Source: https://patents.google.com/patent/DE69915999T3/en
Timestamp: 2020-01-27 00:00:21
Document Index: 248431426

Matched Legal Cases: ['art 30', 'art 54', 'art 55', 'art 54', 'art 54', 'art 54', 'art 54', 'art 54', 'art 54', 'art 54', 'art 54', 'art 54', 'art 55', 'art 54', 'art 54', 'art 54', 'art 54', 'art 54', 'art 54', 'art 54', 'art 54', 'art 55', 'art 54', 'art 54', 'art 54', 'art 54', 'art 54', 'art 54', 'art 54', 'art 54', 'art 54', 'art 54', 'art 64', 'art 64', 'art 64', 'art 64', 'art 64', 'art 64', 'art 65', 'art 64', 'art 64', 'art 64', 'art 65', 'art 64', 'art 65', 'art 65', 'art 64', 'art 64', 'art 64', 'art 64', 'art 64', 'art 64', 'art 64', 'art 64', 'art 64', 'art 91', 'art 91', 'art 91', 'art 91', 'art 105', 'art 106', 'art 105', 'art 105', 'art 105', 'art 105', 'art 105', 'art 105', 'art 105', 'art 106', 'art 105', 'art 105', 'art 91', 'art 91', 'art 105', 'art 105']

DE69915999T3 - Ink supply unit - Google Patents
Ink supply unit
DE69915999T3
DE69915999T3 DE1999615999 DE69915999T DE69915999T3 DE 69915999 T3 DE69915999 T3 DE 69915999T3 DE 1999615999 DE1999615999 DE 1999615999 DE 69915999 T DE69915999 T DE 69915999T DE 69915999 T3 DE69915999 T3 DE 69915999T3
DE1999615999
DE69915999D1 (en
DE69915999T2 (en
1998-07-15 Priority to JP20037798 priority Critical
1998-07-15 Priority to JP20037798 priority
1998-10-06 Priority to JP28410498 priority
1999-07-15 Priority to PCT/JP1999/003839 priority patent/WO2000003877A1/en
1999-07-15 Priority to EP19990929867 priority patent/EP1016533B3/en
2005-02-10 Publication of DE69915999T2 publication Critical patent/DE69915999T2/en
2007-07-31 First worldwide family litigation filed litigation Critical https://patents.darts-ip.com/?family=26512149&utm_source=google_patent&utm_medium=platform_link&utm_campaign=public_patent_search&patent=DE69915999(T3) "Global patent litigation dataset” by Darts-ip is licensed under a Creative Commons Attribution 4.0 International License.
2011-06-09 Publication of DE69915999D1 publication Critical patent/DE69915999D1/en
2012-02-09 Publication of DE69915999T3 publication Critical patent/DE69915999T3/en
The present invention relates to an ink jet recording apparatus composed of a carriage reciprocable in the width of a recording medium, an ink jet recording head provided on the carriage, and ink supply means mounted on the carriage, to supply ink to the recording head. More particularly, the invention relates to a technique for supplying ink while maintaining a negative pressure applied to the printhead or recording head.
An ink-jet recording apparatus used for printing on a large number of pages is as shown in FIG Japanese Published Examined Patent Application No. Hei4-43785 for example, disposed such that an ink tank, for example, a cartridge mounted in the body and connected to an ink supply unit mounted on a carriage via an ink supply pipe for supplying ink to be used for printing, to a recording head via this ink supply unit.
This arrangement makes it possible to significantly eliminate a change in ink pressure, which accompanies the extension or bending of a lead during the movement of the carriage, so as to maintain the pressure.
To improve the color print quality, a recording device is available which uses different types of ink for the same color, i. H. Ink with different optical density. In such a recording device, the number of ink pipes increases as the number of different types of inks increases. Since each ink conduit must be guided to follow the movement of the carriage, a structure for wiring each conduit is complicated or limited. The elasticity and rigidity of the conduit also affects the movement of the carriage, hindering high speed printing.
To solve such a problem is, as disclosed in the Japanese Published Unexamined Patent Application No. Hei10-244685 , a recording apparatus has been proposed which includes an ink supply unit mounted on a carriage for supplying ink to an ink jet recording head, an ink cartridge mounted on the side of the body, and an ink refill unit connected by a lead and detachably engaged with the ink supply unit ,
With this arrangement, the carriage is moved during printing in a state in which the ink supply unit from the supply, such as a line, is dissolved, and the ink supply unit is connected to the supply line only when the ink supply unit is to be refilled with ink. The lead constituting the lead therefore does not need to follow the movement of the carriage and the wiring can be simplified. The carriage can be moved at high speed because the conduit is not expanded or collapsed while following the movement of the carriage, and thus high-speed printing can be realized.
Since the supply of ink from the ink cartridge mounted on the side of the body to the ink supply unit depends on a slight negative pressure generated by the expansion force of an elastic member previously mounted in the ink supply unit, the recording apparatus suffers from a problem that the negative pressure decreases, thus reducing the filled amount of the ink and consuming a prolonged period of filling with ink, since air accumulates in the ink supply unit when the filling with ink is often repeated.
To solve this problem is according to the Japanese Published Unexamined Patent Application Hei 8-174850 a recording apparatus has been proposed in which a differential pressure valve mechanism is provided between the side of the ink supply unit on which the ink storage chamber is located and the recording head, which mechanism has a diaphragm which is opened or closed depending on the differential pressure of the ink.
With this arrangement, it becomes possible to guide ink to the recording head while maintaining the negative pressure, but there is still a problem that, since the diaphragm also fluctuates, when ink fluctuates due to the movement of the carriage, the ink to be supplied to the recording head difficult to maintain the prevailing negative pressure exactly.
In addition, since the diaphragm is provided so as to extend horizontally, an increased area of the diaphragm and thus a larger installation space therefor are required to open or close valve means with a little difference in the negative pressure to be maintained in the recording head. As a result, the carriage of the recording apparatus using plural kinds of ink for printing is quite large.
EP-A-0 794 059 discloses an ink supply unit in the form of a regulator module with two separate ink collecting chambers. A diaphragm-based back pressure regulator mechanism is mounted in the regulator-side ink collection chamber. A torsion spring is provided as a biasing mechanism.
EP-A-0 760 288 also discloses a torsion spring. Forces are balanced in this spring-loaded regulator embodiment, which uses a diaphragm and said torsion spring. The torsion spring is configured to counteract the force of the diaphragm to achieve balance which provides a suitable predetermined back pressure.
An ink supply unit according to the present invention is arranged as described in claim 1.
According to this arrangement, since a differential pressure is set on a pressure receiving surface by means of the coil spring, the fluctuation of ink caused by the movement of a carriage is absorbed by the coil spring, whereby a negative pressure can be finely and suitably maintained.
