EP0536980B1

EP0536980B1 - Method and apparatus for replenishing an ink-jet head with ink

Info

Publication number: EP0536980B1
Application number: EP92309101A
Authority: EP
Inventors: Alessandro Scardovi; Roberto Morandotti
Original assignee: Olivetti SpA; Ing C Olivetti and C SpA
Current assignee: Telecom Italia SpA; Olivetti SpA
Priority date: 1991-10-10
Filing date: 1992-10-06
Publication date: 1997-12-17
Anticipated expiration: 2012-10-06
Also published as: EP0536980A2; IT1250519B; ITTO910763A0; ITTO910763A1; DE69223584D1; EP0536980A3; DE69223584T2

Description

Background of the Invention

The present invention relates to a method and apparatus for replenishing an ink-jet print head with ink and more particularly to a device for use with ink-jet print heads incorporating an ink reservoir confining a porous body soaked with ink.
An apparatus for rapidly connecting and disconnecting a main reservoir located at a distance from the head to/from the ink container of the head containing a spongy body soaked with ink is known from US Patent No. 4,999,652. Through a hole formed in a wall of the container filled with a spongy body, it is possible to insert into the spongy body a hollow needle connected, via a tube, to the main reservoir. Thus the sponge, when it is partially empty, sucks from the main reservoir, by capillary action, a quantity of ink which replaces that previously used up.
Since the head is mounted on a carriage movable along a line of print, the connecting tube must have a considerable length in order to cover the maximum distance of the head from the main reservoir. Moreover, during the to-and-fro movement of the carriage, the tube is repeatedly bent, with the risk of the tube itself being damaged.
A further drawback which restricts, over time, the use of such a device is in the fact that repeated insertion and withdrawal of the needle into/from the sponge causes the walls to be perforated with a large number of pores resulting in a reduction in the capillary action in the part of the sponge adjacent to the needle. This drastically reduces the sponge's capacity to be charged with a fresh supply of ink.
In U.S. Patent No. 3,967,286 an arrangement for automatically supplying ink to a print head is disclosed, in which a reservoir integral with the print head is filled with a liquid absorbing material and has a fill opening. An associated liquid filling device is provided with a top fill opening closed by a plug having an air inlet opening and with a quantity of liquid ink into which a wick is at least partially submerged; one end of the wick passes through an opening in a side wall of the filling device. In use, the exterior end of the wick passes into the fill opening of the reservoir and, if there is no sufficient ink in the liquid absorbing material, the wick which has previously absorbed a considerable amount of liquid from the ink present in the filling device, will deliver part of this liquid to the reservoir.
A drawback of this solution is that under certain conditions it does not work properly: this especially occurs when the wick is put in contact with a portion of the liquid absorbing material inside the reservoir that is completely dried up, so that the hydraulic continuity is not easily ensured.
The present invention provides an apparatus for replenishing an ink-jet print head with ink, comprising a supply reservoir connected to the print head and containing a spongy body of a first porous material for supplying the ink to the print head, the spongy body having a first exposed portion communicating with the surrounding atmosphere through at least one opening in the supply reservoir and a second enclosed portion, a main reservoir filled with ink at atmospheric pressure up to a level; and connecting means for selectively connecting the supply reservoir to the main reservoir. The connecting means comprises a connection element made of a second porous material partially immersed in the main container and designed to be brought up to the first exposed portion of the spongy body by the at least one opening.
In a first aspect of the invention the apparatus is characterised in that said first exposed portion has a first capillarity and said second enclosed portion of the spongy body has a second capillarity different from said first capillarity, said first capillarity being greater than said second capillarity.
A second aspect of the invention is characterised in that the first porous material has a first rigidity and the second porous material has a second rigidity greater than the first rigidity, and the connection element is introduced partially into the opening so as to compress locally the spongy body, whereby the capillarity of the first exposed portion is rendered greater than the capillarity of the second enclosed portion.
A third aspect of the invention is characterised in that the supply reservoir includes a separator element located between the sponge body and the opening, the separator element being composed of a rigid porous material having a capillarity greater than the capillarity of the first porous material of the spongy body.
Preferred embodiments of the present invention provide a device for continually replenishing a print head designed to be repeatedly supplied with ink any number of times, without damage to the sponge contained in the head reservoir. The replenishing device, according to the last cited prior art, consists of a connecting element made of porous material and having one zone immersed in a main ink reservoir, the other end having the possibility to make contact with the spongy body in the print head ink reservoir via a hole in the wall of the head's reservoir. Substantial improvements have been made with respect to the prior art in order to ensure hydraulic continuity between the connecting element and the spongy body, defining a differential structure of the sponge in terms of capillarity.
In one embodiment of the invention the spongy body of a print head is replenished each time the head stops in a parked position, for example, during replacement of a sheet of paper.
The invention is defined with more precision in the appended claims to which reference should now be made.

