CARMICHAEL James (Via La Spezia 241/A, PARMA, 43100, IT)
| CLAIMS 1.- Modular element (la, lb; la', lb'; la'', lb''; la' ' ' , lb' ' ' ; la' ' ' ' , lb' ' ' ' ) for a container processing machine (2) , characterized by comprising: - at least one first support element (20a, 20b; 20a' , 20b' ; 20a' ' ' , 20b' " ) ; - first releasable connecting means (30a, 30a') for releasably connecting said first support element (20a, 20b; 20a', 20b'; 20a''', 20b''') to either a fixed structure (5) of said container processing machine (2) or to a further support element (20b, 20a; 20b' , 20a' ; 20b''', 20a''') of a further modular element (lb, la; lb', la'; lb'', la''; lb''', la'''; lb'''', la''''); and - at least one first worm-screw (11a, lib; 11a', lib'; 11a''', lib'''; 11a'''', lib'''') which may rotate about a first axis (A, E; A', E' ; A'''', E' ''') with respect to said first support element (20a, 20b; 20a', 20b'; 20a''', 20b'''), and is adapted to cooperate with a first portion (8a, 8b) of at least two containers (3) advancing on a conveyor (6) in order to distance them at a given pitch; said first worm-screw (11a, lib; 11a', lib'; 11a''', lib'''; 11a'''', lib'''') being fixed relative to said first support element (20a, 20b; 20a', 20b'; 20a''', 20b''') with respect to a second axis (B, F; B', F ' ) transversal to said first axis (A, E; A', E'; A'''', E ' ' ' ' ) and with respect to a third axis (C, G; C, G ' ) transversal to said first axis (A, E; A', E'; A'''', E ' ' ' ' ) and said second axis (B, F; B' , F' ) ; said first support element (20a, 20b; 20a', 20b'; 20a''', 20b''') supporting said first axis (A, E; A', E ' ; A''''', E'''') of said first worm-screw (11a, lib; 11a', lib'; 11a' ", lib'''; 11a'''', lib'''') at a first distance (L]_, M]_, χ ' , Οχ ' ) from a fourth fixed reference axis (D) measured parallel to said second axis (B, F; B' , F') and at a second distance (L2, M2 , N2 ' , O2 ' ) from said fourth axis (D) measured parallel to said third axis (C, G; C, G' ) ; at least one between said first and second distances (L]_, L2; M]_, M2 ; ]_ ' , N2 ' ; Οχ ' , O2 ' ) being associated to the format of said containers (3) to be conveyed . 2.- The modular element according to claim 1, characterized by comprising a pair of said first support elements (20a, 20b; 20a', 20b'; 20a''', 20b''') arranged on respective opposite axial sides with respect to said first axis (A, E; A', E' ; A'''', E ' ' ' ' ) of said first worm screw (11a, lib; 11a', lib'; 11a''', lib'''; 11a' ' ' ' , lib' ' ' ' ) . 3. - The modular element according to claim 1 or 2 , characterized in that said first support element (20a, 20b; 20a', 20b'; 20a''', 20b-''') comprises: - a first main portion (21a, 21b) carrying said first releasable connecting means (30a, 30b) ; and - a first end portion (22a, 22b) connected to said first main portion (21a, 21b) and defining an apex (23a, 23b) which protrudes, in use, towards said further conveyor (6); said first worm-screw (11a, lib; 11a', lib'; 11a''', lib'''; 11a' ''', lib'''') being rotatably fitted to said apex (23a, 23b) about said first axis (A, E; A' , E' ; A' ' ' ' , E' ' ' ' ) . 4. - A conveying unit (4), comprising: - a first motor (40a, 40b, 40a ,'( 40a''''); and at least one first modular element (la, lb; la', lb'; la''', lb'''; la'''', lb'''') according to anyone of previous claims; a first motion transmission element (41a, , 41a''', 41a''''; 41b) functionally interposed between said first worm-screw (11a, lib; 11a', lib'; 11a''', lib' ' ' ; 11a' ' ' ' , lib' ' ' ' ) of said modular element (la, lb; la', lb'; la''', lb'''; la'''', lb'''') and said first motor (40a, 40b, 40a''', 40a''''); said transmission element (41a, 41b, 41a' ' ' , 41a'''') being capable of transmitting the motion between two direction parallel or coincident to one another . 5. - The conveying unit according to claim 4, characterized in that said transmission element (41a, , 41a''', 41a''''; 41b) is a first joint (41a, 41a''', 41a' ' ' ' ; 41b) which comprises a first shaft (42a, 42a' ' ' , 42a' ' ' ' , 42b) ; said first shaft (42a, 42a''', 42a'''', 42b) being connected with a first output shaft of said first motor (40a, 40b, 40a''', 40a'''') through a first cardan joint (46a, 46a''1, 463'''', 46b) and being connected with said first worm-screw (11a, lib; 11a', lib'; lla'", lib" ' ; 11a' ' ' ' , lib' ' ' ' ) through a second cardan oint - (43a, 43a' v , 43a' ' ' ' , 43b) . 6.- The conveying unit according to claim 4 or 5, characterized by comprising: - a second modular element (lb, la; lb', la'; lb'', la''; lb"', la'''; lb"", la"") comprising, in turn, at least one second support element (20b, 20a; 20b', 20a'; 20b'', 20a''; 20b''', 20a'''; 20b'''', 20a'''') and a second worm-screw (lib, 11a; lib, 11a'; lib'', 11a''; lib'", lla"'; lib'"', 11a"") which may rotate about a fifth axis (E, A; E' , A' ; E" " ; A" " ) with respect to said second support element (20b, 20a; 20b', 20a'; 20b", 20a"; 20b'", 20a'"); said second worm-screw (lib, lla; lib, lla'; lib", lla"; lib'", lla'"; lib"", lla"") being adapted to cooperate with a second portion (8b, 8a) of at least said two containers (3); said second worm-screw (lib, lla; lib, lla'; lib", lla"; lib'", lla'"; lib"", lla"") being fixed relative to said at least one second support element (20b, 20a; 20b', 20a'; 20b", 20a"; 20b'", 20a'") with respect to a sixth axis (F; B) transversal to said fifth axis (E, A; E', A' ; E " ' ' ; A" ".) and with respect to a seventh axis (G, C; G' , C') transversal to said fifth and sixth axis (F, B; F ' , B'); said first and second support element (20b, 20a; 20b', 20a'; 20b'', 20a''; 20b''', 20a''') respectively comprising second and third releasable connecting means (36b, 36b'; 30a, 30a')' releasably connected to one another; said second support . element (20b, 20b' ; 20a, 20a') supporting said fifth axis (E, A; E' , A' ; E ' ' ' ' ; A ' ' ' ' ) of said second worm-screw (lib, lla; lib, 11a'; lib'"', 11a''; lib''', lla'''; lib'''', lla'''') at a third distance (Μχ; Ι_ι ; Οχ ' ; ¾ ' ) from said fourth axis (D) measured parallel to said second axis (B; F) and at a fourth distance (M2 ; L2 ; O2 ' ; ¾ ' ) from said fourth axis (D) measured parallel to said third axis (C; G) ; at least one between said third and fourth distances (M]_, M2 ; L]_, L2 ; 0 ' ; °2 ' ; Nl ' /' N2 ' ) being associated to the format of said containers (3) to be conveyed. 