Therefore, it is an object of the present invention to provide an ink supply unit capable of finely maintaining negative pressure with high precision and stably leading ink to a recording head.
1 shows an embodiment of an ink jet recording device with the outline of its ink supply mechanism.
2 Fig. 16 is a perspective view showing an embodiment of an ink supply unit according to the present invention used for this apparatus.
3 (a) and 3 (b) Fig. 12 show a state in which films for closing the surface and the rear surface are dissolved, and a state in which the films for closing are omitted, in the one embodiment of the ink supply unit.
4 is a sectional view showing the structure of the cross section along a line AA in 2 shows.
5 Fig. 15 is a perspective view showing an embodiment of a differential pressure valve mechanism incorporated in the ink supply unit.
6 (a) and 6 (b) are sectional views showing the differential pressure valve mechanism of the ink supply unit, wherein the mechanism is shown enlarged, 6 (a) shows a state in which the valve is closed, and 6 (b) shows a state in which the valve is open.
7 (a) to 7 (e) Figure 11 are sectional views showing other embodiments of the diaphragm valve constituting the differential pressure valve mechanism.
8th are sectional views showing other embodiments of the differential pressure valve mechanism, wherein the mechanism is shown enlarged, 8 (a) shows a state in which the valve is closed, 8 (b) shows a state in which the valve is open, and 8 (c) is a sectional view showing the other embodiment of the valve.
9 shows an embodiment of a method for producing the above-mentioned valve.
10 shows a relationship between a filter and a passage or channel in a case where the attachment position of the filter of the embodiment in FIG 8th is changed in a state in which the valve is open.
11 (a) and 11 (b) show respective sides of the ink supply unit to show a groove and a through hole forming the channel.
12 Fig. 10 is a sectional view showing another embodiment of the present invention.
13 is a sectional view illustrating the differential pressure valve mechanism is enlarged.
14 (a) to 14 (c) show the process of connection in a method of mounting a main tank in the ink supply unit.
15 (a) to 15 (c) show a state in which ink is replenished from the main tank in connection with the ink consumption by a recording head.
16 (a) to 16 (e) show other embodiments of the main tank.
17 to 19 show other embodiments of the main tank according to the present invention, and the 17 (a) and 17 (b) , the 18 (a) and 18 (b) and 19 (a) and 19 (b) show a state before the main tank is mounted in the ink supply unit or a state in which it is mounted.
20 explains the refilling of the ink supply unit in the in 1 and the process of restoring the ink ejection of the recording head.
1 shows an ink jet recording apparatus. A sleigh 1 is guided by means of a guide element 2 and can be reciprocated by drive means, not shown. A variety of ink supply units 3 (Four ink supply units in this embodiment) each constructed according to the present invention are at the upper part of the carriage 1 attached, and a printhead 4 is on the lower surface of the carriage 1 intended. A cartridge holder 6 for picking up an ink cartridge 5 is provided on each of the sides of a surface area where the slide 1 is moved (only one page is in 1 shown). An ink supplement unit 7 is provided above a non-printing area in the area where the carriage 1 is moved.
The ink supplement unit 7 is to the ink cartridges 5 via lines 8th connected and designed so that they have ink inlets 9 the ink supply units 3 connects to inject ink to a required height when the carriage 1 to an ink supplement area or ink refill area. A reference number 10 denotes a pump unit, ie, an ink injection pressure source connected to the ink replenishing unit 7 over a line 11 ,
2 shows an embodiment of the ink supply unit 3 , The ink supply unit 3 has the shape of a flat container, on its upper surface 21 the ink inlet 9 is formed, which communicates with an ink storage chamber, and an air opening 21 , An ink supply port 23 that with the recording head 4 is in a lower surface area on the lower surface 22 formed in this embodiment. A window is in an area of the page 24 formed of the container or container, indicative of the ink storage 36 , and is by means of a movie 31 locked. The film 31 is deformable with the pressure of the ink and consists of a laminated film in which a metallic layer having an extremely low vapor permeability and an extremely low gas permeability is laminated on a high polymer film, a high polymer film having an extremely low vapor permeability and an extremely low gas permeability, or the like ,
With reference to the 3 Now, the exact structure of the ink supply unit 3 further described. The container containing the ink supply unit 3 roughly, has a frame structure obtained by molding a plastic material, etc., and open sides of a casing 30 are each closed by means of films 31 and 32 each made of a laminated film in which a metallic layer having an extremely low vapor permeability and an extremely gas permeability is laminated on a high polymer film, a high polymer film having an extremely low vapor permeability and extremely low gas permeability, or the like.
The housing 30 is vertical by means of a wall 33 divided and sideways with a wall 34 , as in 4 shown so that narrow grooves 35 and 35 for communication with the air in the upper wall 33 are provided, and the lower part is in the ink storage chamber 36 and a valve chamber 37 divided up. A thick part 30b that extends from the side to the ground is on one side 30a the valve chamber 37 of the housing 30 formed to an ink supply channel 38 in the form of a groove defining which is an upper end 38a has that with the ink inlet 9 communicates, and a lower end 38b spaced from an ink inlet 39 the Wall 34 via a gap G. The groove is offset in the direction of the thickness of the housing 30 ,
By the lower end of the ink feed channel 38 near the ink inlet 39 Provided in this way, highly de-inked ink can be removed from the ink cartridge 5 is injected to the recording head 4 over the ink supply channel 38 flow, which is provided in the lower part, while avoiding contact with the air.
This causes ink in the printhead 4 while its degassed ratio is not lowered, as described above, the highly degassed ink can be used to clean the printhead 4 to fill and the printhead 4 to clean. Therefore, air bubbles in the printhead 4 exist, easily be dissolved in the ink and output from it.
The upper end 38a of the ink supply channel 38 is connected to the ink inlet 9 via a connection opening 9a passing through the housing 30 is formed through. The air opening 21 is connected to a connection opening 42 on the bottom surface of the wall 33 via a connection opening 21a passing through the housing 30 is formed through, the narrow grooves 35 and 35 ' on respective surfaces of the wall 33 as well as openings 40 and 41 which extend in the direction of the thickness, around these narrow grooves 35 and 35 ' to connect, and therefore are connected to the ink storage chamber 36 , That is, an air-communicating fluid channel is defined as a capillary which increases the fluid resistance as much as possible by means of the openings 40 and 41 that extend in the direction of thickness and are spaced horizontally along the wall 33 are spaced apart, and the narrow grooves 35 and 35 ' whose ends are connected by these openings and on the respective sides of the wall 33 are provided. The interior of the ink storage chamber 36 is in communication with the air through the connection opening 42 , the narrow groove 35 , the opening 41 , the narrow groove 35 ' , the opening 40 and the connection opening 21a , in that order.
