COVER FOR INK TANK WITH MIXING FUNCTION

专利摘要:
The invention relates to a tank cover for a continuous ink jet printer, comprising a so-called upper surface (331), a so-called lower surface (332), between which are included an upper part (33a) and a lower part ( 33b) of the lid, at least the latter being delimited laterally by a peripheral surface (Se), and: - at least a first duct (331), which passes through at least part of the lid, to bring a first fluid from said upper part toward said lower portion and directing it, at least partially, laterally toward said peripheral surface (Se); at least one first chamber (333) delimited by an inner surface in which said duct opens and by said peripheral surface (Se), and means (338) for flowing a liquid contained in this chamber in a direction parallel to said peripheral surface; .
公开号:FR3039457A1
申请号:FR1557326
申请日:2015-07-30
公开日:2017-02-03
发明作者:Francis Pourtier；Jean-Pierre Arpin；Thomas Marzano
申请人:Dover Europe SARL；
IPC主号:

专利说明:

COVER FOR INK TANK WITH MIXING FUNCTION
DESCRIPTION
TECHNICAL FIELD AND PRIOR ART The invention relates to the field of continuous inkjet (CIJ) printers.
It also relates to the architecture (arrangement of the ink circuit) of the CIJ printers, in particular in order to guarantee the homogeneity of the ink.
Continuous inkjet (CIJ) printers are well known in the field of coding and industrial marking of various products, for example to mark barcodes, the expiry date on food products, or references or distance marks on the cables or pipes directly on the production line and at high speed. This type of printer is also found in some areas of decoration where the graphic printing capabilities of the technology are exploited.
These printers have several typical subsets as shown in Figure 1.
Firstly, a print head 1, generally offset from the body of the printer 3, is connected thereto by a flexible umbilical 119 gathering the hydraulic and electrical connections necessary for the operation of the head by giving it flexibility that facilitates integration on the production line.
The body of the printer 3 (also called desk or cabinet) usually contains three subsets: - an ink circuit in the lower part of the desk (zone 4 '), which allows on the one hand, to provide ink to the head at a stable pressure and of adequate quality, and secondly to support ink jets not used for printing, - a controller located at the top of the desk (zone 5 ' ), able to manage the sequencing of actions and to carry out the treatments allowing the activation of the various functions of the ink circuit and the head. an interface 6 which gives the operator the means to implement the printer and to be informed of its operation.
In other words, the cabinet has 2 sub-assemblies: in the upper part, the electronics, the power supply and the operator interface, and in the lower part an ink circuit supplying the ink, of nominal quality, under pressure at head and vacuum recovery of ink not used by the head.
Figure 2 schematically shows a print head 1 of an ICJ printer. It comprises a drop generator 60 supplied with electrically conductive ink pressurized by the ink circuit 4.
This generator is capable of emitting at least one continuous jet through a small orifice called a nozzle. The jet is transformed into a regular succession of drops of identical size under the action of a periodic stimulation system (not shown) located upstream of the outlet of the nozzle. When the drops 7 are not intended for printing, they go to a gutter 62 which recovers them in order to recycle the unused ink and send them back into the ink circuit 4.
Devices 61 placed along the jet (charge and deflection electrodes) make it possible, on command, to electrically charge the drops and to deflect them in an electric field Ed. These are then deviated from their natural trajectory of ejection of the generator of drops. The drops 9 intended for printing escape the gutter and will be deposited on the print medium 8.
This description can be applied to so-called continuous jet (CIJ) printers or multi-deflected continuous jet. The binary CIJ printers are equipped with a head whose drop generator has a multitude of jets, each drop of a jet can be oriented only to 2 paths: printing or recovery. In multi-deflected continuous jet printers, each drop of a single jet (or a few spaced jets) can be deflected on different paths corresponding to different charge commands from one drop to another, thus performing a scan of the area to be printed in a direction which is the direction of deflection, the other scanning direction of the area to be printed is covered by relative displacement of the print head and the print medium 8. Generally the elements are arranged in such a way that that these two directions are substantially perpendicular.