7.- The conveying unit according to claim 6, characterized in that: - said first modular element (la, lb; la', lb' ; la'', lb''; la''', lb'''; la'''', lb'''') comprises a first shaft (12a, 12b; 12a', 12b'; 12a''', 12b'''; 12a'''', 12b''''), which is rotatably supported by said first support element (20a, 20b; 20a', 20b'; 20a'', 20b''; 20a''', 20b''') about said first axis (A, E; A', E ' ; A' ' ' ' , E ' ' ' ' ) and is integrally rotatable together with said first worm-screw (lla, lla'; lib, lib') about said first axis (A, E; A', E ' ; A' ' ' ', E''"); - said second modular element (lb, la; lb', la'; lb'', la''; lb''', la'''; lb'''', la'''') comprises a second shaft (12b, 12a; 12b', 12a'; 12b''', 12a'"; 12b'''', 12a''''), which is rotatably supported by said second support element (20b 20b' ; 20a, 20a') about said fifth axis (E, A; E ' , A'; E'"', A'''') and integrally rotatable together with said second worm-screw (lib, 11a; lib, 11a'; lib'', 11a"; lib'", 11a"'; lib"", 11a"") about said fifth axis (E, A; E', A ' ; E " " , A" " ) ; 8.- The conveying unit according to claim 7, characterized by comprising: - a first gear (90"') rotatable integrally with said first shaft (12a'") and driven in rotation, in use, by said first motor (40a'"); - a second gear (91'") rotatable integrally with said second shaft (12b' " ) ; and - a third gear (92"') gear meshing with said first and second gears (90'", 91"'). 9. - The conveying unit according to claim 6 or 7 , characterized by comprising a second joint (41b, 41b"") connected to said second worm-screw (lib, 11a; lib, 11a'; lib", 11a"; lib'", 11a'"; lib"", 11a' " ' ) . 10. - The conveying unit according to claim 9, characterized by comprising: - a first pulley (75'"') operatively connected to said first motor (40a"") and said first joint (41a' ' " ) ; - a second pulley (76'''') operatively connected to said second joint (41b' ' ' ' ) ; and - a belt (77''/') wound onto said first and second pulleys (75"''.', 76""). 11.- The conveying unit according to anyone of the previous claims, characterized by comprising: - a third modular element (60a, 60b); said third modular element (60a, 60b) comprising, in turn, : - at least one third support element (65a, 65b) ; - fourth releasable connecting means (71a, 71b) for releasably connecting said third support element (65a, 65b) either to said fixed structure (5) or to a fourth support element (65b, 65a) ,- - at least one fixed guide (66a, 66b) adapted to cooperate with a third portion (9a, 9b) of said containers (3) advanced by said conveyor (6) ; said guide (66a, 66b) being arranged at a fifth distance (N]_, Οχ) from said fourth axis (D) measured parallel to said second axis (B) , and a at a sixth distance (¾, O2) from said fourth axis (D) measured parallel to said third axis (C) ; at least one between said fifth and sixth distance (N]_, 0]_; N2 , O2 ) being associated to the format of said containers (3) to be conveyed. 12.- The conveying unit according anyone of the previous claims, characterized in that said first support element (20a, 20b; 20a', 20b'; 20a'", 20b'") may slide relative to said fixed structure (5) . 13. - A conveying unit for said container processing machine (2), characterized by comprising: - said conveyor (6) ; and - said fixed structure (5) ; 14. - A container processing machine, comprising: - at least one star wheel (7); and - a conveying unit (4, 4', 4'', 4''', 4'''') according to claim 4 to 13 and arranged upstream from said star wheel (7) . 15. - Series of conveying units (4, 4', 4'', 4''', 4'''') for a container processing machine, characterized in that each conveying unit (4, 4', 4'', 4''', 4'''') comprises : - at least one first support element (20a, 20b; 20a' , 20b' ; 20a' ' ' , 20b' ' ' ) ; - first releasable connecting means (30a; 30a') for releasably connecting said first support element (20a, 20b; 20a', 20b'; 20a''', 20b''') either to a fixed structure (5) or to a second support element (20b, 20a; 20b' , 20a' ; 20b' ' ' , 20a' ") ; - at least one first worm-screw (11a, lib; 11a' , lib'; 11a''', lib'''; 11a'''', lib'''') which may rotate about a first axis (A, E; A', E' ; A'''', E'''') with respect to said first support element (20a, 20a'; 21b, 21b' ) , and is adapted with cooperate with a first portion (8a, 8b) of at least two containers (3) advancing on a conveyor (6) along a fourth axis (D) parallel to said first axis (A, E; A', E'; A''' ', E'''') in order to distance them at a given pitch; said at least one first support element (20a, 20a'; 20b, 20b') supporting said 'first axis (A, E; A', E'; A' ' ' ', E' ''') of relative said first worm-screw (11a, lib; 11a', lib'; 11a''', lib'''; 11a'''', lib'''') at a relative first distance (L]_, M]_ , ¾ ' , ' ) from said fourth axis (D) measured parallel to said relative second axis (B, F) and at a relative second distance (I_2, 2, 2 ' , O2 ' ) from said fourth axis (D) measured parallel to said third axis (C, G) ; at least one between said first and second distances (L]_, L2 ; M]_, M2 ; ]_ ' , ¾ ' ; Ο ' , O2 ' ) being associated to the format of relative said containers (3) to be conveyed. 