The valve chamber 37 is divided into two areas in the direction of the thickness by a differential pressure valve mechanism described later 50 , A groove 43 is formed on a surface of an ink-influencing side to define a vertical ink-flow channel formed at one end thereof with the ink storage chamber 36 via an ink flow opening 39 communicates and at the other end with the differential pressure valve mechanism 50 , A groove 44 is formed in an ink outflow side to define an ink flow channel for connecting the differential pressure valve mechanism 50 with the ink supply port 23 , The front end of the groove 44 is in communication with the ink supply port 23 via a vertical passage opening 45 passing through the housing 30 is formed through.
The 5 and 6 show an embodiment of the above-mentioned differential pressure valve mechanism 50 , A recess 47 for receiving a valve assembly having an opening 46 for receiving a coil spring 51 is formed in the middle region of a side wall, which is one side of the valve chamber 37 of the housing 30 closes, and the coil spring 51 , a penholder 52 , a diaphragm valve 53 and a fastener 57 which also serves as a support element for a filter 56 are fitted therein in a laminated manner. The penholder 52 is with a spring support surface 52a provided around which guide pieces 52b with the removal-preventing claws 52d are formed. An ink flow opening 52c is through the spring bearing surface 52a formed through it.
The diaphragm valve 53 , designed as a movable valve, includes a membrane part 54 of a flexible material that is elastically deformable by receiving a differential pressure, and a thick fastened part 55 , which is the outer circumference of the membrane part 54 stores, is made of a hard material and between the case 30 and the fixing element 57 is held. It is preferred, the diaphragm valve 53 integrally by two-component molding of high polymer materials. In the middle area of the membrane part 54 is a thick closure part or sealing part 54b provided, which has an ink flow opening 54a opposite the ink flow port 52c of the spring holder 52 Has.
The fixing element 57 is with a recess 57a designed to form a filter chamber. A valve seat 57c is in the middle area of a sealing wall or closure wall 57b the recess 57a designed to be in contact with the ink flow port 54a of the diaphragm valve 53 to get to. The valve seat 57c is shaped in a spherical shape, in the direction of the diaphragm valve 53 protrude. A passage opening 57d is above the valve seat 57c provided, through which ink flows.
In this embodiment, when the carriage 1 in the position of the ink refill unit 7 is moved and the ink supply unit 3 with the ink refill unit 7 is connected, the ink inlet 9 with the ink cartridge 5 over the line 8th connected, and the air opening 21 is connected to the pump unit, which is an ink injection pressure source, via the line 11 ,
If the ink refill unit 7 is operated in this state, the pressure in the ink storage chamber 36 lowered, leaving ink in the bottom of the ink storage chamber 36 in through the ink supply channel 38 flows.
If the membrane part 54 of the diaphragm valve 53 with the spring 51 is pressed and elastic with the valve seat 57c is brought into contact, as in 6 (a) shown, in a state where the ink storage chamber 36 filled with ink in this way is the communication between the ink storage chamber 36 and the ink supply port 23 cut off.
When printing is started in this state and ink is ejected from the printhead 9 is consumed, the pressure in the groove 44 , which forms the ink channel, lowered to that of the printhead 9 to keep supplied ink at a fixed negative pressure. As ink continues to be consumed, the vacuum increases. Therefore, also increases on the membrane part 54 acting differential pressure, as in 6 (b) represented, and the membrane part 54 pulls back against the spring 51 to the ink flow opening 54a from the valve seat 57c to separate, and so to form a gap g.
This allows the ink in the ink storage chamber 36 , in the valve chamber 37 flow in through the ink flow port 54a of the membrane part 54 After passing air bubbles and dirt out of it by means of the filter 56 have been removed, and then into the ink supply port 23 to flow in, along a stream line represented by F. When differential pressure drops to a certain extent in this way, the membrane part becomes 54 of the diaphragm valve 53 back to the valve seat 57c by means of the spring 51 pressed to the ink flow opening 54a to close, as in 6a shown.
This process is repeated to supply ink to the print head while maintaining a constant negative pressure, that is, when the negative pressure of the ink supply port 23 rises, the diaphragm valve pulls 53 against the coil spring 51 back to the ink flow port 54a to open.
According to this embodiment, since the periphery of the outer periphery of the ink flow port 54a of the diaphragm valve 53 positive on the valve seat 57c by means of the coil spring 51 is pressed, the fluctuation of the diaphragm valve 53 , which accompanies the movement of the carriage prevents, and the supply pressure of ink to the print head can be stably maintained at a predetermined negative pressure compared with a conventional ink supply unit, which the differential pressure only by the elasticity of the diaphragm valve 53 established.
The 7 (a) to 7 (e) show other embodiments of the diaphragm valve described above 53 , The membrane part 54 is made of a material that can be deflected by the differential pressure of ink, for example, a soft polypropylene, so that it is provided with an annular bearing 54b in its outer circumference and the thick closure part 54b in its middle area the ink flow opening 54a Has. The fortified part 55 is made of a hard material, such as hard polypropylene, and has the shape of a ring-shaped element on the outer periphery of the bearing 54c of the membrane part 54 is careful to store this.
In 7 (a) is a narrow part 54d containing the elastically deformable region of the membrane part 54 forms, tapers to the closure part 54b relative to a position where the narrow part 54d and storage 54c are connected.
In 7 (b) is the narrow part 54d designed so that the connection of this part with the storage 54c and the middle part of the narrow part 54d are in the same plane, and the narrow part 54d is approximately in the middle of storage 54c (or the attached part 55 ) provided in the direction of the thickness. Besides, the fortified part is 55 with an annular recess 55a provided, which is to be provided in a side where the closure part 54b in contact with the valve seat 57c device and which approximates to the connection area between the narrow part 54d and storage 54c so as to extend the elastic deformation of the membrane part 54 not to interfere and to maintain the bearing force or support force.
In each of the 7 (c) to 7 (e) is an annular curved part 54e in the connection area between the narrow part 54d and storage 54c designed to limit the force of the narrow part 54d by means of storage 54c to solve and absorb a deformation caused by a shrinkage stress associated with the injection molding.
In 7 (c) has the curved part 54e a tubular shape, and the storage side of the narrow part 54d and the side of this part, where the ink flow opening 54a are moved away from each other.
In 7 (d) has the curved part 54e a U-shaped cross sectional shape, and the storage 54c and the ink flow port 54a are in the same plane.
In 7 (e) the bellows part is formed with a U-shaped cross-section so that its storage side is moved in the direction of the side where the closure part 54 (b) in contact with the valve seat device.