An ink circuit of a continuous inkjet printer first makes it possible to supply ink under controlled pressure, and possibly solvent, to the drop generator of the head 1 and to create a depression to recover the unused fluids for back printing of the head.
It also allows the management of consumables (dispensing of ink and solvent from a reserve) and the control and maintenance of ink quality (viscosity / concentration).
Finally, other functions are related to the comfort of the user and the automatic support of certain maintenance operations to ensure the same operation regardless of the conditions of use. These functions include solvent rinsing of the head (drop generator, nozzle, gutter), assistance with preventive maintenance such as the replacement of components with limited lifespan (filters, pumps).
These different functions have very different purposes and technical requirements. They are activated and sequenced by the controller of the printer which will be all the more complex as the number and sophistication of the functions will be great.
Inks containing pigments such as titanium oxide (TiC> 2 rutile or anatase) in the form of sub-micron sized particles are particularly interesting for their whiteness and opacity. They are used for marking and identifying black or dark media. The dense pigment particles have a natural tendency to sediment when the ink is at rest. The consequences of this inevitable sedimentation may be duct plugging and the loss of opacity of the markings. The ink circuit must be able to somehow stir the ink to maintain the homogeneity of the ink, or even restore it after a rest more or less long. Moreover, the viscosity, during use of a printer, will change from one value to another. In other words, the viscosity will not be a stable parameter during the operation of the printer. This variation in viscosity is mainly due to three factors: the evaporation of the solvent, the addition of solvent to the ink tank, which results from the cleaning operations of all or part of the fluidic circuit; these operations are carried out using solvent, which is, as a result of such operations, sent to the main tank; - temperature variations.
The quality (measured by the viscosity) of the ink is thus maintained by adding solvent in the ink. There then arises the problem of optimum mixing of the ink and the added solvent.
Another difficulty related to the quality of the ink is the presence of foam in the ink tank in which the unprinted ink returns and recovered by the gutter of the print head. This foam is created by the inevitable aspiration of air with the ink recovered by the gutter. Water-based inks are especially more foaming than solvent-based inks. This air is evacuated by a vent. Preferably, the ink circuit enables the defoaming of the ink sufficiently rapidly so as not to create an overflow of ink through the vent. There is also the problem of recycling air mixed with ink to the head.
In the specific field of inkjet printers, solutions have been proposed to satisfy the requirements related to the presence of dense pigments in the inks and / or to recover the unprinted ink via the gutter of the print head. and / or for mixing solvent added to the ink, whether it is solvent added to compensate for solvent variation or for cleaning operations.
A first solution is shown in FIG. 3A, where the reference 11 designates a reservoir which contains ink 13, which can be withdrawn via a conduit 111 placed at the bottom of the reservoir, with a view to sending it to the print head 1 .
According to this solution, a liquid (solvent and / or ink) which is supplied to the circuit is introduced inside the volume of ink 13 already present in the reservoir, under the free surface of this ink 13. L ink that is supplied may be ink that comes from an outer cartridge, or ink that comes back from the print head. The solvent that is provided can be a solvent that comes from an outer cartridge. But this solution causes significant pressure variations at the outlet of the conduit 111, due to variations in viscosity during the introduction of the solvent.
A second solution is shown in FIG. 3B where references identical to those of FIG. 3A designate the same elements.
According to this solution, a liquid (solvent and / or ink) which is supplied to the circuit is introduced above the volume of ink 13 already present in the reservoir, above the free surface of this ink 13 Again, the ink that is supplied may be ink that comes from an outer cartridge, or ink that comes back from the print head. The solvent that is provided can be a solvent that comes from an outer cartridge. But this solution causes the formation of two phases, the ink 13 on the one hand and, on the other hand, a phase 13ien surface of the ink. This phase 13is essentially consists of solvent, which does not mix well with the ink.
A third solution is shown in FIG. 3C where references identical to those of FIGS. 3A and 3B designate the same elements.
According to this solution, ink E and solvent S and are mixed by means 112 (for example a "T") before being injected into the tank 11. The solvent can have the same origin as mentioned above . But this solution disrupts the hydraulic line on which the means 112 are located.
