Prior art
[0001] The present invention relates to the field of machines and equipment for molding
metal materials. In particular, the subject of the present invention is a lubricating
head for dispensing a lubricating fluid onto the surface of the mold. The invention
is also applicable to the plastics molding industry.
Background of the invention
[0002] As is known, an injection molding machine comprises a fixed plane carrying a first
half-mold and a movable plane carrying a second half-mold. Each half-mold, on its
inner face, has a plurality of cavities which, coupling with those of the other half-mold,
form the imprints corresponding to the pieces to be molded.
[0003] At each molding cycle, the movable plane moves closer to the fixed plane until the
two half-molds are coupled (closed mold), and, after injecting molten material and
waiting a predetermined time interval, the movable plane moves away from the fixed
plane, allowing the extraction of the parts (open mold).
[0004] When the mold is open, it is necessary to dispense a lubricating fluid (sometimes
also a coolant) on the inner faces of the half-molds, the action of which is essential
for the correct extraction of the pieces in the next cycle.
[0005] To dispense the lubricating fluid, usually composed of a liquid part and air, a lubricating
head is used which, placed between the two half-molds when the mold is open, dispenses
a plurality of jets, in a manner oriented toward the faces of the half-molds. For
this purpose, the lubricating head comprises a plurality of nozzles.
[0006] When production requirements change, for example when a mold is changed, and it becomes
necessary, for example, to modify the number and the position of the nozzles from
which the fluid is to be dispensed, the heads currently known require long set-up
times, which are necessary for disassembling the head, modifying the position of the
nozzles or changing the configuration thereof, and reassembling the head.
Object of the invention
[0007] It is the object of the present invention to provide a lubricating head for molds
equipped with a nozzle setting system that meets the industry requirements and overcomes
the drawbacks discussed above with reference to the prior art.
[0008] This object is achieved by a lubricating head for molds according to claim 1. The
dependent claims disclose further advantageous embodiments of the invention.
Brief description of the drawings
[0009] The features and advantages of the lubricating head according to this invention will
be apparent from the description below, given by way of non-limiting example according
to the figures in the appended drawings, wherein:
- Fig. 1 is a diagram of a molding assembly equipped with a lubricating head;
- Fig. 2 is a diagram of a matrix arrangement of the nozzles of the lubricating head;
- Fig. 3 is a diagram of a region arrangement of the lubricating head nozzles;
- Fig. 4, 4a, 5, 5a, and 6 are diagrams of nozzles of the lubricating head;
- Fig. 7 is a functional diagram of a lubricating apparatus according to an embodiment
of the present invention;
- Fig. 8 is a functional diagram of a lubricating apparatus according to another embodiment
of the present invention;
- Fig. 9 shows the diagram in Fig. 8 with an example of a setting of the nozzles;
- Fig. 10 is a diagram of a lubricating and/or cooling apparatus according to yet another
embodiment of the present invention.
Detailed description of the invention
[0010] Referring to Fig. 1, an assembly for molding metal materials, such as for injection
molding, is collectively indicated with 1. The assembly 1 comprises, for example,
a press 2 comprising a base 4, a fixed plane 6, and a movable plane 8 supported by
the base 4. The fixed plane 6 supports a first half-mold 10 and the movable plane
8 supports a second half-mold 12; the two half-molds comprise a mold. Each half-mold
10, 12 on the respective inner face 10a, 12a has a plurality of cavities which, coupling
with the cavities of the other half-mold when the mold is closed, form imprints of
the parts to be molded.
[0011] The assembly 1 further comprises a lubricator 14 for dispensing jets of lubricating
fluid and/or coolant onto the inner faces 10a, 12a of said half-molds 10, 12; the
lubricator 14 comprises a column 16 and a lubricating head 18, suspended from the
column 16. The lubricator 14 is configured to move the head 18 so as to arrange it
between the half-molds 10, 12 when the mold is open (working configuration of the
lubricator).
[0012] Preferably, the head 18 comprises a head body 18b comprising a regular solid, for
example a parallelepiped, having a plurality of head faces 18a, wherein at least one
head face 18a, in the working configuration, faces an inner face 10a, 12a of the mold.
[0013] The head 18 comprises a plurality of nozzles 20 arranged on at least one of said
head faces 18a; each nozzle 20 is adapted to deliver a jet of fluid, typically comprising
a liquid portion and air, which together form a nebulized product intended to be deposited
on the inner faces 10a, 12a of the half-molds 10, 12.