8th shows another embodiment of the differential pressure valve mechanism. In this embodiment, a differential pressure adjusting spring pushes 60 a membrane part 64 elastic without using a housing. That is, the membrane part 64 includes a narrow part 64a which defines a flat surface on one side leading to a valve seat 57c a fixing element 57 indicates a protruding area 64b on one side opposite the side leading to the valve seat 57c ' points to the spring 61 to be positioned, which is fitted on the outer periphery of this element, as well as an ink flow opening 64c through the middle area.
An annular bent part 64d with a U-shaped cross section is in the side of the narrow part 64a formed, where the stored area is located, and a thick storage part 64e is formed in an outer periphery of this element. A flanged fixing part 65 integral with the storage part 64e by hard material is in the outer periphery of the bearing part 64e formed. The front end side, ie the surface leading to the valve seat 57c ' indicates the storage part 64e is stored by means of the soil 65a of the fastening part 65 so that their position is regulated in the direction of the thickness.
In this embodiment, the valve seat has 57c of the fixing element 57 the shape of a protrusion defining a planar surface leading to the membrane part 64 indicates, and an outer edge 57e has, outside the outer circumference of the spring 61 is provided. The height H of the valve seat 57c ' is chosen so that it is equal to the thickness D of the soil 65a of the fixing part 65 is. This allows the surfaces leading to the fixing part 65 and the valve seat 57c ' point, to provide approximately in the same plane, making it possible, the membrane part 64 with the valve seat 57c ' to contact and disconnect it in response to a very small amount of pressure from the printhead 4 consumed amount of ink.
In this embodiment, the spring pushes 61 in a state in which ink is filled, against the membrane part 64 to the valve seat 57c ' to contact elastically over an extremely large area, as in 8 (a) shown. Therefore, the communication between the ink storage chamber 36 and the ink supply port 23 cut off. When printing is started in this state, making ink through the printhead 9 is consumed, creates a gap g between the membrane part 64 and the valve seat 54c , as in 8 (b) shown. This may cause ink in the ink storage chamber 52 into the ink supply port 23 inflow, as represented by S, so that the ink from which air bubbles and dirt have been removed by means of the filter 56 , through the ink flow opening 64c of the membrane part 64 and through an outflow opening 67 passes. In this way, when the differential pressure is slightly reduced, the membrane part 64 back to the valve seat 57c ' by means of the spring 61 pressed, and the ink flow opening 64c will be closed as in 8 (a) shown. Because the pressure of the spring 61 from the valve seat 57c ' being recorded in this condition becomes the narrow part 64a not excessively deformed, and a fluid-tight property can be maintained for a long period of time.
A soft high polymer material is likely to cause contraction, etc. subsequent to injection molding, and the narrow portion 64a may find it difficult to maintain a flat surface. To cope with this difficulty is an annular curved part 64d with an approximately S-shaped cross section on the side of the narrow part 64a formed on which the support area is located, as in 8 (c) shown to the narrow part 64a just to hold.
9 shows an embodiment of an apparatus for producing the diaphragm valve. Casting molds A and B, which define a casting cavity C, which in shape of the entire configuration of the diaphragm valve 53 corresponds, be prepared. A first injection port L1 is provided on a radially outer side with respect to an annular member K, whereas a second injection port L2 is provided on a radially inner side. A hard polypropylene injection molding machine D1 and a soft polypropylene injection molding machine D2 are connected through valves E1 and E2, respectively, whose open or closed time is controlled by a timer F.
The molds A and B are rotated around an area to be formed as the ink flow port, and the first valve E1 is opened to inject a predetermined amount of hard polypropylene. The injected hard polypropylene is uniformly distributed in the outside by the inclusion of centrifugal force and thus brought into an annular shape. After the hard polypropylene is reasonably cured, the second valve E2 is opened to inject soft polypropylene so that the soft polypropylene is shaped into the molds while being brought into close contact with the inside of the annular hard polypropylene.
In the embodiments described above, the filter is provided to be indicative of the differential pressure valve mechanism, but as in FIG 10 As shown, the same effect is obtained even if the filter is provided in a position not indicative of the differential pressure valve mechanism, for example, in a position below the differential pressure valve mechanism 50 , That is, it suffices that the ink storage chamber 36 with a surface of a filter 70 is associated and the other surface of the filter 70 in conjunction with the ink inflow port of the differential pressure valve mechanism 50 over one in a thick area of the housing 30 trained passage opening 71 is associated.
The 11 (a) and 11 (b) show the flow of the ink in the embodiment described above on the surface or the rear surface of the housing 30 , The connection will manufactured by a flow (1) from the ink storage chamber 36 to the filter 70 , a flow (2) from the passage opening 71 via a channel formed in the housing towards the inflow opening 57d the differential pressure valve mechanism 50 , a flow (3) through the membrane valve, a flow (4) through a channel which communicates the outflow openings 66 and 67 the differential pressure valve mechanism 50 connects to the ink supply port 23 , and a river (5), which is the channel 44 flows. A mark with a dot in a circle in these drawings shows the flow perpendicular to the paper surface and towards a reader, whereas a mark with an x in a circle shows the stream perpendicular to the paper surface and away from the reader.
12 shows an embodiment in which a main ink tank is directly connected to an ink supply unit.
A main tank 80 is at the bottom on one side with a connection opening 81 provided to which an ink supply unit 90 connected. The interior of the main tank 80 is divided into several chambers, for example, a first to a third ink chamber 84 . 85 and 86 , by two partitions 82 and 83 in this embodiment. The lower parts of the partitions 82 and 83 are each with connection openings 82a and 83a provided where the upper surfaces 82b and 83b are chosen so that they are lower than the upper end of the connection opening 81 , and gradually diminish, the farther they are from the connection opening 81 for the ink supply unit.
A closure valve 87 is in the connection opening 81 formed, which has a projection 87a on the outside and which is constant in the direction of the connection opening 81 by means of a spring 88 is biased, one end of which by means of the partition wall 82 is stored.
The ink supply unit 90 is formed as a container having an ink storage chamber 92 forms, which with a tubular connecting part 91 which communicates in the connection opening 81 of the main tank 80 can be used in a fluid-tight manner. The connecting part 91 located at the bottom of the ink supply unit 90 , The other surface opposite the connecting part 91 is provided with a later-described differential pressure valve mechanism 100 , The connecting part 91 is with an opening 91 provided, in which the projection 87a of the closure valve 87 can be used, and a means of a spring 93 preloaded valve 94 is inserted in it, leaving the valve 94 can be moved backwards and forwards. The feather 93 is set to be weaker than the spring 88 in the connection opening 81 ,
A connection opening 96 is in an exposed wall 95 the container is provided, which the ink storage chamber 92 defined so that the connection opening is above the surface of ink in the ink storage chamber 92 located. A groove 97 is formed on the surface side of the wall and with the connection opening 96 connected. An area where the connection opening 96 is provided is by means of a film 98a sealed, which has a repellent property and a gas permeability, to prevent ink from entering the groove 97 entry. The groove 97 is closed with an air-collecting film 98b so that they form a channel that communicates with the air.