There is therefore the problem of finding a new device and a new method for injecting ink and / or solvent into an ink tank e of an ICJ type printer. In general, the ink circuit of known ink jet printers capable of projecting dense pigment inks remains an expensive element, because of the many hydraulic components to implement.
There is therefore the problem of performing all or part of the functions of an ink circuit, in a CIJ-type printer, at a lower cost and with a reduced number of components, while guaranteeing a minimum of reliability, or, in In any case, a reliability expected by users, particularly related to the homogeneity of pigment inks throughout the consumption. We therefore seek to implement the simplest possible components, especially for functions such as the control and maintenance of the quality of the ink. The latter can be defined in terms of viscosity and / or concentration of the ink.
In particular, a problem is to reduce, or limit, the variation in opacity of the ink as a function of the ink consumption. The opacity of the markings is mainly (but not only) related to the pigment concentration. If some of the pigments sediment at the bottom of the tank, the pigment concentration in the liquid ink will be decreased, and the opacity will decrease.
Another problem is to reduce, or limit as much as possible, after a shutdown, which can be long, of the machine, the time necessary for the homogenization of the ink, before the restart of the printing.
In another aspect, the ink circuit comprises a large number of hydraulic, hydroelectric, sensor, etc. components. Indeed, modern printers have many sophisticated and precise functions. The hydraulic components (pumps, solenoid valves, self-sealing connections, filters, various sensors) are present or are sized to meet a level of quality, reliability, performance and service to the user. And the maintenance functions consume components because they are often automated.
There is therefore also a need for an ink circuit architecture that minimizes the number of components while ensuring a good level of performance and reliability as well as an easy maintenance allowing rapid interventions, minimizing the risk of contamination and feasible by operators without special training.
SUMMARY OF THE INVENTION The invention firstly relates to a tank cover for a continuous inkjet printer, comprising a so-called upper surface, a so-called lower surface, between which are included an upper part and a lower part of the lid. , at least the latter being delimited laterally by a peripheral surface (Se), and: at least one first duct, which passes through at least a portion of the lid, to bring a first fluid from said upper part to said lower part and to direct it at least partly laterally towards said peripheral surface (Se); at least one chamber delimited by an inner surface into which said duct opens and by said peripheral surface (Se), and means (338, 438) for flowing a liquid contained in this chamber in a direction parallel to said peripheral surface. The invention therefore makes it possible to integrate a function for recovering a fluid, for example ink coming from a print head, in a lid of a tank. The structure of this lid makes it possible, when installed on a tank, to use the inner wall of the tank to guide the fluid introduced into the tank towards the reserve of fluid already contained in the tank.
An inner surface of the first chamber faces, at least in part, the peripheral surface Se.
End faces, or front faces, of said inner surface may be aligned with, or positioned in, the peripheral surface Se.
The inner surface of the chamber may have one or more walls.
The chamber can be opened on the peripheral surface Se, the inner wall of the tank closing it laterally when the lid closes the tank. The inner wall of the tank nevertheless leaves the means free to flow a liquid contained in the chamber in a direction parallel to the peripheral surface.
Alternatively, the chamber has a wall that can be integrally formed with the rest of the chamber and that comes, itself, bear against the inner wall of the tank. The latter nevertheless leaves the means free to flow a liquid contained in the chamber in a direction parallel to the peripheral surface. This wall advantageously has a curvature which corresponds to the inner surface of the reservoir. This wall is almost confused with the surface Se.
According to a particular embodiment, the upper surface and the lower surface of the cover may be at least partly parallel to each other and to a plane (XY). Alternatively they may be at least partly curved or have a curvature.
The first conduit can pass through at least a portion of the cover in at least one direction parallel to the peripheral surface (Se), or perpendicular to the plane (XY).
The first conduit can pass through the lid, from the top surface to the bottom surface.
The first conduit may open into the inner surface of the chamber, for example in a wall of the chamber, for example by at least one orifice made in said surface or said wall. Preferably, said surface or said wall faces at least in part to said peripheral surface Se.
