Printhead ink supply device

A foam unit for storing ink includes a porous member impregnated with ink and a film member wrapped around the porous member. A foam storing case has an opening for allowing insertion and removal of the foam unit into and from the case and a lid adapted to engage with the opening of the foam storing case. When the foam unit is inserted into the foam storing case, an O-ring engages with a projecting portion, and the film is burst by the projecting portion causing the foam member to abut against a filter. Then, a lid is fitted to the opening of the foam storing case. Thus, the foam unit is quickly and neatly replaced, and the ink impregnated in the replaced foam unit can be supplied to a print head.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
The present invention relates to an ink supply device for supplying ink to 
a print head. 
2. Description of Related Art 
A conventional ink supply device is disclosed in U.S. Pat. No. 4,771,295, 
for example. The ink supply device is a head integrated-type ink cartridge 
having an ink tank to which a print head for jetting ink is integrally 
mounted. A porous member (which will be hereinafter referred to as a 
"foam" member) impregnated with the ink is provided inside the ink tank. 
The ink tank is provided with an ink supply passage for communication 
between the print head and the inside of the ink tank. A filter is 
disposed at one end (an ink supply opening) of the ink supply passage 
opening into the ink tank. Further, the ink tank is provided with an 
atmospheric air communication hole for communication between the inside of 
the ink tank and atmospheric air. The ink cartridge is mounted on a 
carriage. The carriage is reciprocated, and simultaneously the print head 
is driven to jet the ink, thereby printing desired data on printing paper. 
Thus, the foam member impregnated with the ink is enclosed in the ink tank. 
As compared with an ink cartridge that has only the ink enclosed in the 
ink tank, the above-mentioned ink cartridge with an open-type ink supply 
mechanism effectively prevents the leakage of the ink from the atmospheric 
air communication hole owing to the ink retentivity of the foam member. 
Furthermore, the ink cartridge buffers a pressure fluctuation in the ink 
tank caused by movement of the ink due to acceleration upon reciprocation 
of the carriage. 
However, the print head and the ink tank are integral with each other in 
the head integrated-type ink cartridge mentioned above. Accordingly, in 
replacing the ink cartridge with another one after fully using the ink, 
the print head is unavoidably thrown away. As a result, a user must bear 
the cost of a new print head, thus increasing a running cost. 
In recent ink jet printers considering such a problem, an ink cartridge 
having a replaceable ink tank has been used so that only the ink tank can 
be replaced with another one. FIG. 6 shows such an ink cartridge in 
schematic section. 
As shown in FIG. 6, an ink cartridge 61 includes an ink tank 56 as a resin 
case and a foam member 52 impregnated with ink. The foam member 52 is 
enclosed in the ink tank 56. The ink tank 56 is provided with an ink 
supply opening 60 for supplying the ink to a print head 50 for jetting the 
ink. A filter 54 is disposed at the ink supply opening 60. The foam member 
52 is in close contact with the filter 54. An atmospheric air 
communication hole 58 is formed through a wall of the ink tank 56 on a 
side opposed to the filter 54. 
The ink cartridge 61 is removably connected to the print head 50 fixed to a 
carriage (not shown). When the ink in the print head 50 is consumed by 
printing, suction maintenance, etc., the ink in the foam member 52 is 
supplied through the filter 54 to the print head 50. When the ink in the 
foam member 52 is consumed, the atmospheric air is introduced from the 
atmospheric air communication hole 58 into the foam member 52, thus 
ensuring full use of the ink and buffering a rapid pressure fluctuation 
occurring in performing the suction maintenance or the like. 
With this structure, the ink cartridge 61 only can be replaced with another 
one, and the print head 50 can be repeatedly used within its allowable 
service life. Thus, as compared with the above-mentioned head 
integrated-type ink cartridge having the print head and the ink tank 
integral with each other, the running cost can be reduced. 