The differential pressure valve mechanism 100 is provided on a channel containing the ink storage chamber 92 with an ink guide path 4a of the printhead 4 combines. As in 13 is a spherical convex valve seat 101 at the bottom of the wall 95 formed, and an ink flow opening 102 is provided in an area at the lower end thereof. A diaphragm valve 104 is by means of a coil spring 103 preloaded to be in contact with the center of the valve seat 101 to get to.
The designed as a movable diaphragm diaphragm valve 104 is elastically deformable by the differential pressure of ink and includes a membrane part 105 which defines a spherical surface having a larger radius than the valve seat 101 , and an annular fastened part 106 that is integral with a fastened part 105a on the outer circumference of the membrane part 105 is. A first ink chamber 107 is between the diaphragm valve 104 and the valve seat 101 Are defined.
A protruding part 105b for engagement with the coil spring 103 is on the protruding side of the middle of the membrane part 105 formed, and a closure part 105c for contact with the protruding end of the valve seat 101 is formed on the opposite rear surface. An ink inlet 105b is designed to penetrate these parts.
The diaphragm valve 104 and the spring 103 are through a valve mounting frame 109 attached, which is provided with a recess to a second ink chamber 108 define. A channel that houses the second ink chamber 108 with the ink guide path 4a of the printhead 4 is formed by a through the valve mounting frame 109 through-shaped through hole or so constructed that grooves 109c and 109d be provided on the surface and these grooves 109c and 109d closed by a film become (in this embodiment, a film 98b on the wall 95 used the ink storage chamber 92 forms). The valve mounting frame 109 Can be securely fastened by the film 98b on the wall 95 the ink storage chamber 92 is split in this way. A reference number 110 denotes a filter attached to the ink inflow port 102 is provided, and 111 denotes a packing seal.
Such a differential pressure valve mechanism 100 Can be mounted so that the spring 103 to a spring retaining projection 109a the valve mounting frame 109 adapted, the fortified part 105a of the membrane part 105 with a tapered groove 109b is aligned, the annular fastened part 106 between the outer periphery of the attached part 105a and the groove 109b is attached, and an integral unit of these elements at a recess 112 is attached.
In the embodiment thus constructed, the spring pushes 103 against the membrane part 105 making it in contact with the hemispherical valve seat 101 device as it is elastically deformed and ink becomes the printhead 4 fed during the spring 103 set differential pressure is maintained, similar to the previously described embodiments.
Now the connection of the main tank 80 with the ink supply unit 90 which are constructed as described above described.
The connection opening 81 of the main tank 80 is aligned with the connecting part 91 the ink supply unit 90 to build up a state in which airtightness by means of the packing seal 111 the connection opening 81 is maintained as in 14 (a) shown.
The further depression in this state causes the protruding area 87a the valve 94 moves backwards to a boundary point in a direction represented by an arrow A against the spring 93 of the connecting part 91 to open a channel as in 14 (b) shown.
If the main tank 80 is pushed further, pushes the valve mounted at the limit point 94 in turn, the protruding area 87a backwards in a direction shown by an arrow B against the spring 88 to the closure valve 87 from the connection opening 81 to separate so as to release the channel as in 14 (c) shown. Then there can be ink in the main tank 80 into the ink storage chamber 92 the ink supply unit 90 infuse, as in 15 (a) shown.
If ink in this state from the printhead 4 is consumed and the pressure in the chamber 108 that with the printhead 4 communicates, sinks, becomes the membrane part 105 from the valve seat 101 against the spring 103 separated. This can cause ink in the chamber 107 in the chamber 108 stream. Refilling ink lowers the negative pressure in the chamber 108 that is, the differential pressure is reduced to a pressure suitable for supplying ink to the printhead 4 so that the membrane part 105 by means of the spring 103 is pushed back. So can the valve seat 101 the ink injection port 105d close and so the negative pressure in the chamber 108 to a predetermined value.
When ink is consumed in this way and the level of ink in the first ink chamber is consumed 84 up to the top 82b of the window 82a the partition 82 diminished, ink is in the second ink chamber 85 consumed, as in 15 (b) shown. When the level of ink in the second ink chamber 85 up to the top 83b of the window 83a the partition 83 diminished, ink is in the third ink chamber 86 consumed, as in 15 (c) shown.
With this structure, the change of an ink level in the ink storage chamber 92 less suppressing than changing an ink level in the main tank 80 in connection with the ink consumption. Therefore, the variation of the pressure can be reduced. To solve a problem, the ambient temperature increases an expansion of the air in the main tank 80 causes and ejects ink and the ink level in the ink storage chamber 92 changed, the presence of the upper end 82b of the window 82a the partition 82 the volume of air in the main tank 80 reduce, which does not communicate with the ambient air, and therefore, the supply pressure of ink to the printhead can be kept stable.
In such a process, the vapor of the ink in the ink storage chamber is prevented from being vaporized 92 Evaporated in the ambient air, through the through the groove 97 and the movie 98 formed capillary. On the other hand, the amount of the increased pressure in the ink storage chamber becomes 92 , caused by the increased ambient temperature, released to the ambient air via the capillary, which is formed from the connection opening 96 in the upper part of the ink storage chamber 92 , the groove 97 and the movie 98 , so that the pressure in the ink storage chamber 92 drops.
The 16 show other embodiments of the main tank. In the embodiment described above, the main tank is in three Split ink chambers; like in the 16 (a) and 16 (b) However, the main tank can also be divided by three or seven partition walls, where the upper ends of connecting windows in the lower parts are positioned higher and higher, the closer the connection windows to the connection opening 91 are positioned. Since the volume of each ink chamber becomes smaller in this way, the dynamic pressure can be reduced by means of the ink flow of ink in connection with the change from one chamber to another chamber.
As in 16 (c) can be shown when the lower end of the partition is tilted so that the lower end is removed from the connection opening 81 is positioned, a dynamic pressure towards the side of the communication port can be reduced by the ink flow of ink in connection with the change from one ink chamber to another. As in 16 (d) In addition, the upper part of each partition is horizontally extended to form a top plate and a wall 80a towards which these upper plates are extended is at least translucent. This makes it possible to visually recognize the consumption of the ink in each ink chamber from the side. As in 16 (e) Also, approximately the same effect is achieved even if connecting windows of the same height are used.