The peripheral surface is straight, it makes it possible to define an extension direction, or an axis, Z. In the following, various indications, including angles, are reported to this peripheral surface (or to a plane tangent thereto). . But we can also relate them to the Z axis or to the XY plane, which is perpendicular to it.
Preferably, at least a portion of the duct is directed towards said peripheral surface (Se) in a direction forming, with this surface, an angle of between 30 ° and 60 °.
Whatever the embodiment envisaged, the peripheral surface (Se) may be cylindrical.
According to one embodiment, the lower part of the lid comprises at least one peripheral portion which projects from said lower surface, at least a portion of said first chamber being made in said peripheral part.
In addition means may be provided to receive at least one measuring rod.
A lid according to the invention may further comprise fluidic connection means, on the upper surface, for bringing at least the first fluid to an inlet of the first conduit.
Preferably, these fluidic connection means comprise an inlet for bringing the first fluid in a direction perpendicular to the peripheral surface (Se) or, where appropriate, parallel to the plane (XY).
A lid according to the invention may further comprise lateral means, for example a groove for receiving a seal, for sealing with the wall of a tank, these lateral means being arranged between said first chamber and the upper surface.
At least one additional duct may advantageously pass through the upper part of the lid and open into a cavity delimited by the lower part. Such a conduit allows a setting atmospheric pressure of the atmosphere present above an ink contained in a tank on which I cover is positioned. In general, the first conduit can lead alone in said one chamber.
According to a variant, a lid according to the invention comprises at least a second duct, which passes through at least a part of the lid, to bring a second fluid from said upper part to said lower part and to direct it at least partially, laterally, towards said peripheral surface (Se), this second duct opening into the first chamber. The first duct and the second duct are, advantageously, at least partly parallel to each other.
According to this variant, the first chamber to accommodate 2 fluids, which will be able to mix, then the mixture can be directed to the reserve of fluid already contained in the reservoir. The two fluids can be, on the one hand, ink that comes from a circulation from the reservoir itself, and, on the other hand, ink that comes from an external supply, for example an ink cartridge or solvent that comes from an external power supply, for example a solvent cartridge or an intermediate solvent reservoir.
The second duct may pass through at least part of the lid in at least one direction parallel to the peripheral surface (Se), or perpendicular to the plane (XY).
The second conduit can pass through the lid, from the upper surface to the lower surface.
The second conduit may open into the inner surface of the chamber, for example in a wall of the chamber, for example by at least one orifice made in said surface or said wall. Preferably, said surface or said wall faces at least in part to said peripheral surface Se.
When the first conduit, respectively the second conduit, opens into the first chamber through a first orifice, respectively a second orifice, the sum of the section of the first orifice and the second orifice, through which the first fluid and the second fluid, is preferably, less than or equal to the section of the means for discharging the liquid from the chamber.
The lid may further comprise: at least one third duct, which passes through at least a portion of the lid, for supplying a fluid, in particular a liquid, from said upper part to said lower part and directing it, at least in part, laterally to said peripheral surface (Se); - At least a second chamber defined by an inner surface into which said third conduit and said peripheral surface (Se), and means for flowing the fluid from the second chamber in a direction parallel to said peripheral surface.
In this variant, the lid comprises, on the one hand, a chamber in which a mixture can be produced, and, on the other hand, a chamber which makes it possible to collect another fluid, for example ink coming from a print head of a printer.
The two fluids to form the mixture may be, on the one hand, ink that comes from a circulation from the reservoir itself, and, on the other hand, ink that comes from a food external, for example an ink cartridge, or solvent that comes from an external power supply, for example a solvent cartridge or an intermediate tank of solvent.
The third duct may open alone in said chamber.
An inner surface of the second chamber faces, at least in part, the peripheral surface Se.
End faces, or front faces, of the inner surface of the second chamber, may be aligned with, or positioned within, the peripheral surface Se.
The inner surface of the second chamber may have one or more walls.
The second chamber can be opened on the peripheral surface Se, the inner wall of the tank closing it laterally when the lid closes the tank. The inner wall of the tank nevertheless leaves the means free to flow a liquid contained in the chamber in a direction parallel to the peripheral surface.