Fig. 1 shows, as an example which is useful for understanding the invention, a simplified diagram of a connection between a spongy body and a main ink reservoir, obtained by means of a porous element.
Preferred embodiments of the invention are now described in detail by way of example with reference to the accompanying drawings, in which:
Figs 2-4 show modifications to the arrangement of Fig. 1;
Fig. 5 shows a replenishing device for the reservoir of a print head, using the arrangement of Fig. 1;
Fig. 6 is a variation of Fig. 5;
Fig. 7 shows an application, to a printer, of the replenishing device of Fig. 5;
Fig. 8 shows a modification to the printer of Fig. 7;
Fig. 9 shows a print head used on the printer of Fig. 8.

Figs. 1-4 illustrate the physical principle on which the ink replenishing device according to the invention is based.
As is known, when two spongy bodies 1 and 2 soaked to a differing extent with a liquid, for example ink, are brought into contact, hydraulic continuity is established via the contact surface 3.
The greater negative pressure existing in the spongy body which is less soaked with ink (the body 1 in the case of Figs 1-5) causes ink to be drawn from the other, more soaked body 2 until an equilibrium is established between the negative pressures in the two bodies 1 and 2. Therefore, since the body 2 is completely soaked with ink, being immersed in a main reservoir 4 full of ink 5 with a free surface making contact with the atmosphere via a hole 6, the body 1, when it is partially empty of ink, sucks ink from the reservoir 4 until it is almost entirely impregnated.
Figures 2-4 illustrate a few useful measures for ensuring initiation of the ink suction process by the spongy body 1.
In Fig. 2 a spongy body 1 is contained in a reservoir 10 having a hole 12 formed in a wall 11 for accommodating the body 2. A sleeve 14 is inserted into the hole 12, said sleeve projecting inside the reservoir 10 so as to create in the spongy body 1 a zone 15 which is more compressed and therefore has a greater capillarity than the portion 25 of the body 1 which is further away.
During emptying of the ink from the spongy body 1, for example in order to supply a print head (not shown in the drawings), the zone 15 will be the last zone to be emptied. Therefore, by arranging end-of-ink sensors (not shown in the drawings) in the vicinity of the zone 15 it is possible to know when this zone starts to become empty. By bringing at this point the free end 2′ of the body 2 up to the body 1 through the sleeve 14, hydraulic continuity is established in a reliable manner between the two bodies 1 and 2.
Fig. 3 shows the use of a spongy body 2 which is per se more rigid than the spongy body 1, or has been rigidified by a tubular support 16. In this case the body 2 is pressed through the hole 12 against the spongy body 1 so as to compress it locally inside the contact surface 3. In order to ensure initiation of the ink suction process by the body 1, the latter is packed inside the reservoir 10 so as to form a zone 18 which is more compressed in the vicinity of the bottom 11 and the hole 12.
Fig. 4 shows the use of a thin layer 20 of a rigid porous material, for example porous ceramic or Porex (registered trademark), i.e. a sufficiently rigid thin sheet which is obtained using sintered nylon microscopic balls. The porous layer 20 advantageously replaces the measures illustrated in Figs. 2 and 3.
Fig. 5 illustrates use of the principle of replenishment of the reservoir 10 with ink, in order to supply an ink-jet print head. The reservoir 10 is filled with a spongy body 1, subsequently referred to simply as a sponge, packed on the bottom so as to form a more compressed zone 22 which is roughly delimited with respect to the upper part 25 by a broken line 24.
The side wall 28 has formed in it a hole 30 for accommodating a spongy or fibrous body 32, referred to below as a connecting element for the ink, of the type indicated by 2 in Figs. 1-4.
More particularly the element 32 consists of a porous or fibrous material having a plurality of capillary ducts arranged in a bundle each with a diameter varying between 50 and 500 µm. The element 32 has an elongated cylindrical shape with a prismatic circular crows-section much larger than the cross-section of each capillary duct. The transverse dimension or diameter of the element 32 may vary between 3 and 15 mm.
The hole 30 leaves exposed a part 34 of the surface of the sponge 1, up to which one end 36 of the element 32 is brought. The element 32 may be made using one of the following materials:

1) Expanded polymer materials (sponges), for example consisting of:
- Polyether urethane
- Melamine resins
- Polyvinyl alcohol
2) Fibrous materials
- Polyurethane-coated polyester fibres (nibs)
- Natural fibres in general (wool, vegetable fibres)
- Polyamide fibres
These fibrous materials may be in the form of fabric, felt or "non-woven fabric".
3) Ceramic materials
- Porous ceramics in general
- Porex (registered trademark) (sintered nylon balls)

In the case where expanded polymer materials are used for the element 32, they are advantageously enclosed in a tubular sleeve 38 similar to that indicated by 16 in Fig. 3.
The reservoir 10 carries an ink-jet print head 40 integrally fixed to its bottom part. The head 40 may consist of a multi-layer plate 41 incorporating capillary cells each containing a resistance which can be actuated so as to expel drops of ink from corresponding nozzles 42 so as to print onto a horizontal sheet 43. The reservoir 10 together with the head 40 are mounted on a structure 44 forming part of a movable carriage (not illustrated for the sake of clarity) of a printer.
The plate 41 may be, for example, of the type described in European Patent Application No. 401996 published on 12 December 1990, in the name of the present Applicant.
A main reservoir 48 filled with ink is arranged underneath the head 40 so that the level of the ink forms a pressure head H of about 1-3 cm with respect to the head 40. The other end 32′ of the element 32 is immersed in the reservoir 48.
Simply bringing the element 32 up against the surface 34 of the sponge 1 causes the meniscuses of the capillary channels of the element 32 to be combined, and hence eliminated, with the meniscuses of the corresponding capillary channels of the sponge 1, thus creating hydraulic continuity between the ink inside the main reservoir 45 and the ink contained in the sponge 1. In extreme cases, hydraulic continuity is established even if the capillary channels of the sponge 1, which emerge at the surface 34, contain no ink. In fact, the meniscuses present at the end 36 of the element 32 rise up back along the channels of the sponge 1 until they encounter the ink which soaks them in a zone far from the surface 34.
However, to ensure hydraulic continuity, it is preferable for the hole 30 to be arranged so that it uncovers a zone of the sponge 1 where, owing to the compression exerted by the walls of the cartridge 10, there is a high degree of capillarity and hence the guarantee that this zone is emptied only just before all of the ink is used up.
It is in fact preferable that the contact between the sponge and the element 32 should occur in a zone which is always soaked with liquid connected to the ink contained in a chamber 45 supplying the plate 41 so that the sucking action always occurs at the right time.
The chamber 45 is always kept full of ink so as to prevent the presence of air bubbles in it affecting proper operation of the head. In this connection it is possible to pack the sponge inside the reservoir so as to obtain localised compression at the contact point. Or else, it is possible to use a sponge of varying capillarity (polyvinyl alcohol for example) so that it has a greater capillarity in a zone 52 close to the hole 30 and the chamber 45.
By way of example in Fig. 5, the zone 52 has been delimited by a (dotted) line 54 indicating a surface separating the part 52 with greater capillarity and the upper part 25 with reduced capillarity.
Obviously, in the embodiment of the ink replenishing device shown in Fig. 5, according to the invention, the measures illustrated in Figs. 2, 3 and 4 may be advantageously used to establish at the right time hydraulic continuity between the element 32 and the sponge 1.
In an alternative embodiment, the reservoir 10 may be replaced by a removable cartridge 55 (Fig. 6) inserted from above into the support 56 in turn mounted on the structure 44 of Fig. 5. The cartridge 55 contains a sponge 1 soaked with ink.
In the embodiment of Fig. 6, the print head 40 is integral with the support 56 and is not replaced together with the cartridge 55. The chamber 45 is delimited at the top by a sleeve 57 through which a porous or fibrous element 58 passes.
The element 58 is made using one of the materials listed above in connection with the element 32 of Fig. 5 and projects at the top by a distance so as to penetrate into a hole 59 of the cartridge 55 until it comes into contact with a free portion 60 of the sponge 1.