[0014] With reference to Fig. 2, on one of said head faces 18a, the arrangement of the nozzles
is assimilable to a nozzle matrix M provided with m rows and n columns. Each position
of the matrix M corresponds to a nozzle Uij, wherein "i" is the row number (with i=1...m)
and "j" is the column number (with j=1...n). For example, the nozzle U11 is the nozzle
that covers the position (1,1) corresponding to the row 1 and the column 1.
[0015] In general, however, the arrangement of the nozzles Uij on the head face 18a of the
head 18 need not be in rows and columns; in other words, the matrix M remains associated
with a region of the head face, and the identification of the nozzle Uij is carried
out with reference to that region. Referring to Fig. 3, for example, on the head face
18a, the region R is identified in which nozzles Uij are present. In this context,
the nozzle U11 is the nozzle that covers the position (1,1), corresponding to row
1 and column 1 of the region R.
[0016] According to a first embodiment (Fig. 4; nozzle NC), a nozzle 20 has a liquid port
22 for the outlet of the jet of liquid, an air port 24 for the outlet of the jet of
pressurized air, a driven liquid valve 22a, a nozzle driving line 22b for driving
the liquid valve 22a, a nozzle liquid line 22c for supplying the pressurized liquid,
and a nozzle air line 24c for supplying the pressurized air. The nozzle liquid line
22c is suppliable by a nozzle liquid connection 22' and is connectable to the liquid
port 22, and the liquid valve 22a, which is normally closed and adapted to switch
from the closed to the open configuration, is operational therebetween; the nozzle
driving line 22b is supplied by a driving connection nozzle 23 and is connected to
the liquid valve 22a to drive it from the closed to the open configuration; the nozzle
air line 24c is suppliable by a nozzle air connection 24' and is directly connected
to the air port 24.
[0017] According to another embodiment (Fig. 5; nozzle NO), the liquid valve 22a' is normally
open and adapted to switch from the open configuration to the closed configuration;
the nozzle driving line 22b is connected to the liquid valve 22a' to drive it from
the open configuration to the closed configuration.
[0018] According to yet another embodiment (Fig. 6; nozzle GZ NC), the nozzle 20 comprises,
moreover, a driven air valve 24a; the nozzle air line 24c is connectable to the air
port 24, and the air valve 24a, which is normally closed and adapted to switch from
the closed to the open configuration, is operational therebetween; the nozzle driving
line 22b is also connected to the air valve 24a to drive it from the closed to the
open configuration.
[0019] According to a first embodiment (Fig. 7), the head 18 comprises a head liquid line
32 connected to the nozzle liquid connections 22' of all the nozzles 20 of the head
face 18a of the head 18 and a head air line 34 connected to the nozzle air connections
24' of all the nozzles 20 of the head face 18a of the head 18.
[0020] A main liquid valve 32a, placed upstream of the head liquid line 32, is adapted to
be electrically controlled to open or close the pressurized liquid supply to the head
liquid line 32. Similarly, a main air valve 34a, placed upstream of the head air line
34, is adapted to be electrically controlled to open or close the pressurized air
supply to the head air line 34.
[0021] Further, the head 18 comprises a plurality of first head driving branches 33, wherein
each first head driving branch 33 is a driving line connectable to the respective
liquid valve 22a of a plurality of nozzles 20, for example, all the nozzles of a predetermined
row of a matrix M configuration or a region R configuration.
[0022] Further, first head driving valves 33a are provided, wherein each first head driving
valve 33a is located upstream of a respective first head driving branch 33 and adapted
to be electronically controlled to open or close the supply of driving fluid to said
first head driving branch 33.
[0023] Further, the head 18 comprises, for each nozzle 20, a driving management valve 35
arranged between each first head driving branch 33 and the liquid valve 22a of the
respective nozzle 20, e.g., normally closed and adapted to switch into an opening
configuration to place said first head driving branch 33 in communication with the
liquid valve 22a to drive it to open.
[0024] Further, the head 18 comprises a plurality of second head driving branches 37, wherein
each second head driving branch 37 is a driving line connected to the driving management
valves 35 of a plurality of nozzles 20, e.g., all the nozzles of a predetermined column
of a matrix M configuration or a region R configuration.
[0025] In other words, if the nozzles of a predetermined row comprise a first plurality
of nozzles and the nozzles of a predetermined column comprise a second plurality of
nozzles, said first plurality of nozzles and said second plurality of nozzles have
at least one nozzle in common.
[0026] Moreover, second head driving valves 33b are provided, wherein each second head driving
valve 33b is placed upstream of a respective second head driving branch 37 and adapted
to be electronically controlled to open or close the driving fluid supply to said
second head driving branch 37.