However, to further reduce the running cost of the ink cartridge 61, it is 
necessary to provide an ink exchanging means at a low cost. Also, it is 
required that the user can exchange the ink easily without staining 
his/her hands. 
As such ink exchanging means, there has been proposed a method of injecting 
the ink by using an injector or the like as disclosed in U.S. Pat. No. 
4,589,000. In applying this method using the injector to the ink cartridge 
61 to supply the ink into the foam member 52, the foam member 52 continues 
to be used. Accordingly, the foam member 52 deteriorates by the injector 
in the course of repeatedly supplying ink and is broken into fine 
fragments. The fine fragments of the foam member 52 are introduced to the 
filter 54 together with the ink, thus blocking the filter 54 or entering 
the print head 50 causing deterioration in print quality. Further, there 
is a possibility of dust entering the foam member 52 upon injection by the 
injector causing deterioration in print quality. 
When the same injector is repeatedly used to supply ink from an ink 
container storing a large amount of ink to the ink cartridge 61, good 
quality ink may not be maintained because of a change in concentration of 
the ink, solidification of the ink, or entry of dust or the like in the 
injector or the ink container. This problem has conventionally been 
eliminated by closely storing the ink in the injector and only using the 
injector once for the supply of the ink to the ink cartridge 61. However, 
since the injector is thrown away after use continuously replacing the 
injector increases costs. 
SUMMARY OF THE INVENTION 
It is accordingly an object of the present invention to provide an ink 
supply device that can reduce cost and improve print quality. 
To achieve the above mentioned and other objects, an ink supply device of 
the present invention comprises a foam unit comprising a porous member 
impregnated with ink and a film member wrapped around the porous member, a 
foam storing case having an opening for allowing insertion and removal of 
the foam unit into and from the case, and a lid adapted to engage with the 
opening of the foam storing case. The foam storing case has a projecting 
portion projecting inside the case and forming an ink supply passage 
communicating with the print head. When the foam unit is inserted into the 
foam storing case, the foam unit is depressed by the projecting portion, 
and the film member of the foam unit is burst by the projecting portion to 
allow the ink contained in the porous member to be supplied through the 
ink supply passage to the print head. 
In the ink supply device of the present invention thus constructed, the 
foam unit having the porous member impregnated with the ink and the film 
member wrapping the porous member can be inserted into and removed from 
the foam storing case through the opening thereof. Further, the lid is 
engaged with the opening of the foam storing case. 
As apparent from the above description, according to the ink supply device 
of the present invention, the foam unit with an ink impregnated porous 
member and a wrapping film member is removably stored into the foam 
storing case from the opening thereof, and the lid is engaged with the 
opening of the foam storing case. Accordingly, the exchange of the ink can 
be performed by replacing only the foam unit with a new one. That is, the 
foam storing case for storing the foam unit can be reused without being 
thrown away, unlike the prior art wherein a case storing a foam member 
impregnated with ink must be thrown away after the ink is fully used. 
Thus, the cost of a new case is unnecessary thereby reducing the running 
cost. Further, since the porous member impregnated with ink is wrapped 
with the film member, there is no possibility that the user may touch the 
porous member to stain his/her hands.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS 
A preferred embodiment of the present invention is described with reference 
to the drawings. 
As shown in FIG. 2, a carriage 12 is slidably mounted on a shaft 14 to 
reciprocate along the width of a recording paper 11. A print head 16 (see 
FIG. 1) for jetting ink is mounted on the carriage 12. Further, a foam 
storing case 20 connected to the print head 16 is also mounted on the 
carriage 12. Recording of desired data onto the recording paper 11 is 
performed by reciprocating the carriage 12 and simultaneously driving the 
print head 16 to jet the ink onto the recording paper 11. 
As shown in FIG. 1, the print head 16 includes a nozzle portion 2, a 
piezoelectric element 4, and an electric connector 6. The piezoelectric 
member 4 and the connector 6 are connected together by a signal line (not 
shown). An electric signal corresponding to image information to be 
recorded is supplied to the connector 6 from outside the print head 16. 