This system for achieving the hydraulic connection between the cartridge 55 and the chamber 45 supplying the plate 41 advantageously replaces other known and more complicated connecting systems which use, for example, a hollow needle associated with a filter for the ink. In fact, the element 58, as a result of its own capillarity, establishes a hydraulic connection between the sponge 1 and the chamber 45, performing at the same time a rigorous filtering action as regards all the impurities which may be present in the ink. Furthermore, the element 58 prevents air from passing into the chamber 45 even when no cartridge 55 is present, thus ensuring that there are no air bubbles inside the chamber 45.
Fig. 7 illustrates an application, to an ink-jet printer, of the device for replenishing the reservoir of the print head with ink, in accordance with the invention.
A print head 61 of the same type as that shown in Fig. 5 is mounted on a carriage 62 movable along a guide 64. The carriage is moved by a motor 65, via a cable 66, so as to print on a sheet 67 in both the directions indicated by the double arrow A.
At one end of its travel, the head 61 stops in a parked position R where an ink release element 70 comes into contact with the sponge 1 contained in the cartridge 10 of the head 61.
The release element 70 is entirely similar to that indicated by 32 in Fig. 5 and is formed using the materials listed above. The bottom end 72 of the element 70 is immersed inside a main reservoir 74 fixed to the structure 63 of the printer. The reservoir 74 contains 1 to 8 times as much ink as that contained in the cartridge 10 when the sponge 1 is completely soaked with ink.
The reservoir 74 is located lower down than the head 61 so that the pressure head H (Fig. 5) between the free surface of the ink inside the reservoir and the nozzles of the head 61 is between about 1 and 3 cm.
Each time the head 61 is kept in the parked position R, for example after printing a page on the sheet 67, the element 70 releases to the sponge 1, as a result of the capillary action, a quantity of ink which substantially replaces that used during printing.
Therefore, since replenishing of the reservoir 10 with ink may be performed very frequently, each time the head 61 stops in the position R, the dimensions of the reservoir 10 may be very small, for example so as to contain a minimum of 3 cc of ink, sufficient on average to print about 50 pages of standard A4 format.
Therefore, with the repeated replenishing system according to the invention, use of the same head or of the same cartridge may be greatly prolonged, notably reducing the printer running costs of the user.
Fig. 8 shows a printer using an ink-jet print head 75 (Fig. 9) for printing on a sheet 78 arranged vertically. The head 75 is mounted on a carriage 77 and is integral with the reservoir 76.
A bottom wall 80 of the reservoir 76 has formed in it a hole 82 for exposing a portion 83 of the sponge 85 and for accommodating an ink release element 87 intended to replenish the sponge 85 with a fresh supply of ink.
The release element 87 is similar, as regards its shape and the material form which it is made, to the elements 32 of Fig. 5 and/or 2 of Figs. 1-4.
The element 87 is supported inside a sleeve 89 integral with a main ink container 90 mounted on the frame 93 of the printer and slidable vertically on guides 92. The container 90 is situated underneath the reservoir 76 and in the region of a parked position R (Fig. 7) at one end of the travel of the carriage 77 where the print head 75 is kept immobile during a pause.
A lever 94 hinged at a point 95 of the frame 93 is rotated in a clockwise direction by the head 75 when it reaches the position R, so that an arm 94′ of the lever 94 raises the reservoir 90 so as to bring the element 87 into contact with the sponge 85.
In the non-limiting example of Fig. 8, the release element 87 consists of a material which is more rigid than the sponge 85. Therefore, the element 87 is pressed against the sponge 85 so as to create a limited compression zone 97, hence with a greater capillarity, so as to ensure the prompt and correct flow of ink between the reservoir 90 and the sponge 85.
Normally in the parked position R, a nozzle suction and protection device (not shown in the figures) is provided with an elastic cap surrounding the nozzles.
To prevent a quantity of air entering through the hole 82 (Fig. 9) as a result of the sucking action applied to the nozzles, an elastic cap 98 is preferably applied to the support 89 in order to seal the opening 82 during parking of the head.
It is understood that modifications, replacements or the addition of parts may be made to the device for replenishing a print head with ink according to the invention, without departing from the scope of the invention.