[0027] In normal use of the head 18 in said embodiment, starting with an initial configuration
wherein the main liquid valve 32a is closed, the air main valve 34a is closed, all
first head driving valves 33a are closed, and all second head driving valves 33b are
closed, the main air valve 34a may be opened, causing air to be blown from the air
ports 24 of all the nozzles 20, which is sometimes desired for cleaning the half-mold.
[0028] Alternatively or subsequently, the main liquid valve 32a may be opened to put pressure
on the head liquid line 32; however, as long as there is no driving of the liquid
valves 22a of the nozzles 20, no dispensing of the liquid will occur. The opening
of a predetermined first head driving valve 33a allows for pressurizing and supplying
driving fluid to a respective first head driving branch 33, which is intercepted,
upstream of the respective nozzles 20, by the respective driving management valves
35, so that, as long as there is no driving of the driving management valves 35, there
is no opening of the respective liquid valves 22a. Finally, the opening of a predetermined
second head driving valve 33b allows for the respective driving management valves
35 to be driven to open, and this allows for the liquid valves 22a of the nozzles
20 supplied by the first head driving branch 33 corresponding to the first open head
driving valve 33a to open.
[0029] In other words, such a system allows liquid to be dispensed from a predetermined
nozzle Uij by opening the i-th first head driving valve 33a and the j-th second head
driving valve 33b. As a result, by combining the openings of the first head driving
valves 33a and the second head driving valves 33b, it is possible to select individually
the nozzles of an entire matrix M or region R to be enabled for liquid dispensing
according to the requirements.
[0030] In still other words, the head setting method comprises:
- a) actuating the first head driving valve 33a for fluidly selecting the first plurality
of nozzles (20);
- b) actuating the second head driving valve 33b for fluidly selecting the second plurality
of nozzles (20);
- c) said predetermined common nozzle being thus identified and activated for dispensing
a lubricating and/or cooling fluid.
[0031] The nozzles 20 mentioned above are of the nozzle type NC; according to a variant,
said nozzles are of the nozzle type NO.
[0032] According to yet another embodiment (Fig. 8), each nozzle 20 comprises an air valve
24a (nozzle GZ NO, Fig. 6), which is connectable to the first head driving branch
33 by means of the respective driving management valve 35, which in turn may be drivable
by the second head driving branch 37.
[0033] This allows the jet of air to be controlled by the air port 24 of the nozzle 20,
together with the jet of liquid. Obviously, by keeping the main liquid valve 32a closed
and opening the main air valve 34a, air-only blowing may be performed on the mold,
using the individually selected nozzles.
[0034] In general, in all of the aforesaid embodiments, to some nozzles 20 or to the nozzle
seats of the head to which said nozzles are applied, if not used, special caps are
applied that prevent the outflow of liquid and air, even though they are connected
to the supply lines.
[0035] The driving management valve 35 is a driven check valve, suitable for maintaining
pressure in the driving line to which it is connected downstream, even when the driving
fluid supply from the respective first head driving valve 33a ceases, and when the
command coming from the respective second head driving valve 33b to drive to open
ceases, since said downstream driving line is not connected to the drain.
[0036] This allows a head 18 to be quickly set up for lubrication and/or cooling of a mold
by means of successive activations of the first head driving valves 33a and of the
second head driving valves 33b.
[0037] For example, with reference to Fig. 9, it is assumed that the nozzles U11, U13, U22,
U24, U31, U33, U34, U42, and U43 must be activated. While the main liquid valve 32a
is closed, the main air valve 34a is closed, and the main driving line 39 is pressurized:
- the 1st second head driving valve 33b, the 1st first head driving valve 33a, and the
3rd first head driving valve 33a are activated; when these valves are then deactivated,
the driving of the nozzles U11 and U31 remains active and pressurized by virtue of
their respective driving management valves 35;
- the 2nd second head driving valve 33b, the 2nd first head driving valve 33a and the
4th first head driving valve 33a are activated; when said valves are then deactivated,
the driving of the nozzles U22 and U24 remains active and pressurized by virtue of
their respective driving management valves 35;
- the 3rd second head driving valve 33b, the 1st first head driving valve 33a, the 3rd
first head driving valve 33a, and the 4th first head driving valve 33a are activated;
when these valves are then deactivated, the driving of the nozzles U31, U33 and U34
remains active and pressurized by virtue of their respective driving management valves
35;
- the 4th second head driving valve 33b, the 2nd first head driving valve 33a, and the
3rd first head driving valve 33a are activated; when these valves are then deactivated,
the driving of the nozzles U42 and U43 remains active and pressurized by virtue of
their respective driving management valves 35.