16.- Series of conveying units (4, 4', 4'', 4''', 4'''') according to claim 15, characterized in that each conveying unit (4, 4', 4'', 4''', 4'''') comprises : - a second support element (20b, 20b'; 20a, 20a'); and - a second worm-screw (lib, 11a; lib, 11a'; lib'', la''; lib''', 11a' '' ; lib'''', 11a'''') which may rotate about a fifth axis (E, A; E' , A'; E ' ' ' ' ; A'''') with respect to said second support element (20b, 20b'; 20a, 20a'); said second worm-screw (lib, 11a; lib, 11a',· lib'', 11a''; lib''', 11a' " ; lib'''', 11a'''') being fixed relative to said at least one said second support element (20b, 20b'; 20a, 20a') with respect to a sixth axis (F; B) transversal to said fifth axis (E, A; E ' , A' ; E' ' ' ' ; A' ' ' ' ) and with respect to a seventh axis (G; C) transversal to said sixth axis (F; B) and said fifth axis (E, A; E ' , A' ; E ' ' ' ' ; A' ' ' ' ) ; said at least one first and second support element (20a, 20a'; 20b, 20b') of each conveying unit (4, 4', 4'', 4''', 4'''') respectively comprising second and third releasable connecting means (36b, 36b'; 30a, 30a') releasably connected to one another; said fifth axis (E, A; E', A'; E' ' ' ' ; A'''') being arranged at a third distance (Μχ, L]_; ' , ' ) from said fourth axis (D) and at a fourth distance (M2f L2 O2, N2) from said fourth axis (D) ; at least one between said third and fourth distance (M]_( M2 ; I_2) being associated to the format of the containers (3) to be conveyed. 17.- Series of conveying units according to claims 15 or 16, characterized in that each conveying unit (4) comprises : - at least one fixed guide (66a, 66b) adapted to cooperate with a third portion (9a, 9b) of said containers (3) advancing parallel to said first axis (A, E; A' , E' ; A' ' ' ' , E ' ' ' ' ) ; - at least one third support element (60a, 60b) which comprises fourth releasable connecting means (71a; 71b) for releasably connecting said third support element (60a; 60b) to either said fixed structure (5) or to a fourth support element (60b; 60a) ; said guide (66a; 66b) being arranged at a fifth distance (N^; Οχ) from said fourth axis (D) measured parallel to said second axis (B) , and at a sixth distance (¾; O2) from said fourth axis (D) measured parallel to said third axis (C) ; at least between said fifth and said second distance ( ^, ¾ Οχ, O2 ) being associated to the format of said containers (3) to be conveyed. 18.- Modular element (60a, 60b) for a container processing machine (2) , characterized by comprising: - at least one first support element (65a; 65b) ; - first releasable connecting means (71a, 71b) for releasably connecting said first support element (65a, 65b) to either a fixed structure (5) of said container processing machine (2) or to a further support element (65b; 65a) of a further modular element (60b; 60a) ; and at least one fixed guide (66a; 66b) adapted to cooperate with a first portion (9a; 9b) of at least two containers (3) advancing on a conveyor (6) parallel to a first axis (A, E; A', E' ; A'''', E' ' ' ' ) ; said first support element (65a; 65b) supporting said guide (66a, 66b) at a first distance (N_; O^) from a second fixed reference axis (D) measured parallel to a third axis (B) transversal to said first axis (A, E; A' , E' ; A'''', E''''), and at a second distance (¾; O2) from said second axis (D) measured parallel to a fourth axis (C) , which is transversal to said first and third axes (A, B) ; at least one between said first and second distances (Νχ, 2 ; , O2) being associated to the format of said containers (3) to be conveyed. 19.- Method for adapting a conveying unit (4, 4', 4'', 4''', 4''') for a container processing machine (2) to a different format of containers (3), said conveying unit (4, 4', 4'', 4''', 4''') comprising: - a fixed structure (5); - at least one first worm-screw (11a, lib; 11a' , lib'; 11a''', lib'''; 11a'''', lib'''') which may rotate relative to said fixed structure (5) about a first axis (A, E; A' , E' ; A' ' ' ' , E ' ' ' ' ) ; said first worm-screw (11a, lib; 11a', lib'; 11a''', lib'''; 11a'''', lib'''') being adapted to cooperate with a first portion (8a, 8b) of said container (3) advancing parallel to said first axis (A, E; A', E' ; A'''', E'''') in order to distance them at a given pitch, said method comprising the steps of: choosing a modular support element (la, lb; la' , lb'; la'', lb''; la''', lb'''; la'''', lb'''') rotatably supporting said first worm-screw (11a, lib; 11a', lib'; 11a''', lib'''; 11a'''', lib'''') about said first axis (A, E; A', E'; A'''', E'' '') on the basis of at least one between a first distance (L]_; M]_) between said first axis (A, E; A', E'; A'''', E'''') and a fixed second reference axis (D) measured parallel to a third axis (B, B') transversal to said first axis (A, E; A', E' ; A'''', E' ' ' ' ) , and a second distance (L2; M2 ) between said first axis (A, E; A', E'; A'''', E ' ' ' ' ) and said second reference axis (D) measured parallel to a fourth axis (C, C) transversal to both said first and second axes (A, B) ; and releasably connecting said modular support element (la, lb; la', lb'; la' ', lb' '; la''', lb'''; la' ' ' ' , lb' ' ' ' ) to said fixed structure (5) . |
TECHNICAL FIELD
The present invention relates to a modular element for a container processing machine, to a series of conveying units for container processing machine, and to a method for adapting a conveying unit for a container processing machine to a different format of containers. BACKGROUND ART
As is known, many liquid or powder products including not only food products such as milk, fruit juices or beverages in general, but also mineral lubricating or detergent oils are sold in containers having different shapes and size.
