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Claims  |
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I claim:
1. A tank system for multicolor dispensing of tinting fluids to printing
equipment or the like, requiring a continuous flow of fluids, comprising:
a. a plurality of tank means for containing fluids, at least one per color
to be dispensed, each having inlet ports for entry of fluids into the tank
located above the level of the fluid in the tank, and outlet ports for
exit of fluid from the tank means;
b. inlet manifold means for conveying fluid to the tank means, for location
above the fluid level in the tank means, comprising:
1. a level conduit having top, bottom, and side walls, a plurality of
outlet ports in the side walls, a plurality of input port means for
admitting fluid into the level conduit;
2. a plurality of valve means, at least one per tank, each having an input
and an output, the input sealably connected to an outlet port of the
conduit, and the output of at least one valve means per tank connected to
an inlet port of one of the tank means and each having open and closed
positions for controlling fluid flow from the outlet ports;
3. each of the outlet ports and valves being level with the conduit, such
that fluid cannot pool in the ports, valves or conduit;
c. output manifold means for conveying fluid from the tank means, located
above the tank means, comprising:
1. a sloping conduit having a top, a bottom, and side walls, upper and
lower ends, a plurality of inlet ports in the top and a plurality of
output ports;
2. Drain valve means for draining the output manifold, having open and
closed positions, an input sealably connected to the lower end of the
conduit and an output connected to an input port in the conduit of the
inlet manifold means;
3. A plurality of inlet valve means, at least one for each tank means,
located at the inlet ports of the conduit, each having an input and an
output, the output sealably connected to an inlet port of the conduit;
4. a plurality of input tube means each having two ends, an output end
connected to the input of the inlet valve means, and an input end for
location below the fluid level in the tank means;
d. a plurality of pump means connected to the output manifold means for
causing fluid to flow into the output manifold means from the tank means
via the tube means;
e. output means for supplying fluid to the printing equipment having an
input connected through a valve to an output port of the output manifold
means, and an output adapted to supply fluid to the printing equipment;
f. input means for accepting excess fluid from the printing equipment
having an output connected to an input port means of the inlet manifold
and an input adapted to receive fluid from the printing equipment.
2. The tank system of claim 1, further comprising means for flushing
tinting fluid out of at least the inlet manifold means.
3. The tank system of claim 2 in which the flushing means comprises:
a. flush tank means for holding a flushing fluid located above the inlet
manifold means;
b. tube means connecting the flush tank means to an input port means of the
inlet manifold means, having valve means for controlling flow of the
flushing fluid;
c. said flushing means being arranged such that when the valve means of the
tube means are opened, flushing fluid is permitted to flow from the flush
tank through the inlet manifold.
4. The tank system of claim 3 in which the tube means of the flushing means
connects to an inlet port of the output manifold, and the flushing means
thus flushes both inlet and output manifold means.
5. The tank system of claim 3 further comprising: drain valve means having
an output and an input, the input being connected to an outlet port of the
inlet manifold means; and catch basin means connected to the output of the
drain valve means.
6. The tank system of claim 5 further comprising recirculating means for
conveying flushing fluid from the catch basin means to the flush tank
means.
7. The tank system of claim 1 in which the pump means comprises a plurality
of pumps, one for each tank, in the input tube means of the output
manifold means.
8. The tank system of claim 7 in which each pump is submerged in the fluid
in the tank.
9. The tank system of claim 1 in which the pump means comprises a single
pump located in the output manifold between the input and output ports.
10. The tank system of claim 1 in which the pump means is non-electric.
11. The tank system of claim 10 in which the pump means is operated by
compressed air.
12. The tank system of claim 1 in which the valve means are remotely
controllable.
13. The tank system of claim 12 in which the valve means are non-electric.
14. The tank system of claim 13 in which the valve means are operated by
compressed air.
15. The tank system of claim 1 in which the tanks are sealed air-tight,
whereby fumes emitted by the fluid in the tank may not escape.
16. The tank system of claim 15 further comprising a positive-ventilation
valve on each tank permitting air to enter, but preventing fumes from
escaping.
17. The tank system of claim 1 in which the valves of the inlet and output
manifolds are arranged such that only one valve in each of the inlet and
output manifolds is open at one time.