[0038] By then operating the main liquid valve 32a and the main air valve 34a at the beginning
of each molding cycle, it is possible to spray the surface of the mold with a nebulized
jet.
[0039] Ultimately, the setting method of the present invention is executable by a head 18
- wherein said head 18 comprises:
- a) a first plurality of nozzles 20 fluidly selectable for activation by actuating
a first head driving valve 33a;
- b) a second plurality of nozzles 20 fluidly selectable for activation by actuating
a second head driving valve 33b, wherein said first plurality of nozzles and said
second plurality of nozzles have at least one predetermined nozzle in common;
- and wherein the method comprises:
- a) actuating the first head driving valve 33a for fluidly selecting the first plurality
of nozzles 20;
- b) actuating the second head driving valve 33b for fluidly selecting the second plurality
of nozzles 20;
- c) said predetermined nozzle in common being thus identified and activated for dispensing
a lubricating and/or cooling fluid.
[0040] According to an embodiment of the head, using a nozzle NO (Fig. 4), an air valve
24" is placed upstream of the nozzle 20 (Fig. 4a); similarly, using a nozzle NC (Fig.
5), an air valve 24" is placed upstream of the nozzle 20 (Fig. 5a).
[0041] A lubricating apparatus (Fig. 10) comprises the lubricator 14 described above, valve
means 90 comprising the first head driving valves 33a, the second head driving valves
33b, the main liquid valve 32a and the main air valve 34a, and a management device
100, which is operationally connected to the lubricator and valve means 90 for managing
lubricator operations.
[0042] The management device comprises electronic management means 105 adapted to be configured
or programmed, for example by software, for the programmed actuation of the main liquid
valve 32a, the main air valve 34a, the first head driving valves 33a and the second
head driving valves 33b. For example, said electronic management means comprise a
microchip or a dedicated circuit board.
[0043] Preferably, moreover, the management device 100 comprises storage means 110 adapted
to store data identifying a predetermined mold and setting data for identifying the
nozzles to be activated for lubricating or cooling said predetermined mold.
[0044] The storage means 110 are operationally connected with the electronic management
means and, preferably, with the lubricator 14, so that, when a predetermined mold
is reused, the nozzles identified by the setting data are automatically activated
by the electronic management means 105.
[0045] According to another aspect of the invention, the management device 100 comprises
temperature detection means 115 adapted to detect the temperature at a plurality of
discrete locations identified on the face of a half-mold by defining temperature data
comprising a temperature matrix T wherein each discrete location on the face of the
half-mold corresponds to the detected temperature.
[0046] The management device 100 further comprises processing means 120 adapted to process
the temperature matrix T and generate nozzle setting data to define which nozzles
to activate in order to achieve optimal lubrication or cooling of the half-mold.
[0047] The processing means 120 are operationally connected to the electronic management
means 105 to activate the nozzles identified by the setting data during the lubrication
and/or cooling cycles performed between molding cycles.
[0048] Innovatively, the head with a nozzle setting system according to the present invention
meets the needs of the industry and overcomes the drawbacks discussed above with reference
to the prior art.
[0049] Advantageously, for example, the head allows, when setting the nozzles, to work remotely,
eliminating the need for the operator to physically intervene on the head.
[0050] Advantageously, moreover, the head allows for nozzle setting operations to be performed
quickly and the preferred setting for a predetermined mold to be stored so that it
may be recalled in subsequent operations.
[0051] According to another advantageous aspect, the head according to the invention allows
for predetermined and automatic nozzle cleaning cycles to be carried out.
[0052] According to yet another advantageous aspect, the head according to the invention
allows for working together with a thermo-detection system operating on the mold,
to coordinate and optimize the lubrication and cooling of the molds.
[0053] It is clear that a person skilled in the art, in order to satisfy current needs,
could make modifications to the head described above, said modifications all being
contained within the scope of protection defined in the following claims.