Alternatively, the second chamber has a wall which can be integrally formed with the rest of the chamber and which itself comes to bear against the inner wall of the tank. The latter nevertheless leaves the means free to flow a liquid contained in the second chamber in a direction parallel to the peripheral surface. This wall advantageously has a curvature which corresponds to the inner surface of the reservoir. This wall is almost confused with the surface Se.
The third duct may pass through at least part of the lid in at least one direction parallel to the peripheral surface (Se), or perpendicular to the plane (XY).
The third duct can pass through the lid, from the upper surface to the lower surface.
The third conduit may open into the inner surface of the second chamber, for example in a wall of the chamber, for example by at least one orifice made in said surface or said wall. Preferably, said surface or said wall faces at least in part to said peripheral surface Se. Regardless of the number of chambers and, in each chamber, the number of ducts, one and / or the other of the ducts, or each duct, allows, preferably, to bring each fluid at least into part under a level defined by the lower surface of the lid and / or under the lateral or peripheral sealing means, when these are present. The invention also relates to a tank comprising a body and a lid as described in the present application, at least the first chamber being closed, laterally, by the inner wall of the tank body.
Such a reservoir may further comprise means for transferring ink, contained in the reservoir, to said first conduit of the lid. The invention also relates to a continuous ink jet printer, comprising: an ink circuit comprising a reservoir as described in the present application, for example as described above, a print head, hydraulic connecting means, for bringing from the ink tank on which the lid is deposited, an ink to print the print head. The invention also relates to a continuous inkjet printer, comprising: an ink circuit comprising a reservoir comprising a body and a cover as described in the present application, for example as described above, at least the first chamber being closed, laterally, by the inner wall of the tank body, - a printing head, - hydraulic connection means, for bringing from the ink tank, an ink to print the print head - Means for bringing an ink to recover from the print head to, according to the embodiment, the 1st conduit or the 3rd conduit. The invention also relates to a continuous ink jet printer, comprising: an ink circuit comprising a reservoir comprising a body and a cover as described in the present application, of the type comprising a 1st and a 2nd ducts, by example as described above, at least the 1st chamber being closed, laterally, by the inner wall of the tank body, - a print head, - hydraulic connection means, for bringing, from the ink tank , an ink to print the print head, - means for bringing to the first conduit an ink recovered at the bottom of the tank and, towards the second conduit, an ink from an ink supply circuit or a solvent from a circuit solvent supply. The invention also relates to a continuous ink jet printer, comprising: an ink circuit comprising a reservoir comprising a body and a lid as described in the present application, of the type comprising 3 ducts, for example as described above, at least the first chamber being closed, laterally, by the inner wall of the tank body, - a printing head, - hydraulic connecting means, for bringing from the ink tank, an ink to print the print head, - means for bringing: * to the 1st conduit an ink recovered at the bottom of the tank, * to the 2nd conduit, an ink or a solvent from an ink supply circuit or solvent, * towards the 3rd conduit, an ink to recover from the print head. The invention also relates to a method of operating a continuous inkjet printer of the type described in the present application, for example as described above, in which ink is recovered from the head of the ink jet. printing and sent to the 1st conduit, then into the 1st chamber, this ink then flowing along the inner wall of the tank. The invention also relates to a method of operating a continuous inkjet printer, of the type described in the present application, for example as described above, in which: - ink is recovered at the bottom of the reservoir and fed into the first conduit, forming a first ink flow in the first chamber, - ink or solvent is sent (e), by the ink supply circuit, in the second conduit, forming a 2nd flow in the 1st chamber, the 2 streams mixing in said 1st chamber, forming a mixture which flows along the inner wall of the tank. The invention also relates to a method of operating a continuous inkjet printer, of the type described in the present application, for example as described above, in which: - ink is recovered at the bottom of the reservoir and fed into the first conduit, forming a first ink flow in the first chamber, - ink or solvent is sent (e), by the ink supply circuit and / or solvent, in the 2nd duct, forming a 2nd flow in the 1st chamber, the 2 flows mixing in said 1st chamber, forming a mixture which flows along the inner wall of the tank, - the ink being recovered from the head of printing and sent to the 3rd conduit, then into the 2nd chamber, this ink then flowing along the inner wall of the tank.