18. A non-recirculating tank system for multicolor dispensing of fluids to
printing equipment or the like, comprising:
a. a plurality of tank means for containing fluids, at least one per color
to be dispensed, each having a fluid port for location above the level of
the fluid in the tank with tube means for extending therefrom to a point
below the level of fluid in the tank, and an air port for introduction of
compressed air into the tank means;
b. manifold means for conveying fluid to and from the tank means, for
location above the fluid level in the tank means, comprising:
1. a level conduit having top, bottom, and side walls, and a plurality of
side ports in the side walls, and supply port means for withdrawing fluid
from the conduit;
2. a plurality of valve means, at least one per tank, each having two
ports, with control means for controlling flow therebetween, the first
port being connected to a side port of the conduit, and the second port of
at least one valve means per tank being connected to a fluid port of one
of the tank means;
3. each of the first ports and valves being level with the conduit, such
that fluid cannot pool in the ports, valves or conduit;
c. air supply means connected to the air ports of the tank means for
causing air to flow into the tanks means, causing a pressure therein;
d. output means for supplying fluid to the printing equipment having an
input connected through a valve to the supply port of the manifold means,
and an output adapted to supply fluid to the printing equipment. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
The inventon pertains to the field of systems for containing and dispensing
multiple fluids. More specifically, the invention presents a system
especially suited for multicolor tinting inks, for use in printing
apparatus or the like.
As the cost of paper has increased in recent years, it has become less
economical for printers to stock large quantities of different colored
paper stock. Instead, many printers have turned to "web tinter" systems.
These color the base paper stock before use, allowing the printer to
replace a multitude of different colored paper with cheaper white stock,
which is then tinted whatever color is required by the job. Typically, the
inks or dyes used in such applications are alcohol based and must be kept
circulating through the tinter.
Currently, a single tank or pail of ink serves as a source of dye. The dye
is pumped into a fountain on the tinter. A drain is provided in the side
of the fountain as an overflow, from which excess dye is dumped back into
the pail. This method is satisfactory while in use for a single color,
although this use of open pails with volatile and flammable dyes does lead
to concerns about safety. To change colors, the press operator must drain
the fountain, disconnect the pail, flush the lines with clear alcohol,
then connect a new pail. Each step is done manually. The fluids must be
poured to and from tanks or pails, and lines transferred, all of which
leads to problems with spillage and loss of dye. The current method of
color changing is obviously messy and unsafe.
It is an object of the invention to provide a system for containing
multiple tinter dyes with a minimum of manual handling, spillage and
escape of fluid.
It is a further object of the invention to provide a system for dispensing
tinter dyes which permits changing colors easily and quickly.
It is a still further object to provide a fluid-handling system for
multiple fluids which minimizes the danger from the use of flammable
liquids.
Another problem with present methods of changing colors is that of
contamination of one dye stock by the last-used stock. The dye left in the
lines and in any connecting piping will flow into the next tank of dye,
unless special precautions are taken to clean the equipment. This is
especially true in recirculating systems, with the added complexity and
piping involved.
It is thus an object of the invention to provide a multicolor tank system
for tinter inks which allows changing colors with a minimum of
contamination of the dyes by other colors.
SUMMARY OF THE INVENTION
The invention presents a dispensing system especially suited to
recirculating dye systems.
A plurality of tanks dispense fluid to an output manifold, which is tilted
so that it will drain by gravity to one end. Each line from a tank to the
manifold has a valve to control output and prevent back flow into the
tank. The valves enter the manifold from above, so as to gravity drain
into the manifold when the valve closes. A line from the output manifold
leads to the tinter fount.
The low end of the output manifold is shut off with a drain valve. The
output of the drain valve, and the overflow and a drain line from the
tinter fount, is led back to the same tank, containing the color being
used, by an inlet manifold. The inlet manifold is level, with outlet
valves leading from its sides into the tanks. This level arrangement
eliminates low spots and allows all of the fluid in the manifold to drain
through whichever output valve is open.
A flushing system may be provided, either by an extra tank, by circulating
fluid through the system, or by a reservoir draining through the inlet
manifold to a catch basin, which can be dumped. Because of its design, the
output manifold will self-drain, and thus need not be flushed.
In a non-recirculating embodiment, the output manifold can be eliminated.