These containers are manufactured in plants comprising a plurality of stations at each of which corresponding machines process such containers .
Examples of such machines are rinsing, filling, capping and labelling machines.
The above said plants also comprise a plurality of linear conveyors and star wheels for feeding the system with the containers, for transferring the containers from a machine to the other and for transferring the containers outside the system.
More precisely, star wheels comprise a plurality of circumferential seats adapted to receive respective containers . At some point along the linear conveyor trajectory, the containers come into a position of in-line mutual contact. In order to address the problem of separating the containers from their position of mutual contact so that they can be taken up by the seats of the star wheel, a worm-screw is usually located at a location adjacent to the conveyor. The worm screw extends alongside the conveyor belt and is arranged to mesh with the contour of the containers to feed them smoothly and continuously into the seats of the star wheels.
Since plants usually process containers of different format, e.g. with reference to size and shape, the worm-screws are required to efficiently convey containers of different format.
To this purpose, it is necessary to ensure that the worm-screw meshes with a certain amount of the contour of the containers of different format. This need is especially felt when container speed increases and container weight decreases .
In a first known solution, conveying unit comprises a support structure rotatably supporting the worm-screw about a first axis. In particular, the worm-screw is fixed to the support structure. In this way, the first axis cannot be moved with respect to such support structure.
Accordingly, such worm-screws are optimized for only one given format containers, and are prevented from meshing with a substantial amount of the contour of the containers having different size from such given format.
As a consequence, fixed axis worm-screws are prevented from efficiently conveying containers whose format is very different from the given format.
For example, fixed axis worm-screws fail to efficiently convey containers whose format is smaller than the given format .
Fixed axis worm-screws therefore result in severe limitations on the efficiency of the conveyance of containers .
It is also known to use worm-screws supported by support structure through bearings, which are mounted on a pair of slides.
More precisely, the slides allow the worm-screw to be moved along a second axis and a third axis orthogonal to the first axis. In particular, the second axis is horizontal and the third axis is vertical.
In this way, when it necessary to change the format of the containers to be processes, the worm-screw is moved with respect to the support structure and arranged in given position, in which it meshes with a substantial amount of the volume of the containers to be conveyed.
However, this kind of worm-screws are likely to be misadjusted when the format of the containers is changed, so causing delays and lost production.
A need is felt within the industry to provide a conveying unit which can be easily reconfigured for different containers format, so as to eliminate operator errors which may result in a damage of containers. Such need is especially felt when containers are conveyed at particularly high speed and/or the surfaces of containers are particularly delicate.
A need is also felt within the industry to allow an ideal application position and contact profile between containers, so as to efficiently convey containers with delicate surfaces at the highest speed possible.
Finally, a need is felt to meet the above- identified requirements while reducing the costs and the space due to the motors driving in rotation the worm- screws .
DISCLOSURE OF INVENTION
It is an object of the present invention to provide a modular element for a container processing machine allowing to efficiently convey containers of different format and designed to meet at least one of the above- identified requirements in a straightforward, low-cost manner .
According to the present invention, there is provided a modular element for a container processing machine as claimed in claim 1.
Furthermore, according to the present invention, there is provided a series of conveying units for container processing machine as claimed in claim 15.
According to the present invention, there is also provided a further modular element for a container processing machine as claimed in claim 18.
Finally, according to the present invention, there is provided a method for adapting a conveying unit for a container process machine to a different format of containers as claimed in claim 19.
BRIEF DESCRIPTION OF THE DRAWINGS
In the following a preferred, non-limiting embodiment of the present invention will be described by way of example with reference to the accompanying drawings, in which:
Figure 1 shows a perspective view of a modular element according to the present invention and of a first embodiment of a conveying unit incorporating such modular element;
Figure 2 shows a section along line II-II of Figure
1;
Figure 3 shows a lateral view of the first embodiment of a conveying unit incorporating the modular elements of Figure 1;
Figure 4 shows a frontal view of the first embodiment of the conveying unit of Figure 1;
Figures 5 and 6 show respective frontal views of a second embodiment of the conveying unit incorporating the modular element of Figure 1 while processing containers having respective format different from one another;
Figure 7 shows a frontal view of the second embodiment of the conveying unit, with parts sectioned;
Figure 8 shows a frontal view of a third embodiment of the conveying unit incorporating the modular element of Figure 1 ;
Figure 9 shows a lateral view of a fourth embodiment of a conveying unit incorporating the modular element of Figure 1;
Figure 10 shows a section along line X-X of Figure
9;
Figure 11 shows a lateral view of a fifth embodiment of a conveying unit incorporating the modular element of Figure 1; and
Figure 12 is a section along line XII-XII of Figure 11 ; and
Figure 13 shows a schematic top view of a container processing machine incorporating the modular element of Figure 1.
BEST MODE FOR CARRYING OUT THE INVENTION
Number la in the accompanying Figures indicate as a whole a modular element for a machine 2 (Figure 13) for processing containers 3, such as bottles, pots, cans and the like.
Non-limitative examples of such products include not only food products such as milk, fruit juices or beverages in general, although also mineral lubricating or detergent oils are sold in containers having different shapes and size. Machine 2 may be a rinsing machine for rinsing the containers, a filling machine for filling the containers with a predetermined volume of a liquid product, a capping machine for applying a plurality of caps on respective containers or a labelling machine for applying a plurality of labels on respective containers.
In the case shown, machine 2 is a labelling machine .
Modular element la is incorporated in a conveying unit 4, which substantially comprises:
- a fixed structure 5 ;
- a linear conveyor 6 for conveying the containers to be labelled by machine 2 along a direction A; and
- a plurality of star wheels 7 (only one of which is shown in Figure 13) fed by conveyor 6 with containers
3 and feeding containers 3 along a circumferential arc shaped trajectory.