BRIEF DESCRIPTION OF THE FIGURES - FIG. 1 represents a known printer structure; FIG. 2 represents a known structure of a printer head of an ICJ type printer; FIGS. 3A-3C illustrate solutions of FIG. supply of a reservoir, - Figures 4A - 4E show an embodiment of a lid according to the invention, - Figures 5A - 5E show another embodiment of a lid according to the invention, - Figure 6 is a bottom view of another embodiment of a lid according to the invention; FIG. 7 illustrates the operation of measuring rods in an ink tank of a CIJ-type printer; FIGS. 8A and 8B show exemplary embodiments of a tank according to the invention, with circulation of the ink from the lower part of the tank towards its upper part; FIGS. 9 to 13 represent aspects of a circuit of a CIJ printer to which the invention can be applied.
DETAILED DESCRIPTION OF AN EMBODIMENT
FIG. 4A shows a side view of an exemplary embodiment of a cover 33 for a reservoir of a printer, for example of the type shown schematically in FIGS. 7 or 8A-8B or 13.
This cover extends between an upper surface 33i and a lower surface 332. In the embodiment shown, these two surfaces are substantially parallel to each other and in an XY plane. By definition, the direction Z is the direction perpendicular to this plane.
A first part 33a, said upper part, will be supported above the side walls 19 of the tank, as shown schematically in Figures 4B and 4C. This first portion 33a has, in the XY plane, a shape, for example substantially square or rectangular.
A second portion 33b, said lower portion, has an outer shape adapted to the inner shape of the tank that the lid will close. For example, this outer shape is rectangular; alternatively it may be circular. In the latter case, this second portion 33b has for example the shape of a circular ring, which can be seen in Figure 6 (view from below). It has external dimensions adapted to those of the inner shape of the tank; in the case of a circular shape, it has an outside diameter D substantially equal to the inside diameter of the tank on which the cover is intended to be positioned to close it. Its lateral edge defines a cylindrical surface Se straight or part of a cylindrical surface Se right, which corresponds to the inner wall of the tank, when the latter is closed by the cover 33. A special case is that of the cylindrical surface of revolution , but, apart from this particular case, are also included here the straight cylinders, section other than circular, for example rectangular. The cylindrical surface extends parallel to an axis Z, which will be the vertical axis when the lid will be positioned on the reservoir. This second part is intended to be introduced into the upper part of the tank. It may advantageously comprise means for forming a seal with the inner wall of the tank, for example a peripheral groove 335e which will allow to receive a seal.
A conduit 331 passes through at least a portion of the lid, it is preferably positioned in a portion near the outer edge thereof. This conduit makes it possible to bring a fluid from the upper part 33a of the lid towards the surface Se, in fact towards the inner wall of the tank when the lid 33 is in position thereon. The fluid flows under the action of the circuit pump in which it flows, but also under the action of gravity. According to the illustrated embodiment, it comprises a first portion 331a, which extends in a direction substantially perpendicular to the XY plane of the cover (or parallel to the surface Se or the Z axis). This first part is extended by a second part 331b, which forms an elbow with the first part. The duct 331 opens into a chamber, or cavity, 333, through an opening 341. This chamber 333 can be made in a portion 333. In the illustrated embodiment, the latter is partly protruding from the lower part 33b of the lid. This portion extends the circular ring 33b, under the lower surface 332, over part of its periphery. In addition, this cavity, which faces the surface Se, is intended to come to face the wall 19, when the lid 33 is installed at the top of the tank. This arrangement is shown in FIGS. 4B and 4C. A variant is explained below in connection with FIG. 4E.