Each tank is pressurized by an air supply, and fluids are forced into the
inlet manifold by the pressure. Draining and flushing are accomplished as
in the recirculating versions, when pressure in the tank is released.
DESCRIPTION OF THE DRAWING
FIG. 1 shows an over-all view of the invention in use.
FIG. 2 shows a cut-away view of the preferred embodiment of the invention.
FIG. 3 shows an end cut-away view of one tank.
FIG. 4 shows another embodiment of the invention.
FIG. 5 shows a timing diagram of the system as used.
FIG. 6 shows a cut-away view of a single tank in a non-recirculating
embodiment of the invention.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
FIG. 1 shows the invention in use, FIGS. 2 and 3 are cut-away views. In all
cases, like numbers indicate like components. For convenience, where
multiple identical elements are used, appended letters indicate a feature
associated with a given tank: Thus (22A) is a pump in a tank "A", (22B) an
identical pump in tank "B", etc.
The invention comprises a large, fluid-tight tank assembly (1) divided up
into a number of tanks (A), (B), (C), (D) etc, each of which is
fluid-tight and isolated from the others. For safety, given the volatile
nature of the dyes used, the tanks are preferably at least covered (24)
and may be made air-tight. In such a case a valve (25) must be provided to
allow air to enter as the fluid level is pumped down. This valve (25) may
be actuated with the controls for the tank, or be a simple one-way ("PCV"-
Type) valve, allowing air in, but not out. Each tank is provided with
holes or "ports" for introduction ("inlet" or "inputs" ports) or
withdrawal ("outlet" or "output" ports) of fluid from the tank.
The heart of the invention, especially in its recirculating embodiments, is
the two manifolds, inlet (4) and output (3). Each manifold is provided
with holes or "ports" for introduction ("inlet" or "input" ports) or
withdrawal ("outlet" or "output" ports) of fluid from the manifold. The
output manifold (3) is above the inlet manifold (4) and the tanks and
slopes to a drain valve (12) at one end. From the drain valve (12), a tube
(13) leads to an input port of the inlet manifold. Thus, if the valve (12)
is opened, the output manifold may gravity drain into the inlet manifold.
By contrast, the inlet manifold (4), below the output manifold (3) but
above the fluid level (26) in the tanks (2), is level from end to end.
Valves (7) lead off from outlet ports in the side of the inlet manifold
(4) and through level pipes (8) drain into the tanks (2) through the tank
inlet ports.
It is vital that the inlet manifold (4) and valves (7) be level (and pipes
(8) must be level or slope into the tank), so that there will be no "low
spots" in the inlet manifold to collect fluid. Thus, if valve (7A) is
open, all of the fluid in the manifold will drain into tank (A), leaving
none behind to contaminate the next dye.
Fluid from each tank (2) is pumped into from the tank through an input tube
means (5) to an inlet port in the top of the output manifold (3). Each
tank may have a submerged pump (22), as shown, or the pump may be located
outside the tank. If desired (FIG. 4) a single pump (27) may replace the
plurality of smaller pumps, leaving the lower end (28) of the tank feed
pipe (5) open, in which case the pump is located at the low end of the
output manifold (4) above the drain valve (12). A drain (29) and drain
valve (30) may be provided for the pump itself (27), if appropriate. In
either case, each input tube means (5) is equipped with an inlet valve (6)
located above the inlet port of the output manifold (3). This allows the
valve to gravity drain into the manifold, and prevents "low spots" in
which fluid may collect.
The valves may be manually operated or remotely controlled via a control
panel (14). If remote, it is desirable to use non-electric, preferably
air-operated, valves, to minimize the likelihood of sparks near the
flammable fluids. Similarly, air-operated pumps are preferred, especially
for non-submerged pumps, although electric pumps may be used.
The fluid from an output port of the output manifold (3) is fed to the
device requiring the fluid, here shown as a web tinter, mounted on a press
(15) (only partially shown), via tube (17). The excess or used fluid
returns to an input port of the inlet manifold (4) via return line (18).
As shown in FIGS. 1 and 2, the using device may have a reservoir or fount
(16) fed through tube (17). When the fluid reaches a pre-determined level
it overflows through tube (19) to recirculate back to the tank via the
inlet manifold through return line (18). A drain (21) is provided to drain
the fount (16) to the return line (18).