Star wheels 7 rotate along respective vertical axes and comprise a plurality of angularly egui-spaced seats for respective containers 3.
Modular element la advantageously comprises (Figure
4) :
a pair of support elements 20a;
releasable connecting means 30a for releasably connecting such support elements 20a to fixed structure 5 ; and a worm-screw 11a which rotates about axis A relative to support elements 20a and is adapted to cooperate with a first portion 8a of containers 3 advancing on conveyor 6 in order to distance them at a given pitch;
worm-screw 11a is fixed to support elements 20a with respect to an axis B transversal to axis A and to an axis C transversal to both axes A, B;
support elements 20a support axis A of worm-screw 11a at a first distance L]_ from a reference fixed axis D measured parallel to axis B, and at a second distance I_2 from axis D measured parallel to axis C;
first and second distances L-_ L2 are associated to the format of containers 3 to be conveyed.
In particular, axis A is horizontal, axis B is horizontal and orthogonal to axis A and axis C is vertical and, therefore, orthogonal to both axes A, B.
Axis D is fixed with respect to structure 5, and is parallel to axis A.
In the embodiment shown, axis D coincides with the direction along which containers 3 advance on conveyor 6.
In particular, support elements 20a are arranged at opposite end of worm-screw 11a relative to axis A.
Each support element 20a substantially comprises:
- a parallelepiped main portion 21a; and - a lateral portion 22a integral with main portion 21 and defining an apex 23a, which extends towards conveyor 6.
In particular, main portion 21a comprises a top surface 24a and a bottom surface 25a.
Connecting means 30a releasably connect support element 20a of each modular element la to a plate 19a, which is connected to structure 5.
Connecting means 30a substantially comprise, for each modular element la, :
- a pair of holes 31a defined by relative surface
25a;
a pair of pins 32a whose top halves engage respective holes 31a and whose bottom halves engage respective holes 49a of plate 19a;
a screwed hole 33a interposed between holes 31a and defined by surface 25a; and
a screwed pin 35a engaging hole 33a and passing through plate 19a.
Each modular element la further comprises connecting means 36a.
Connecting means 36a substantially comprise, for each support element 20a, :
a pair of holes 37a defined by relative surface 24a;
a pair of pins 38a whose bottom halves engage respective holes 33a; and
a screwed hole 39a interposed between holes 37a and defined by surface 24a.
Worm-screw 11a comprises a shaft 12a elongated along axis A and an. outer body 13a surrounding shaft 12a. In particular, body 13a is fitted to shaft 12a through the interposition of a pin 14a (Figure 3) .
Apices 23a of support elements 20a house respective bearings 26a, which support body 13a rotatably with respect to axis A (Figure 2).
Conveying unit 4 comprises (Figure 4) :
- modular element la;
- a modular element lb, which is arranged over and is releasably connected with modular element la;
- a modular element 60a, which is arranged on the opposite side of modular elements la, lb with respect to conveyor 6 ; and
- a modular element 60b, which is arranged over modular element 60a and is releasably connected to modular element 60a.
Modular element lb is similar to modular element la and will be disclosed hereinafter only insofar as it differs from the latter; corresponding parts or equivalents of modular elements lb, la will be indicated, where possible, by the same reference numerals . Modular element lb differs from modular element la in that :
- worm-screw lib (not shown in Figure 1 for sake of simplicity) rotates about axis E relative to support element 20b and is adapted to cooperate with a second portion 8b of containers 3 advancing on conveyor 6 ;
- worm-screw lib is fixed to support elements 20b with respect to an axis F transversal to axis E and to an axis G transversal to both axes E, F; and in that
- support element 20b support axis E of worm-screw lib at a third distance M ] _ from reference axis D measured parallel to axis F and at a fourth distance M2 from axis D measured parallel to axis G.
More precisely, axes E, F, G are parallel and arranged above respectively axes A, B, C.
Third and fourth distances Mi M2 are associated to the format of containers 3 to be conveyed.
In a completely analogous manner with respect to support element 20a, support element 20b comprises:
- a parallelepiped main portion 21b; and
- a lateral portion 22b integral with main portion 21 and defining an apex 23b, which extends towards conveyor 6.
In particular, main portion 21b comprises a top surface 24b and a bottom surface 25b.
Furthermore, connecting means 30b of modular element lb are releasably connected to connecting means 36a of modular element la.
More precisely, connecting means 30b substantially comprise, for each support element 20b, (Figure 4) .·
- a pair of holes 31b defined by relative surface
25b and engaged by top halves of respective pins 38a;
- a through hole 33b; and
- a screwed hollow-pin 45b passing through hole 33b and screwed within hole 39a.
Each modular element 60a, 60b advantageously comprises (Figure 1) :
- a pair of support elements 65a, 65b; and
- a fixed guide 66a, 66b adapted to cooperate with respectively portions 9a, 9b containers 3 advancing on conveyor 6.
More precisely, portion 9b is arranged in front of portion 8b and over portions 9a, 8a.
Support element 65a, 65b supports relative guides 6a, 66b at a relative distance N ] _ Ο from reference axis D measured parallel to axis B, F and at a relative distance ¾ , O2 from axis D measured parallel to axis C, G. More precisely, Ν # and N2 O2 represent the distance between axis D and homologous points of guides 66a, 66b.
At least one between distances ] _, ¾ is associated to the format of said containers 3 to be conveyed.
In a completely analogous manner, at least one between distances 0]_, O2 is associated to the format of said containers 3 to be conveyed.
In particular, each pair support elements 65a, 65b is arranged on opposite axial end of relative guide 66a, 66b. .
Each support element 65a, 65b substantially comprises :
- a parallelepiped main portion 80a, 80b; and
- a lateral arm 81a, 81b which protrudes integrally from respective main portion 80a, 80b towards conveyor 6 and respective apex 23a, 23b, and which carries, on the opposite side of main portion 80a, 80b, relative guide 66a, 66b.