Claims

Apparatus for replenishing an ink-jet print head (61) with ink, comprising
a supply reservoir (10) connected to the print head and containing a spongy body (1) of a first porous material for supplying the ink to the print head, the spongy body having a first exposed portion (15) communicating with the surrounding atmosphere through at least one opening (30) in the supply reservoir and a second enclosed portion;

a main reservoir (48) filled with ink at atmospheric pressure up to a level; and

connecting means (2) for selectively connecting the supply reservoir to the main reservoir, the connecting means comprising a connection element (32) made of a second porous material partially immersed in the main container and designed to be brought up to the first exposed portion of the spongy body by the at least one opening; characterised in that said first exposed portion has a first capillarity and said second enclosed portion of the spongy body has a second capillarity different from said first capillarity, said first capillarity being greater than said second capillarity.
Apparatus for replenishing an ink-jet print head (61) with ink, comprising:
a supply reservoir (10) connected to the print head and containing a spongy body (1) of a first porous material for supplying the ink to the print head, the spongy body having a first exposed portion (15) communicating with the surrounding atmosphere through at least one opening (30) in the supply reservoir and a second enclosed portion;

a main reservoir (4) filled with ink at atmospheric pressure up to a level; and

connecting means (2) for selectively connecting the supply reservoir to the main reservoir the connecting means comprising a connection element (32) made of a second porous material partially immersed in the main container (4) and designed to be brought up to the first exposed portion of the spongy body by the at least one opening;
characterised in that the first porous material has a first rigidity and the second porous material has a second rigidity greater than the first rigidity, and the connection element (32) is introduced partially into the opening (30) so as to compress locally the spongy body (1), whereby the capillarity of the first exposed portion (15) is rendered greater than the capillarity of the second enclosed portion.
Apparatus for replenishing an ink-jet print head with ink according to claim 1 or 2, characterised in that the supply reservoir (10) includes an annular compression element (14), fixed in the opening (30) and projecting inside the supply reservoir so as to compress locally the spongy body (1), the annular compression element comprising a through hole (12) for exposing the first portion (15) of the spongy body and for receiving the connection element (32), whereby the capillarity of the first exposed portion is rendered greater than the capillarity of the second enclosed portion.
Apparatus for replenishing an ink-jet print head (61) with ink, comprising:
a supply reservoir (10) connected to the print head and containing a spongy body (1) of a first porous material for supplying the ink to the print head, the spongy body communicating with the surrounding atmosphere through at least one opening (30) in the supply reservoir;

a main reservoir (4) filled with ink at atmospheric pressure up to a level; and

connecting means (2) for selectively connecting the supply reservoir to the main reservoir, the connecting means comprising a connection element (32) made of a second porous material partially immersed in the main container (4) and designed to be brought up to the spongy body by the at least one opening;
characterized in that the supply reservoir (10) includes a separator element (20) located between the spongy body (1) and the opening (30), the separator element being composed of a rigid porous material having a capillarity greater than the capillarity of the first porous material of the spongy body.
Apparatus for replenishing an ink-jet print head with ink according to any of the preceding claims, characterised in that the connection element (32) comprises a plurality of capillary ducts parallel to a longitudinal axis of the connection element, each of said capillary ducts having an average diameter of between 50 and 500 µm.
Apparatus for replenishing an ink-jet print head with ink according to claim 5, characterised in that the connection element (32) has a substantially cylindrical shape, having a transverse dimension of at least an order of magnitude greater than the diameter of each of the capillary ducts.
Apparatus for replenishing an ink-jet print head with ink according to claim 1 to 4, characterised in that the second porous material of the connection element (32) consists of an expanded polymer.
Apparatus for replenishing an ink-jet print head with ink according to claim 7, characterised in that the expanded polymer is choosen in a group consisting of polyether urethan resin, melamine resin, and polyvinyl alchool.
Apparatus for replenishing an ink-jet print head with ink according to claim 1 to 4, characterised in that the second porous material of the connection element (32) consists of a fibrous material.
Apparatus for replenishing an ink-jet print head with ink according to claim 9, characterised in that the fibrous material is choosen in a group consisting of polyamide fibres, natural fibres and polyurethane-coated polyesther fibres.
Apparatus for replenishing an ink-jet print head with ink according to claim 1 to 4, characterised in that the second porous material of the connection element (32) consists of an open cell porous ceramic material.
Apparatus for replenishing an ink-jet print head with ink according to claim 2 to 11, characterised in that the connection element (32) has a substantially cylindrical shape, having a transverse dimension of at least one order of magnitude greater than the diameter of each of the capillary ducts.
Apparatus for replenishing an ink-jet print head with ink according to any of the preceding claims, characterised in that the supply reservoir (10) is removably connected to the print head so as to form a removable cartridge (55).
Method for replenishing an ink-jet print head with ink comprising the following steps:
a) providing an apparatus for replenishing an ink-jet print head with ink according to any of the preceding claims,

b) arranging the main reservoir (48) in the vicinity of the supply reservoir (10) so as the level of ink in the main reservoir forms a hydraulic head (H), with respect to said print head, having an absolute value less than the characteristic negative pressure exerted by the spongy body (1),

c) bringing a non-immersed part of the connection element (32) up to the first exposed portion of the spongy body by the at least one opening (30) in order to establish hydraulic continuity between the connection element and the spongy body, whereby the supply reservoir (10) is replenished with the ink sucked from the main reservoir as a result of capillarity.