When the electric signal is supplied, the piezoelectric element 4 is 
driven to jet the ink from the nozzle portion 2. 
Referring to FIG. 1, the foam storing case 20 is provided with an opening 
21 from which a wrapped ink impregnated foam unit 22 can be stored or 
removed. Further, the foam storing case 20 is formed with an ink supply 
passage 26 for supplying the ink to the print head 16. The ink supply 
passage 26 communicates at one end thereof with the print head 16 to form 
an ink channel leading to the nozzle portion 2. The other end of the ink 
supply passage 26 leads to an upper end of a projecting portion 28 
projecting into the foam storing case 20 from the inner wall thereof. The 
upper end of the projecting portion 28 has an opening serving as an ink 
supply opening 27. A filter 29 formed of stainless steel or the like is 
mounted on the upper end of the projecting portion 28. The filter 29 
preferably has an aperture size of 20 .mu.m or less. 
The foam unit 22 includes a foam member 30 impregnated with ink, a spacer 
32, and a film 34 such as a high-molecular resin film, tightly wrapped 
around the foam member 30 and the spacer 32. The film 34 is provided with 
a handling member 35, such as a tab or pull-strip, identical in material 
with the film 34. The handling member 35 is designed to be easily picked 
up by a user so that the user can easily draw the foam unit 22 out of the 
foam storing case 20. The foam member 30 functions to buffer a pressure 
fluctuation in the foam storing case 20 caused by movement of the ink due 
to acceleration upon reciprocation of the carriage 12. The spacer 32 
preferably has a shape as shown in FIG. 3, and it functions to smooth the 
introduction of atmospheric air into the foam member 30. As shown in FIG. 
3, the spacer 32 is constructed of four bar members 33 forming a grid 
portion. The grid portion is provided with four recesses 71 to uniformly 
communicate the atmospheric air over the surface of the foam member 30 
exposed to the spacer 32. 
As shown in FIG. 4, an O-ring 36 is bonded to the film 34 on an under 
portion to engage with the projecting portion 28 of the foam storing case 
20 upon insertion of the foam unit 22 into the foam storing case 20. In 
bonding the O-ring 36, an excess amount of adhesive is applied to the 
lower surface of the foam unit 22 to form a thick applied portion 37 as 
shown by a dashed line in FIG. 4 with enhanced strength. The strength of 
the thick applied portion 37 is set to a value not less than 1.5 times the 
strength of the film 34. 
A lid 24 seen in FIG. 1 is removably engaged with the foam storing case 20 
at the opening 21. The lid 24 is provided with a inwardly projecting 
portion 38 defining an atmospheric air communication hole 39 and an 
inwardly projecting portion 40 for depressing the foam unit 22. Further, 
the lid 24 has an O-ring 42 as a sealing member for sealing the opening 21 
when engaging the lid 24 with the foam storing case 20. The assembled ink 
supply device is shown in FIG. 5. 
In operation of the ink supply device, the foam unit 22 is replaced with a 
new one in the following manner. 
First, the lid 24 engaged with the opening 21 of the foam storing case 20 
is removed, and the foam unit 22 stored in the foam storing case 20 is 
drawn out by pulling the handling member 35. Then, another new foam unit 
22 is inserted into the foam storing case 20. During the insertion of the 
foam unit 22, the O-ring 36 first comes into engagement with the 
projecting portion 28. The film 34 is then burst by the projecting portion 
28. As a result, the foam 30 abuts against the filter 29 as shown in FIG. 
5. In this preferred embodiment, the strength of the film 34, the hardness 
of the foam member 30, and the shape of the projecting portion 28, are 
designed so that when the force applied to the foam unit 22 during 
insertion into the foam storing case 20 is about 1.5 kgf or greater, the 
film 34 is burst. 