In particular, main portion 80a, 80b of each support element 65a, 65b comprises a top surface 84a, 84b and a bottom surface 85a, 85b.
Modular element 60a comprises:
connecting means 71a for releasably connecting each support element 65a to a plate 19b of fixed structure 5; and
connecting means 72a for releasably connecting each support element 65a to support element 65b of modular element 60b.
Furthermore, modular element 60b comprises connecting means 71b for releasably connecting each support element 65b to connecting means 72a of relative support element 65a of modular element 60a. In particular, connecting means 71a comprise, for each support element 65a, :
- a pair of holes 100a defined by surface 85a;
- a pair of pins 101a whose top halves engage respective holes 100a and whose bottom halves engage respective holes 32b of plate 19b;
- a screwed hole 102a interposed between holes 100a and defined by surface 85a; and
- a screwed pin 104a passing through a hole 35b defined by plate 19b and screwed within hole 102a.
In particular, hole 35b is interposed between holes
32b.
Connecting means 72a comprise, for each support element 65a, :
- a pair of holes 110a defined by surface 84a;
- a pair of pins 111a whose bottom halves engage respective holes 110a; and
- a screwed hole 112a interposed between holes 110a and defined by surface 84a.
Connecting means 71b substantially comprise, for each support element 65b, :
- a pair of holes 101b defined by relative surface 85b and engaged by top halves of respective pins 111a of relative support element 65a;
- a through hole 102b; and
- a screwed hollow pin 105b passing through hole 102b and screwed within hole 112a.
Conveying unit 4 further comprises a pair of motors " 40a, 40b and of joints 41a, 41b (Figures 1 and 3).,
Each joint 41a, 41b comprises a first shaft 42a, 42b, which is articulated onto an output shaft of respective motors 40a, 40b through a cardan joint 46a, 46b and which is articulated onto shaft 12a, 12b of a respective worm-screws 11a, lib through a cardan joint 43a, 43b.
More precisely, shaft 42a, 42b comprises two rods telescopically coupled with one another. In this way, the distance between cardan joints 43a and 46a (43b and 46b) may vary when modular elements la, lb are replaced with new modular elements la, lb.
Joints 41a, 41b could be replaced by any kind of transmission mechanism capable of transmitting motion between two axes which can be either coaxial or parallel .
In use, conveyor 6 advances containers 3 parallel to axis A towards star wheel 7.
Upstream from worm-screws 11a, lib of conveying unit 4, containers 3 come in mutual contact one with respect to another.
Worm-screws 11a, lib cooperate with portions 8a, 8b of containers 3 and sequence such containers 3 at a given pitch, which corresponds to the angular distance between the seats of star wheel 7.
As first portions 8a of containers 3 cooperate with worm-screw 11a of modular element la, second portion 8b of worm-screw 11 of modular element lb, third portions 9a of containers 3 cooperate with guide 66a and fourth portions 66b of containers 3 cooperate with guide 66b.
Motors 40a, 40b drive in rotation, through joints 41a, 41b worm-screws 11a, lib about axes A, E.
Apices 23a, 23b of each modular element la, lb support axes A, E of worm-screw 11a, lib at the distance L]_, Mi from reference axis D measured parallel to axis B, F and at the distances L>2 r M2 from reference axis D measured parallel to axis C.
More precisely, distances L]_ L2 and M2 are such that worm-screw 11a and lib may engage with a certain amount of the surface of portions 8a, 8b containers 3, so efficiently conveying such containers 3 and distancing them at the given pitch.
Modular elements 60a, 60b support guides 66a, 66b at respective distances N]_ from reference axis D measured parallel to axes B, F, and at respective distances ¾ ( O2 from reference axis D measured parallel to axes C, G.
In case that the format of containers 3 changes, i.e. because diameter or height of containers 3 changes, modular element lb is removed from modular element la and modular element la is removed form fixed structure 5. In a completely analogous manner, modular element 60b is removed from modular element 60a and modular element 60a is removed from plate 19b fixed structure 5.
In particular, shafts 12a, 12b of worm-screws 11a, lib are disconnected by shafts 42a, 42b of joints 41a, 41b.
New modular elements la, lb, 60a, 60b are chosen on the basis of the format of new containers 3 to convey.
In other words, new modular elements la, lb, 60a,
60b are chosen so that the new values of distances L ] _, L.2 , ]_ , M2 , ¾ , N2 , Ο , C>2 ensure that containers 3 are efficiently conveyed.
For example, in case that the diameter of new containers 3 is smaller than the diameter of containers 3 previously conveyed, axes
A, E of worm-screws 11a, lib and guides 66a, 66b of new modular element la, lb, 60a, 60b will be nearer to the vertical axis of new containers. 3 with respect to axes A, E and guides 66a, 66b of previously used modular element la, lb, 60a, 60b.
Accordingly, new distances L]_, L2 , M^, M2 , N]_, 1¾ , °1' °2 associated to new modular element la, lb, 60a, 60b will be lower than distances L]_ ' , L2 , M]_, M2 , N]_, ¾ , 0]_, O2 associated to previously used modular element la, lb, 60a, 60b. Shafts 42a, 42b of joints 41a, 41b are connected to shafts 12a, 12b of worm-screws 11a, lib of new modular element la, lb.
In this way, even if axis A of " worm-screw 11a, lib of new modular element 1 is staggered with respect to axis A, E of relative worm-screw 11a, lib of modular element la, lb previously used, the same motors 40a, 40b and joint 41a, 41b may be used.
With reference to figure 5 to 7 , 4' indicates a second embodiment of conveying unit.
Conveying unit 4' is similar to conveying unit 4 and will be disclosed hereinafter only insofar as it differs from the latter; corresponding parts or equivalents of conveying units 4, 4' will be indicated, where possible, by the same reference numerals.
Conveying unit 4' differs from conveying unit 4 in that it comprises further modular elements la', lb' instead respectively of modular elements 60a, 60b.
Accordingly, conveying unit 4' comprises further worm-screws 11a' , lib' rotatably supported by support elements 20a' , 20b' rotatably about respectively axes A' , E' .
