafts (12) of the screwing heads (10), each of which is able to screw a cap (19) onto the mouth of a respective container (9) set in rotation about said main axis (3) synchronously with a screwing head (10).
  • 3. Equipment as claimed in claim 1 or 2, wherein the heating means has for each shaft (12) a heating assembly (25), stationary with respect to the related shaft (12).
  • 4. Equipment as claimed in claim 3, wherein said heating assemblies (25) include at least a resistive organ (27) able to be connected with a source of electrical energy (44).
  • 5. Equipment as claimed in claim 4, wherein to each shaft (12) are associated temperature sensor means (29) in correspondence with or in proximity to its operating part (12a).
  • 6. Equipment as claimed in claim 5, wherein the heating means (25) and the temperature sensor means (29) are associated to control means (36, 40) able to perform a feedback regulating action on the supply of electrical energy to the resistive organs (27) by said source (44), according to the temperature measured by the sensor means (29).
  • 7. Equipment as claimed in claim 6, wherein said control means has a control unit (36) whereto are connected the sensor means (29) and a switching device (40) interposed between each resistive organ (27) and said source of electrical energy (44), each switching device (40) being susceptible to being commanded by said control unit (36).
  • 8. Equipment as claimed in any of the claims from 3, wherein each heating assembly (25) includes a metal sleeve (26) which surrounds a related shaft (12), serving as a thermal diffusion element.
  • 9. Equipment as claimed in claim 8, wherein the temperature sensor means has for each support shaft (12) a thermostatic probe (29) which traverses said sleeve (26) and is provided with a sensitive end which projects in an air gap interposed between each sleeve (26) and the related support shaft (12).
  • 10. Equipment as claimed in claim 9, wherein each resistive organ (27) is removable in a direction substantially transverse to the axis of the related shaft (12) and has two arched portions articulated about an axis that is parallel to the general axis of the related sleeve (26), each of said portions being provided with a respective resistance element.
Priority Claims (1)
Number Date Country Kind
01830347 May 2001 EP
US Referenced Citations (2)
Number Name Date Kind
3350839 Carter Nov 1967 A
4742667 Muller et al. May 1988 A
Foreign Referenced Citations (1)
Number Date Country
29505567 Apr 1996 DK