The O-ring 36 functions not only to guide the projecting portion 28 into 
position but also to enhance sealability so that the ink contained in the 
foam unit 22 does not leak. Thereby, the ink is prevented from sticking to 
the inner wall of the foam storing case 20. Further, the O-ring 36 
functions also to hold the projecting portion 28 by its own elastic force 
and thereby prevents the foam unit 22 from being released from the 
projecting portion 28 by the elastic force of the compressed foam member 
30. 
Even when the film 34 is burst by the projecting portion 28, the thick 
applied portion 37 shown in FIG. 4 is not burst because the strength of 
the thick applied portion 37 is higher than that of the film 34. 
Therefore, the thick applied portion 37 retains the burst portion of the 
film 34 as shown in FIG. 5 adjacent to the projecting portion 28. Thus, 
the burst portion of the film 34 is prevented from covering and closing 
the filter 29. 
It is preferable to preliminarily set an internal pressure in the foam unit 
22 higher than the atmospheric pressure. In this case, when the film 34 is 
burst by the projecting portion 28, the ink contained in the foam unit 22 
is automatically introduced into the ink supply passage 26. Alternatively, 
it is preferable to set a volume of the foam member 30 of the foam unit 22 
larger than a capacity of the foam storing case 20. In this case, when the 
foam unit 22 is inserted into the foam storing case 20, the foam member 30 
is compressed, which increases the internal pressure in the foam unit 22. 
Accordingly, the ink is similarly introduced into the ink supply passage 
26. 
After the foam unit 22 is completely inserted into the foam storing case 
20, the lid 24 is brought into engagement with the opening 21 of the foam 
storing case 20. At this time, the projecting portion 38 on the lid 24 
bursts the film 34. The lower end of the projecting portion 38 is located 
inside the grid portion of the spacer 32 as shown in FIG. 5, so that the 
atmospheric air communication hole 39 is brought into communication with 
the inside of the foam unit 22. Accordingly, atmospheric air is supplied 
to the foam member 30, and the ink contained in the foam member 30 is 
therefore smoothly supplied to the print head 16. Similar to the formation 
of the thick applied portion 37, a strength enhanced portion may be 
provided on the film 34 at a portion to be burst by the projecting portion 
38, so as to prevent the burst portion of the film 34 from completely 
breaking free and closing the atmospheric air communication hole 39. 
The atmospheric air is smoothly introduced from the atmospheric air 
communication hole 39 into the foam member 30 through the space defined 
between the foam member 30 and the film 34 by the spacer 32. As compared 
with the case when the spacer 32 is absent, the ink contained in the foam 
member 30 can be more fully used, and a rapid pressure fluctuation 
occurring in suction maintenance or the like can be more buffered. 
Further, the spacer 32 ensures a sufficient space between the foam member 
30 and the lid 24 to reduce a capillary force between the foam member 30 
and the lid 24. Thereby, the ink is prevented from flowing out through the 
atmospheric air communication hole 39. 
When the lid 24 is engaged with the opening 21 of the foam storing case 20, 
the projecting portion 40 depresses the foam member 30 through the film 34 
to thereby introduce the ink into the ink supply passage 26 and 
simultaneously prevent the foam member 30 from separating from the filter 
29. 
In the replacement of the foam unit 22 mentioned above, there is a 
possibility that air bubbles may enter the ink supply passage 26 from the 
filter 29. To cope with this possibility, the air bubbles are sucked with 
the ink from the nozzle portion 2, thereby removing the air bubbles in the 
ink supply passage 26. If the air bubbles reside in the print head 16, a 
pressure wave in jetting of the ink is damped by the compressibility of 
the air bubbles to reduce a print quality. Accordingly, such suction 
maintenance to suck the air bubbles with the ink is necessary. To shorten 
maintenance time and reduce a suction amount of the ink in suction 
maintenance, it is desirable that the volume of the ink channel leading 
from the foam member 30 to the nozzle portion 2 is set as small as 
possible. In this preferred embodiment, even if the air bubbles enter the 
ink supply passage 26 from the filter 29 during replacement of the foam 
unit 22, the ink is also introduced into the ink supply passage 26 by the 
replacement of the foam unit 22, thereby feeding the air bubbles toward 
the print head 16. As a result, the volume of the ink channel from the 
nozzle portion 2 to the air bubbles can be reduced. Accordingly, the 
removal of the air bubbles by the suction of the ink can be securely 
performed, and the suction amount of the ink for the removal of the air 
bubbles can be reduced. 