Worm-screw lib' of modular element lb' is arranged above worm-screw 11a' of modular element la', and axis E ' is arranged above and parallel to axis A' .
Support elements 20a' support axis A' of worm-screw 11a' at a distance ]_ ' from axis D measured parallel to axis F' and at a distance 2 ' measured parallel to axis G' . At least one between distances ' , ¾ ' is chosen on the basis of the format' of containers 3 to be conveyed.
In a completely analogous manner, support elements 20b' support axis E' of worm-screw lib' at a distance 0]_ ' from axis D measured parallel to axis F' and at a distance O2 ' measured parallel to axis G' . At least one between distances Οχ', O2 ' is chosen on the basis of the format of containers 3 to be conveyed.
Connecting means 30a' releasbaly connect each support element 20a' of modular element la' to plate 19b of fixed structure 5.
Connecting means 30b' are releasably connected with connecting means 36a' of support element 20a' of modular element la' . In this way, each support element 20b' of modular element lb' is releasably connected to a corresponding support element 20a' of modular element la' .
Finally, conveying unit 4' differs from conveying unit 4 in that it comprises:
- a pair of further motors (not shown) ; and
- a pair of further joints (not shown) .
Each further joint comprises a further shaft (not shown) which is articulated onto an output shaft of respective motor (not shown) through a first cardan joint and which is articulated onto shaft 12a', 12b' of respective worm-screws through a second cardan joint.
Each further shaft comprises two rods telescopically coupled with one another.
In a completely analogous manner to joints 41a, 41b, further joints could be replaced by any kind of transmission mechanism capable of transmitting motion between two axes which can be either coaxial or parallel.
The operation of conveying unit 4' differs from the operation of conveying unit 4 in that not only first and second portions 8a, 8b of containers 3 cooperate respectively with worm-screw 11a, lib of modular elements la, lb, but also third and fourth portions 9a, 9b of such containers 3 cooperate respectively with worm-screw 11a', lib' of modular elements la', lb'.
Furthermore, shafts 12a', 12b' of worm-screws 11a', lib' are driven in rotation by further motors through further joint.
In case that the format of containers 3 changes, i.e. because diameter or height of containers 3 changes, modular element lb' is removed from modular element la' , and modular element la' is removed form fixed structure 5.
In particular, shafts 12a', 12b' of worm-screw 11a', lib' are disconnected by further second shafts of relative further joints.
New modular elements la, lb, la', lb' are chosen on the asis of the format of new containers 3 to be conveyed.
In other words, new modular elements la, lb, la', lb' are chosen so that the new values of distances L ] _, L>2 , M]_ , M2 , N]_ ' , 2 ' , 0]_ ' , O2 ' ensure that containers 3 are efficiently conveyed and distanced at the given pitch.
With reference to figure 8, 4'' indicates a third embodiment of conveying unit.
Conveying unit 4'' is similar to conveying unit 4' and will be disclosed hereinafter only insofar as it differs from the latter; corresponding parts or equivalents of conveying units 4', 4'' will be indicated, where possible, by the same reference numerals .
Conveying unit 4'' differs from conveying unit 4' for not comprising modular elements la', lb'.
Furthermore, plates 19a' ' , 19b' ' and, therefore, modular elements la'', lb'' of conveying unit 4'' may slide along axis B' ' relative respectively to plates 18a'', 18b'' of fixed structure 5.
In this way, it is possible to adjust position of modular elements la'', lb'' relative to containers 3.
More precisely, each plate 19a'', 19b'' comprises, on the opposite side of worm-screws:
- respective protrusions 17a'', 17b'' housed with gap into respective grooves 16a' ', 16b' ' of plates 18a'', 18b'', and comprising, in turn, respective through holes, which are screwed parallel to axis B'' and are engaged " by screw 67a' ', 67b'' extending parallel to axis B; and
- respective pair of screwed through holes 68a'', 68b' ' which are coupled with respective screws 69a' ' , 69b''.
More precisely, screwed holes and screws 69a'', 69' ' extend parallel to axis C ' .
The operation of conveying unit 4'' is similar to the operation of conveying unit 4' and is therefore not hereinafter described.
With reference to figures 9 and 10, 4' 7 ' indicates a fourth embodiment of conveying unit.
Conveying unit 4''' differs from conveying unit 4' for comprising neither motor 40b nor joint 41b.
Furthermore, conveying unit 4''' differs from conveying unit 4' for comprising:
- a gear 90''' driven in rotation by joint 41a''' and angularly integral with shaft 12a' ' ' of worm-screw 11a' ' ' ;
- a gear 91''' angularly integral with shaft 12b''' of worm-screw lib' ' ' ; and
- an idler gear 92''' meshing with both gears 90''' and 91 " ' .
In particular, shafts 12a''', 12b''' of worm-screws 11a''', lib' ' ' are coaxial with respective gears 90''', 91 ' ' ' . .
Finally, conveying unit 4''' differs from conveying unit 4' in that each modular elements la' ' ' , lb' ' ' comprises :
- a pair of support element 20a''', 20b''' arranged at the end of worm-screws 11a''', lib''' facing motor 40' " ; and
- a block 29a' ' ' , 29b' ' ' axially interposed between support elements 20a''', 20b''' arranged at the end of worm-screws 11a' ' ' , lib' ' ' facing motor 40' ' .
Blocks 29a''' define together with block 29b''' define relative cavities 93''' housing gears 90''', 91' ' ' , 92' ' ' .
The operation of conveying unit 4''' differs from the operation of conveying unit 4' in that both worm- screws 11a''', lib''' are driven in rotation by same motor 40a' ' ' .
More precisely, motor 40a''' drives joint 41a''', which drives in rotation gear 90'''. Gear 90''' drives in rotation both shaft 12a' ' ' of worm-screw 11a' ' ' and gear 91'''. Gear 91''' drives in rotation gear 92''' which, in turn, drives in rotation shaft 12b' ' ' of worm- screw lib' ' ' .