In a non-recirculating system (FIG. 6), for example if the device using the
fluid uses a float and valve to control fluid level, the invention may be
provided with an air-supply system in place of the outlet manifold. A
single, level manifold (44) then serves to convey fluid from the tanks,
and to drain back into them. A source of compressed air (40) pressurizes
the tank (41) containing the fluid (42) to be dispensed, through an air
port (48). When the valve (43) located at a side port (47) in the side of
the manifold (44) is opened, fluid is forced into a tube (45) extending
from under the fluid level in the tank to an outlet port (46) of the tank,
and to the valve (43) on the manifold, through a supply port of the
manifold and up to the device fount. To drain, the pressure is released,
and everything proceeds as for the recirculating system.
Although eight, four and three tanks are shown in FIGS. 1, 2 and 4,
respectively, it will be understood that any number of tanks may be
included within the teachings of the invention. The actual number used
will depend upon the number of colors commonly used in a given shop.
In its simplest form, the invention may be built with only those elements
discussed above. It is preferred, however, to provide a means for flushing
the last-used dye from the system before introducing the next color. This
is done through the use of a flushing solution, most likely clear alcohol
(or whatever is used as the dye base). It would be possible to add another
tank (i.e. seventh tank to a six-color set-up) and run the system for a
period on a supply of clean fluid from that tank, replacing the fluid
periodically. This has the disadvantage that the fluid in the extra tank
will deteriorate, as it is used over and over, and inadequate flushing
will inevitably result in time.
The design of the invention allows a simpler and more effective method to
be used. Because the entire system gravity-drains into the inlet manifold,
it is only necessary to flush that manifold. A small flush tank (9) of
flushing liquid (23) is located above the inlet manifold (4) and connected
to it by a tube (11) and valve (10). Once the system is drained, valve
(10) is opened for a short period, flushing the manifold (4) into the
last-used tank. The addition of a small quantity of clear fluid should
have no effect upon the dye in the tank, and might serve to make up for
losses from the fount due to evaporation and paper absorption. It this is
not desired, a drain valve (31) can be installed in the side of the inlet
manifold (4) (level, as in valves (7)) and a tube (32) led from that valve
(31) to a catch basin or pail (33), the contents of which may be discarded
after flushing, or recycled back to tank (9). If desired the flush tank
may be connected with the outlet manifold, as shown at (34), flushing both
manifolds.
FIG. 5 shows a timing diagram to clarify the sequence of operations of the
invention in use. At the beginning (to), the tinter is running color 1,
(i.e. blue) from tank "A". Inlet (7A) and outlet (6A) valves to that tank
are open. The operator wishes to switch the system to color 2, (i.e.
green) from tank "B". At (t1) he begins the change-over. At (t1) he begins
the change-over. Valve (6A) is closed, admitting no further fluid from
tank "A", and the pump (22A) is turned off (the valves (6) and pumps (22)
may be ganged on a single control, if desired). The output manifold drain
(12), and fount drain (21) are opened, and both gravity drain into the
inlet manifold. After these have drained (t2), the fount drain is closed.
The output manifold drain (12) may be closed, or can remain open, as
shown, if the connection shown at (27) in FIG. 2 is used. Fluid is
admitted from the flush tank by valve (10) between (t2) and (t3), and
flushes into tank "A" through valve (7A). The valve (10) is closed at (t3)
and the inlet manifold drains. At (t4), valve (7A) is closed, and valves
(7B) and (6B) are opened, and pump (22B) switched on. Fluid is pumped from
tank "B" through (6B) to the output manifold into the fount (16). When the
fount is full, the overflow returns to "B" through (19), (18) and the
inlet manifold (3) and valve (7B), and the tinter is ready to go in the
new color.
In addition to the flush tank, the basic invention may be modified to
include automatic control and sequencing of the valves. An interlock may
be added to ensure that only one valve on each manifold may be operated at
once, and preventing simultaneous operation of inlet and output valves on
different tanks.
Accordingly, it is to be understood that the embodiments of the invention
herein described are merely illustrative of the application of the
principles of the invention. Reference herein to details of the
illustrated embodiments are not intended to limit the scope of the claims
which themselves recite those features regarded as essential to the
invention.
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Description |
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