The 17 (a) and 17 (b) show another embodiment of the present invention. In this embodiment, a hollow needle 113 that with an ink storage chamber 92 communicates at the rear surface of an ink supply unit 90 formed, whereas an ink supply 114 in an ink cartridge 80 is formed and by means of a film 115 is closed, which the hollow needle 113 can pierce. In the ink cartridge 80 is a floor area 116 with an inclined surface which is higher than the inclined surface is further spaced from the ink supply port 114 , In the ink storage chamber 92 the ink supply unit 90 is a first ink level detection electrode 118 arranged so that a common electrode 117 below the first ink level detection electrode 118 is provided, and in the ink cartridge 80 is a second ink level detection electrode 119 above the first electrode 118 and disposed at a position where the second electrode 119 is free if there is no ink in the ink cartridge 80 located. The common electrode 117 is preferably arranged so that it is below an ink inflow opening 102 located.
According to this embodiment pierces, as in 17 (b) shown when the hollow needle 113 with the ink supply port 114 the ink cartridge 80 is aligned and pushed there, the hollow needle 113 the movie 115 so the ink in the ink cartridge 80 into the ink storage chamber 92 the ink supply unit 90 can flow.
When the ink consumption progresses due to the printing process, etc., until ink in the last chamber 86 the ink cartridge is used, the second electrode is located 119 free in the air, and the lead to the electrode 117 is interrupted, which detects that the ink in the ink cartridge is consumed. When ink is consumed further in this state, the first electrode becomes 118 freed from ink, thereby detecting that the ink is in the ink storage chamber 92 is consumed.
The 18 show another embodiment of the present invention. In this embodiment, a connection channel 120 formed, which is connected to an ink storage chamber 92 and extended to a position opposite to an ink chamber of an ink cartridge 80 , At least one hollow needle, hollow needles 121 whose number is the number of chambers in the ink cartridge 80 corresponds in this embodiment, is in the upper surface of the connecting channel 120 fitted to the connection channel 120 to communicate.
The ink cartridge 80 is divided into several chambers 84 ' . 85 ' and 86 through partitions 82 ' and 83 ' and with ink supply openings 125 formed. Each ink supply port 125 has a valve 124 , the constant downward by means of a spring 123 is biased, which opposite the hollow needle 121 is positioned in the case where the ink cartridge 80 on a bracket 122 is appropriate. The ink supply openings 125 are by means of a movie 126 locked.
According to this embodiment pierces when the ink cartridge 80 in the holder 122 inserted and pushed down, the front end of the hollow needle 121 the movie 126 and pushes the valve 124 up to open a channel. This allows ink in each chamber of the ink cartridge 80 then into the ink storage chamber 92 over the connection channel 120 stream. If the ink cartridge 80 from the holder 122 is solved, is the valve 124 not by the hollow needle 121 stored, and it's like in 18 (b) shown, elastic on the ink supply port 125 by means of the spring 123 pressed so as to prevent ink from the ink supply port 125 flows out.
In the embodiment described above, the ink supply port is by means of the valve 124 locked; like in the 19 but can also be an elastic plate 127 , as For example, a rubber plate, with a through hole 127a which is opposite the front end of the hollow needle 121 be provided, wherein the opening by means of the film 126 is closed. This leads to a similar effect.
If the ink cartridge 80 with the bracket 122 aligned and pressed into the holder pierces the hollow needle 121 the movie 126 and then pushes into the through hole 127a the elastic plate 127 into and expand this to build the connection. In this state, as the outer circumference of the hollow needle 121 through the elastic plate 127 is closed, the leakage of ink, the evaporation of ink solvent, and also prevents the influx of air. In this embodiment, it is preferred that the hollow needle 121 an area 121 with small diameter on the front side and has an area 121b large diameter with a tapered front end on the area that the elastic plate 127 contacted.
If the ink cartridge 80 from the holder 122 is solved, the hollow needle 121 from the elastic plate 127 withdrawn. Therefore, the through hole becomes 127a contracted to hold ink with a capillary force so as to prevent the outflow of ink to the outside.
With reference to the 20 Now, an operation for supplying ink to the ink supply unit will be made 3 over the line 8th from the ink cartridge 5 that in a body like in 1 is shown installed described.
When the sled 1 in a position of the ink refill unit 7 is moved and the ink refill unit with the ink supply unit 3 is connected, the ink inlet 9 the ink supply unit 3 in conjunction with the ink cartridge 5 through a pipe 8th extending from the ink refill unit 7 and the line 8th via a coupling 130 extends, and the open air opening 21 is with the pump unit 10 via lines 11 connected to the ink refill unit 7 and the tube 11 extend, via a coupling 131 ,
When the pump unit 10 the ink refill unit 7 operated in this state, the pressure in the ink storage chamber decreases 36 off, ink in the ink cartridge 5 becomes the ink inlet 9 over the wires 8th and 8th' pulled and over the coupling 130 , and flows into the ink storage chamber 36 through the ink supply channel 38 ,
Since the lower end 38b of the ink supply channel 38 at the bottom of the ink storage chamber 36 is located and a gap G between the lower end 38b and the ink inflow port 39 the valve neck 37 exists, air bubbles that flow along with the ink increase by buoyancy in the gap G, through the wall 34 interrupted the valve chamber 37 defined, and move to the upper part of the ink storage chamber 36 without entering the valve chamber 37 einzufließen.
As described above, since negative pressure on the ink storage chamber 36 is applied and ink in the ink cartridge 5 sucked, ink in the ink storage chamber 36 be injected without air bubbles in the valve chamber 37 enter.
After the ink storage chamber 36 has been replenished with a predetermined amount of ink, the ink inlet 9 closed, and then the pump unit 10 the ink refill unit 7 operated to reduce the pressure of the ink in the ink storage chamber 36 so that ink in the ink storage chamber can be fully degassed. Of course, there is pressure in the ink storage chamber 36 decreases and the differential pressure valve mechanism 50 that is between the ink storage chamber 36 and the printhead 4 is connected, serves as a check valve, no air on the printhead 4 , and no unnecessarily high suction force acts on the printhead.
When a printing error occurs due to, for example, clogging of the printhead 4 during, for example, a printing operation, the printhead becomes 4 through a cap 132 closed, and a suction pump 133 is operated, so that a so-called ejection recovery is performed.
When vacuum through the lid 132 is applied, the negative pressure acts on the differential pressure valve mechanism 50 from the groove 44 which forms an ink channel, via the ink guide path 4a , Because the differential pressure valve mechanism 50 open when printing on the side of the printhead 4 decreases as described above, ink is in the valve chamber 37 by means of the filter 56 filtered (see 5 ), passes through the differential pressure regulating mechanism 50 through and flows into the printhead 4 one.