With reference to figures 11 and 12, 4'''' indicates a fourth embodiment of conveying unit. Conveying unit A'''' is similar to conveying unit 4' and will be disclosed hereinafter only insofar as it differs from the latter; corresponding parts or equivalents of conveying units 4 ' ' ' ' , 4 ' will be indicated, where possible, by the same reference numerals.
Conveying unit A'' 1 ' differs from conveying unit 4' for comprising only one motor 40a' ' ' ' for driving in rotation both worm-screw 11a' ' ' ' of modular element la' ' ' ' and worm-screw lib' ' ' of modular element lb' ' ' ' .
Furthermore, conveying unit 4'''' differs from conveying unit A' 1 for comprising:
- a pulley 75'''' driven in rotation by output shafts of motor 40a' ' ' ' and driving in rotation a shaft 50a' ' ' ;
- a pulley 76' ' ' ' connected to a shaft 50b' ' ' ' ; and
- a belt 77 ' ' ' ' wound on pulleys 75 ' ' ' ' , 76 ' ' ' ' .
More precisely, shafts 42a'''', 42b'''' of joint
41a'''', 41b'''' are articulated via cardan joint 46a'''', 46b'''' respectively onto shafts 50a'''', 50b'
Pulleys 75'''', 76'''' and belt 77'''' are housed within a housing 78' ' ' ' .
The operation of conveying unit A'''' differs from conveying unit 4' in that motor 40a'''' drives in rotation pulley 75' ' ' ' .
Pulley 75'''' drives both shaft 42a''' of joint 41a' ' ' ' and belt 11'''', which in turn, drives pulley 76 ' ' ' ' .
Joint 41a' ' ' ' drives in rotation worm-screw lib' ' ' ' about axis E ' ' ' ' while pulley 76''' drives shaft 42b''' of joint 41b'
Joint 41b' ' ' drives, in turn, in rotation worm- screw lib'
From an analysis of the features of modular element la, lb, la', lb', la'', lb'', la''', lb''', la'''', lb' ' ' ' and of modular element 60a, 60b made according to the present invention, the advantages it allows to obtain are apparent .
In particular, modular element la, lb; la' , lb' ; la'', lb''; la''', lb'''; la'''', lb'''' allows to arrange axis A (E) of worm-screw 11a, lib; 11a', lib'; 11a'', lib''; 11a''', lib'''; 11a'''', lib'''' at designed distances L]_ I_2 , ]_, M2 , N · , N 2 ' ' °1' °2 ' from axis D measured parallel to axis B, B'; C, C ; F, F' and G, G' , on the basis of the format of containers 3 to be conveyed.
Accordingly, it is sufficient to replace modular elements la (lb) with new modular elements la (lb) arranging axis A (E) of worm-screw 11a (lib) at different distances L]_ L2 , χ, M2 , ]_ 2 ' , 0]_, O2 ' from axis D in order to reconfigure conveying unit 4, 4', 4'', 4''', 4'''' for a new format of containers 3.
In this way, modular element la, lb; la', lb'; la'', lb''; la''', lb'''; la"", lb"" arranges containers 3 at an ideal position relative to worm-screw 11a, lib; 11a', lib'; 11a", lib"; 11a'", lib"'; 11a' " ' , lib'
In a completely analogous way, modular element 60a
(60b) allows to arrange guide 66a (66b) at designed distances and N2 (Ο and O2) from axis D measured parallel to axis B and C (F and G) , on the basis of the format of containers 3 to be conveyed.
Resulting conveying unit 4, 4', 4", 4'", 4"" is therefore highly modular and can be reconfigured without requiring highly skilled, personnel for processing containers 3 of different format.
As the risk that operator errors result could result in a damage of containers 3 is highly reduced, conveying unit 4, 4', 4", 4'", 4"" are particularly advantageous for conveying even containers 3 with delicate surface at very high speeds.
Furthermore, modular element la, lb; la', lb'; la", lb"; la'", lb'"; la"", lb'"' and 60a, 60b do not impinge the general structure of conveying unit 4, 4', 4", 4'", 4"".
Conveying unit 4 ' ' ' , 4 " " requires only one motor 40a' ' ' , 40a' ' ' ' for driving in rotation both worm-screws 11a' ", lib'" and 11a'"', lib"".
Accordingly, conveying unit 4'", 4"" does not require additional spaces and inf a-structure for housing a further motor.
In this way, conveying unit 4' ' ' ' may , be reconfigured without requiring, additional spaces for housing a plurality of motors 40a''''.
Even, conveying unit 4''' requires only one joint 41a''' for driving in rotation both worm-screws 11a''', lib'".
Accordingly, conveying unit 4''' conveys containers 3 in a particularly economic way.
Finally, it is apparent that modifications and variants not departing from the scope of protection of the claims may be made to modular element la, lb, la', lb', 60a, 60b.
In particular, conveying unit 4, 4', 4'', 4''', 4'''' could comprise only one modular element la (lb), la' (lb'), la'' (lb"), la'" (lb'"), la"" (lb"").
Conveying unit 4 could comprise only one modular element 60a, 60b.
Conveying unit 4, 4', 4" could comprise only one motor 40a for driving in rotation both worm-screws 11a, lib; 11a', lib'; 11a' ' , lib".
In this case, motor 40a could be connected to worm- screws 11a, lib; 11a', lib'; lla" , lib" either by:
- only one joint 41a'" and gears 90'", 91'", 92 ' ' ' ; or - two joints 41a' ' ' ' , 41b' ' ' ' driven respectively by pulleys 75 ' ' ' ' , 76 ' ' ' ' and belt 77 ' ' ' ' .
Conveying unit 4''', 4'''' could comprise one or more ' modular element 60a, 60b instead of modular elements la', lb'.
Conveying unit 4, 4'', 4''', 4'''' could comprise protrusion 17a' ' , 17b' ' , grooves 16a' ' , 16b' ' , screws 67a'', 69a'' and holes 68a''.
Finally, conveying unit 4, 4'', 4''', 4'''' could comprise other coupling means for rendering respective plates 19a, 19b; 19a'', 19b'' slidable with respect to corresponding plates 18a, 18b; 18a'', 18b''.
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