As the filter 29 is brought into pressure contact with the foam member 30, 
dust or the like can be prevented from entering the print head 16. 
Furthermore, in the case where the filter 29 has an aperture size as 
mentioned above, even if the air bubbles in the foam member 30 come into 
contact with the filter 29, the entry of the air bubbles into the ink 
supply passage 26 can be prevented by the surface tension of the ink 
acting on its interface formed at the openings of the filter 29. This 
effect depends upon the surface tension of the ink to be used. However, it 
can be enhanced by suitably modifying the aperture size of the filter 29. 
Further, the shape of the foam member 30 may be suitably designed to 
exhibit a capillary force of the foam member 30 and the above-mentioned 
effect of preventing the entry of the air bubbles, thereby allowing 
printing in any attitude and greatly improving a general-purpose 
applicability of the printer. 
As mentioned above, the exchange of the ink is performed by removing the 
foam unit 22 from the foam storing case 20 and then inserting a new one 
therein. Accordingly, the running cost can be reduced as compared with the 
prior art wherein the ink cartridge 61 (see FIG. 6) is replaced with a new 
one. Further, the user can easily exchange the ink without staining 
his/her hands. In addition, since the foam unit 22 is replaced with a new 
one, dust or the like having entered from the atmospheric air 
communication hole 39 sticks to the foam member 30, and is removed 
together with the foam member 30. Accordingly, dust or the like having 
entered from the atmospheric air communication hole 39 is prevented from 
reaching the print head 16, thus having no influence upon ink jetting and 
ensuring a good print quality. 
The film 34 of the foam unit 22 is first burst by the projecting portion 28 
of the foam storing case 20 when the foam unit 22 is inserted into the 
foam storing case 20. Accordingly, there is no possibility that the user 
may touch the foam member 30 impregnated with the ink to stain his/her 
hands or the like. 
In this preferred embodiment, the film 34 is burst by the projecting 
portion 28 when the force applied to the foam unit 22 in inserting the 
foam unit 22 into the foam storing case 20 is 1.5 kgf or more. However, 
the film 34 may be burst with a force lower than 1.5 kgf by suitably 
designing the strength of the film 34, the hardness of the foam member 30, 
and the shape of the projecting portion 28. 
In this preferred embodiment, the thick applied portion 37 is provided at a 
portion of the film 34 to be burst by the projecting portion 28 to prevent 
the burst portion of the film 34 from closing the filter 29 mounted on the 
tip of the projecting portion 28. As a modification, the tip of the 
projecting portion 28 may be so shaped as to incline with respect to the 
foam unit 22. In this case, when the foam unit 22 is inserted into the 
foam storing case 20, the film 34 of the foam unit 22 first comes into 
contact with the front edge of the inclined tip of the projecting portion 
28 and is burst by the inclined tip from a position contact with the front 
edge. Accordingly, the separation of the burst portion from the film 34 
does not occur to thereby prevent the closing of the filter 29. As another 
modification, the tip of the projecting portion 28 may be provided with a 
projection to burst the film 34 of the foam unit 22 so as not to close the 
filter 29. 
In this preferred embodiment, when the foam unit 22 is inserted into the 
foam storing case 20, the film 34 is burst by the projecting portion 28. 
As a modification, when the lid 24 is brought into engagement with the 
opening 21 of the foam storing case 20, the film 34 may be burst by the 
projecting portion 28. 
While advantageous embodiments have been chosen to illustrate the 
invention, it will be understood by those skilled in the art that various 
changes and modifications can be made therein without departing from the 
scope of the invention as defined in the appended claims.