This ejection recovery process occurs when the ink cartridge 5 with the ink supply unit 3 over the coupling 130 is connected and the ejection recovery is performed, the open air opening 21 is sealed, strongly degassed ink quickly from the ink cartridge to the ink flow port 39 in the lower part of the wall 34 that the valve chamber 37 defines, allowing the ink into the valve chamber 37 flows in without reducing the degassing rate. Even if air bubbles are generated when the ink cartridge 5 and the ink supply unit 3 connected, these air bubbles never enter the valve chamber 37 a, as described above.
When the ink inlet 9 and the air opening 21 kept closed, also takes the pressure in the ink storage chamber 36 so that air dissolved in the ink is discharged therefrom toward the upper space in the ink storage chamber 36 , As a result, the degassing rate of the ink can be restored.
The ink supply unit according to the present invention has a differential pressure valve with a coil spring and a movable diaphragm, which can elastically contact a valve seat with the coil spring. Since the pressure of ink supplied to an ink-jet head is kept negative by the coil spring, the fluctuation of the movable diaphragm in connection with the movement of a carriage by means of the coil spring can be suppressed. Therefore, ink can be stably supplied to the printhead while maintaining a proper negative pressure.
Ink supply unit ( 3 . 90 ), in which: a differential pressure valve with a coil spring ( 51 . 103 ) and a movable membrane ( 53 ), which is designed by means of the coil spring ( 51 . 103 ) a valve seat ( 57c ) is elastically contacted, housed in a container having an ink storage chamber ( 36 . 92 ) connected to an ink jet recording head ( 4 ) connectable ink feed opening ( 23 ) communicates with the movable membrane ( 53 ) between the valve seat ( 57c ) and the coil spring ( 51 . 103 ), the movable membrane ( 53 ) is arranged vertically when the ink supply unit ( 3 . 90 ) on a carriage ( 1 ) and the movable membrane ( 53 ) is arranged parallel to a plane which is perpendicular to a direction in which the carriage ( 1 ) is moved.
Ink supply unit ( 3 . 90 ) according to claim 1, wherein: the differential pressure valve is a disk-like elastic membrane element ( 54 ), which in its center with an ink flow opening ( 54a ), a valve seat provided on an upstream side of the ink flow ( 57c ) leading to the ink flow port ( 54a ), and a coil spring provided downstream ( 51 ), which the ink flow opening ( 54a ) of the elastic membrane element ( 54 ) against the valve seat ( 57c ) presses.
Ink supply unit ( 3 . 90 ) according to claim 1, in which: the movable membrane ( 53 ) the pressure of the coil spring ( 51 . 103 ) via a holder ( 52 ).
Ink supply unit ( 3 . 90 ) according to one of claims 1 to 3, wherein: the housing ( 30 ) includes a frame-like housing, in whose side surface a window is provided, wherein an air-interrupting film ( 31 ) closes this window.
Ink supply unit ( 3 . 90 ) according to claim 1, wherein: the ink storage chamber ( 36 ) communicates with the ambient air via a capillary formed in the container.
Ink supply unit ( 3 . 90 ) according to claim 5, in which: the capillary has a groove ( 97 ) on an upper wall of the ink storage chamber ( 36 . 92 ) and an air-interrupting film ( 98 ) the groove ( 97 ) closes.
Ink supply unit ( 3 . 90 ) according to claim 5, in which: the capillary has a groove ( 97 ) on a side wall of the ink storage chamber ( 36 . 92 ) and an air-interrupting film ( 98 ) the groove ( 97 ) closes.
Ink supply unit ( 3 . 90 ) according to claim 1, in which: the movable membrane ( 53 ) a movable part ( 54 . 105 ) of a soft material and a fastening part ( 55 . 106 ), which is made of hard material and on an outer periphery of the movable part ( 54 . 105 ) is attached.
Ink supply unit ( 3 . 90 ) according to claim 8, in which: a holding part in an outer periphery of the movable part ( 54 ) is trained; and the moving part ( 54 . 105 ) with the fastening part ( 55 . 106 ) is connected via the holding part.
Ink supply unit ( 3 . 90 ) according to claim 1, in which: a movable part ( 54 ) on the movable membrane ( 53 ) is provided; and a holding part in an outer periphery of the movable part (FIG. 54 . 105 ) is trained.
Ink supply unit ( 3 . 90 ) according to claim 1, 8 or 10, wherein: the movable membrane ( 53 ) with a movable part ( 54 . 105 ) is provided; and an annular bent part near an outer periphery of the movable part (FIG. 54 . 105 ) is trained.
Ink supply unit ( 3 . 90 ) according to claim 10, in which: the movable part ( 54 . 105 ) is in the direction of the thickness approximately in the middle of the holding part.
Ink supply unit ( 3 . 90 ) according to claim 8 or 10, in which: a middle region of the movable part ( 54 . 105 ) is offset with respect to an outer peripheral portion of the movable member.
Ink supply unit ( 3 . 90 ) according to claim 8, in which: the fastening part ( 55 . 106 ) on its side towards the valve seat ( 57c ) is formed with a flange part; and a position of the movable part ( 54 . 105 ) is regulated in the direction of its thickness by means of the flange part.
Ink supply unit ( 3 . 90 ) according to claim 1, wherein: a filter ( 70 ) is disposed in an upstream side with respect to the differential pressure valve.
Ink supply unit ( 3 . 90 ) according to claim 1, wherein: the coil spring ( 51 . 103 ) in contact with the movable membrane ( 54 . 105 ) via a holder ( 52 ) having an ink flow port provided so as to become an ink flow port (US Pat. 54a ) of the movable membrane ( 54 . 105 ) points.
Ink supply unit ( 3 . 90 ) according to claim 1, wherein: the valve seat ( 57c ) is formed as a spherical surface, which in the direction of the movable membrane ( 54 . 105 protruding).
Ink supply unit ( 3 . 90 ) according to claim 1, in which: a protruding part on a surface of the valve seat ( 57c ) is formed, where it is in contact with the movable membrane.
Ink supply unit ( 3 . 90 ) according to one of claims 1 to 18, wherein: the valve seat ( 57c ) as a protruding part with a flat surface on one side in the direction of the movable valve ( 54 . 105 ) is trained.
Ink supply unit ( 3 . 90 ) according to claim 1, wherein: the movable valve ( 54 . 105 ) comprises a disc-like movable member made of a soft high-polymer material provided with a thick portion at its outer periphery, and an annular support member made of a high-polymer hard material provided with a flange portion on its side facing the valve seat; and the valve seat ( 57c ) is formed as a protruding part defining a flat surface on one side of the movable valve and having a thickness approximately equal to that of the flange part.
Ink supply unit ( 3 . 90 ) according to claim 20, wherein: the flat surface of the protruding part and the flange part are in the same plane.