1. A lubricating and/or cooling apparatus for a molding machine for metal materials,
comprising:
A) a lubricator (14) comprising a lubricating head (18) comprising:
i) a head body (18b) having a head face (18a);
ii) a plurality of nozzles (20), wherein each nozzle (20) is applicable to the body
face (18a) and has a liquid port (22) and an air port (24), a drivable liquid valve
(22a), a nozzle driving line (22b) for driving the liquid valve (22a), a nozzle liquid
line (22c) for supplying the pressurized liquid and a nozzle air line (24c) for supplying
the pressurized air, wherein the liquid valve (22a) is operational between the nozzle
liquid line (22c) and the liquid port (22), the nozzle driving line (22b) is connected
to the liquid valve (22) to drive it, and the nozzle air line (24c) is connectable
to the air port (24);
iii) a head liquid line (32) connected to the nozzles (20) for supplying the respective
liquid ports (22), a head air line (34) connected to the nozzles (20) for supplying
the respective air ports (24);
iv) a plurality of first head driving branches (33), wherein each first head driving
branch (33) is a driving line connectable to the respective liquid valve (22a) of
a first plurality of nozzles (20);
v) for each nozzle (20), a drivable driving management valve (35), operational between
each first head driving branch (33) and the liquid valve (22a) of the respective nozzle
(20);
vi) a plurality of second head driving branches (37), wherein each second head driving
branch (37) is a driving line connected to the driving management valves (35) of a
second plurality of nozzles (20), said first plurality of nozzles and said second
plurality of nozzles having at least one nozzle in common;
B) valve means (90) comprising:
i) a plurality of first head driving valves (33a), wherein each first head driving
valve (33a) is placed upstream of a respective first head driving branch (33) and
is electronically controllable for supplying the driving fluid to said respective
first head driving branch (33);
ii) a plurality of second head driving valves (33b), wherein each second head driving
valve (33b) is placed upstream of a respective second head driving branch (37) and
is electronically controllable for supplying the driving fluid to said second head
driving branch (37);
iii) a main liquid valve (32a) placed upstream of the head liquid line (32) and electrically
controllable for opening or closing the supply of pressurized liquid to the head liquid
line (32), and a main air valve (34a) placed upstream of the head air line (34) and
electrically controllable for opening or closing the supply of pressurized air to
the head air line (34).
2. An apparatus according to claim 1, wherein each nozzle (20) comprises a drivable air
valve (24a), operational between the nozzle air line (24c) and the air port (24),
wherein the nozzle driving line (22b) is also connected to the air valve (24a) to
drive it.
3. An apparatus according to claim 1, comprising, for each nozzle (20), a drivable air
valve (24a), outside the respective nozzle (20), operational between the nozzle air
line (24C) and the air port (24), wherein the nozzle driving line (22b) is also connected
to the air valve (24a) to drive it.
4. An apparatus according to any one of the preceding claims, wherein the driving management
valve (35) is a driven check valve.
5. An apparatus according to any one of the preceding claims, comprising a management
device (100) for managing the lubrication and/or cooling operations.
6. An apparatus according to claim 5, wherein the management device (100) comprises electronic
management means (105) adapted to be configured or programmed for the programmed actuation
of the main liquid valve (32a), the main air valve (34a), the first head driving valves
(33a) and the second head driving valves (33b) as a function of setting data defining
the nozzles to be activated.
7. An apparatus according to claim 6, wherein the management device (100) comprises storage
means (110) adapted to store identification data of a predetermined mold and setting
data of the nozzles corresponding to said predetermined mold for identifying the nozzles
to be activated for said predetermined mold.
8. An apparatus according to claim 5 or 6, wherein the management device (100) comprises:
- temperature detection means (115) adapted to detect the temperature of a plurality
of predetermined discrete positions on the face of a half-mold, defining temperature
data consisting of a temperature matrix (T), wherein the detected temperature corresponds
to each discrete position of the face of the half-mold; and
- processing means (120) adapted to process the temperature matrix (T) and generate
setting data of the nozzles for defining the nozzles to be activated in order to obtain
an optimum lubrication and/or cooling of the half-mold as a function of the detected
temperatures.
9. A method for setting a lubrication and/or cooling apparatus for a molding machine
for metal materials,
- said apparatus according to any of the preceding claims;
- wherein the method comprises:
a) actuating the first head driving valve (33a) for fluidly selecting the first plurality
of nozzles (20);
b) actuating the second head driving valve (33b) for fluidly selecting the second
plurality of nozzles (20);
c) said predetermined nozzle in common being thus identified and activated for supplying
a lubricating and/or cooling fluid.
10. A method for setting a lubrication and/or cooling head (18) for a molding machine
for metal materials,
- wherein said head (18) comprises:
a) a first plurality of nozzles (20) selectable for activation by actuating a first
head driving valve (33a);
b) a second plurality of nozzles (20) selectable for activation by actuating a second
head driving valve (33b), wherein said first plurality of nozzles and said second
plurality of nozzles have at least one predetermined nozzle in common;
- and wherein the method comprises:
a) actuating the first head driving valve (33a) for fluidly selecting the first plurality
of nozzles (20);
b) actuating the second head driving valve (33b) for fluidly selecting the second
plurality of nozzles (20);
c) said predetermined nozzle in common being thus identified and activated for dispensing
a lubricating and/or cooling fluid.