Ink supply unit ( 3 . 90 ) according to one of claims 1 to 21, in which: the differential pressure valve is a disk-like movable membrane ( 54 . 105 ), in the middle of which an ink flow opening is formed, a coil spring ( 51 . 103 ) in contact with the movable membrane ( 54 . 105 ) and a valve seat ( 57c ) which is formed as a protruding part defining a flat surface on one side of the movable diaphragm and having an outer edge which is outside an outer periphery of the coil spring ( 51 . 103 ) is provided.
Ink supply unit ( 3 . 90 ) according to claim 22, in which: the movable membrane ( 54 . 105 ) is formed on its side facing the valve seat with a flat surface and on its opposite surface with a protruding part, which the coil spring ( 51 . 103 ) stores.
Ink supply unit ( 3 . 90 ) according to claim 1, wherein: an ink injection port is provided on an upper surface of the container and is connected to a bottom portion of the ink storage chamber via one of the ink storage chamber (14). 36 . 92 ) isolated passage communicates.
Ink supply unit ( 3 . 90 ) according to claim 1, wherein: an ink injection port is provided on an upper surface of the container and is provided with a bottom portion of the ink storage chamber (10). 36 . 92 ) communicates in the vicinity of an upstream side of the differential pressure valve via a passage isolated from the ink storage chamber.
Ink supply unit ( 3 . 90 ) according to claim 1, wherein: the ink reservoir and an area where the differential pressure valve is accommodated by means of a Wall ( 33 ) are separated in their bottom part with a connection opening ( 21a ) is provided; several electrodes ( 117 . 118 . 119 ) for detecting an ink level in the ink storage chamber ( 36 . 92 ) are provided; and at least one of the electrodes ( 117 . 118 . 119 ) above the connection opening ( 21a ) is provided.
Ink supply unit ( 3 . 90 ) according to claim 1, wherein: the differential pressure valve is a spherical movable diaphragm ( 54 . 105 ), which in its center with an ink flow opening ( 54a ), a coil spring ( 51 . 103 ) in contact with the movable membrane ( 54 . 105 ) and a valve seat ( 57c ), which has a spherical part which faces in the direction of the movable membrane ( 54 . 105 protruding).
Ink supply unit ( 3 . 90 ) according to claim 27, in which: the valve seat ( 57c ) is formed on a wall which forms the ink storage chamber.
Ink supply unit ( 3 . 90 ) according to claim 27, in which: the movable membrane ( 54 . 105 ) and the coil spring ( 51 . 103 ) are attached by means of a valve mounting frame to a wall which forms the ink storage chamber.
Ink supply unit ( 3 . 90 ) according to claim 29, in which: the valve fixing frame is provided with a passage which is connected to a recording head ( 4 ) communicates.
Ink supply unit ( 3 . 90 ) according to claim 30, wherein: the passageway is a groove ( 97 ) in the valve mounting frame and an air-interrupting film ( 98 ) closes the groove.
Ink supply unit ( 3 . 90 ) according to claim 5, wherein: a film member having both gas permeating and repelling properties is interposed between said capillary and said ink storage chamber (12). 36 . 92 ) is provided.
Ink supply unit ( 3 . 90 ) according to claim 1, wherein: means ( 118 . 119 ) are provided for detecting the ink level on an upstream side with respect to the differential pressure valve.
Ink supply unit ( 3 . 90 ) according to claim 15, wherein: means ( 118 . 119 ) for detecting the ink level on an upstream side with respect to the filter ( 70 ) are provided.
Ink supply unit ( 3 . 90 ) according to claim 15, wherein: means ( 118 . 119 ) are provided for detecting the ink level so that the filter ( 70 ) is not exposed when the end of the ink is detected.
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DE69915999T2 DE69915999T2 (en) 2005-02-10
DE69915999D1 DE69915999D1 (en) 2011-06-09
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1999-07-15 EP EP20040001663 patent/EP1440808B2/en not_active Expired - Lifetime
1999-07-15 ES ES04001663T patent/ES2301888T5/en not_active Expired - Lifetime
1999-07-15 ES ES07005031T patent/ES2330682T3/en not_active Expired - Lifetime
1999-07-15 DE DE1999224902 patent/DE29924902U1/en not_active Expired - Lifetime
1999-07-15 AT AT07024971T patent/AT496775T/en not_active IP Right Cessation
1999-07-15 DE DE1999641375 patent/DE69941375D1/en not_active Expired - Lifetime
1999-07-15 ES ES07024971T patent/ES2358054T3/en not_active Expired - Lifetime
1999-07-15 DE DE1999643417 patent/DE69943417D1/en not_active Expired - Lifetime
1999-07-15 JP JP2000560002A patent/JP3874067B2/en not_active Expired - Lifetime
1999-07-15 AT AT09165877T patent/AT507976T/en not_active IP Right Cessation
1999-07-15 AT AT99929867T patent/AT263028T/en not_active IP Right Cessation
1999-07-15 WO PCT/JP1999/003839 patent/WO2000003877A1/en active IP Right Grant
1999-07-15 DE DE1999638202 patent/DE69938202T3/en not_active Expired - Lifetime
1999-07-15 EP EP20070024971 patent/EP1914080B1/en not_active Expired - Lifetime
1999-07-15 ES ES99929867T patent/ES2219029T7/en active Active
1999-07-15 DE DE1999615999 patent/DE69915999T3/en not_active Expired - Lifetime
1999-07-15 DE DE1999630171 patent/DE69930171T2/en not_active Expired - Lifetime
1999-07-15 AT AT07005031T patent/AT441530T/en not_active IP Right Cessation
1999-07-15 ES ES09165877T patent/ES2362979T3/en not_active Expired - Lifetime
1999-07-15 DE DE1999643172 patent/DE69943172D1/en not_active Expired - Lifetime
1999-07-15 ES ES03012124T patent/ES2260546T3/en not_active Expired - Lifetime
1999-07-15 AT AT04001663T patent/AT386640T/en not_active IP Right Cessation
2000-03-15 US US09/525,477 patent/US7090341B1/en not_active Expired - Lifetime
2000-12-28 HK HK04101462A patent/HK1059918A1/en not_active IP Right Cessation
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2003-06-02 JP JP2003156123A patent/JP2003312016A/en not_active Withdrawn
2004-04-06 US US10/819,756 patent/US7350907B2/en active Active
2005-12-23 US US11/317,928 patent/US7422317B2/en active Active
2006-06-23 US US11/426,194 patent/US7559634B2/en active Active
2008-02-26 US US12/037,618 patent/US8136931B2/en active Active
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JP2008247043A (en) 2008-10-16
EP1440808B1 (en) 2008-02-20
AU724586B2 (en) 2000-09-28 Liquid supply method, system, ink container, cartridge and replenishing container and head cartridge usable with system