The chamber 333 is delimited by an inner surface, which comprises, in the illustrated embodiment, lateral walls 336, 337, whose front face 336a, 337a is almost in the surface Se and bears against the inner wall of the tank when the latter is closed by the lid 33; these front faces 336a, 337a advantageously have a curvature which corresponds to the inner surface of the tank. The chamber is thus open in or on the surface Se or the inner wall of the reservoir which will close the side later. A flat gasket (not shown in the figures) may optionally be disposed between these front faces 336a, 337a and the inner surface of the tank. A wall 349, in which the opening 341 is made, delimits the bottom of the cavity facing the surface Se (and the inner wall of the tank when the latter is closed by the lid 33).
The chamber 333 also comprises, in its lower part, flow means 338, for example at least one slot or at least one outlet orifice. In one embodiment, these means face an upper wall 339 of the chamber. These flow means will allow the fluid, which has entered the chamber 333, to flow along the wall 19. Preferably, these flow means provide the fluid with a surface greater than or equal to the surface of the the orifice 341. This condition ensures that the chamber 333 does not allow to retain liquid, which would lead to slow the flow of this liquid to the tank.
The duct 331 makes it possible to direct the liquid towards the surface Seet towards the internal wall of the tank when the latter is closed by the lid 33, preferably under the means 335e of sealing when these are present and / or at least partly under a level defined by the lower surface of the cover (the XY plane for example). The chamber 333 makes it possible to confine the liquid which will be directed towards the inner wall and then, by its outlet means, to guide it towards the bottom of the tank (or in a direction opposite to the upper surface 33i).
The cavity 333 advantageously has a volume large enough so that it is not saturated and so that the fluid does not overflow laterally. Practically, a volume of between 50 mm3 and 1000 mm3 may be suitable. As an indication, the volume of the reservoir is for example between 0.5 I and 10 I.
In the zone in which the duct 331 is made, the second portion 33b of the cover 33 may have a local extra thickness, which extends perpendicularly to the surface Se. FIGS. 4C and 6 show the thickness of this part 33b, which is smaller than the thickness ez of the part in which the conduit 331 is made.
Preferably, the duct 331 brings the fluid to the cavity 333 in a direction inclined towards the means 338. This inclination is a compromise between the fact of not splashing the wall and the constraint of limiting the length of the duct (and therefore the material necessary and to work to achieve it).
For example, this inclination is approximately 45 ° with respect to the XY plane (or with respect to the surface Se or Z tax) or, more generally, an angle between 30 ° and 60 ° (relative to the XY plane or with respect to the surface Se or to the axis Z). Thus, in the illustrated embodiment, the second portion 331b of the channels that bring the fluid to the cavity 333 is inclined, for example at an angle of about 45 °.
A variant, also covered by the invention, is shown in FIG. 4D, in which the first portion 331a of the duct forms, with respect to the XY plane, an angle other than 90 °, (or is not parallel to the surface Se or Z axis) for example an angle of 45 °. If the second part 331b, is also inclined by approximately 45 ° with respect to the XY plane (or with respect to the surface Se or to the axis Z), then these 2 parts form, between them, an angle d about 90 °. Accessibility is favored in the configuration of Figure 4B, with the use of a connector 350 that allows horizontal access.
After being discharged by the means 338, the fluid flows along the cavity 19: it can therefore neither create splashes (which could occur if drops of fluid were dropped on the surface of the liquid contained in the tank) nor disturb any measurements, for example level measurements, that would be carried out inside the tank. This is particularly the case when leveling rods 516 - 522 are provided, as illustrated in FIG. 4C. When the fluid is ink that comes from the printer head of a printer CIJ, the wall will allow to spread the ink on the side wall of the tank, which will lead to a spread on the one hand ink and, on the other hand, air bubbles, which can be contained in this liquid, because of the mixture that the ink has undergone, with air, during the suction in the gutter recovery.
An interface or connector element 350 may be disposed on the upper part 33i of the cover, to connect an outer conduit to the conduit 331. FIG. 4C shows a section of such an element 350 and can be seen in FIG. front view in Figure 4A. This element makes it possible to bring a fluid inlet 351 (in the form of, for example, a "fir" connector) in communication with the duct 331. A duct 353 is passed through which comprises two parts, which form, between they, an angle of about 90 °. This makes it possible to have an inlet 351 disposed parallel to the XY plane (or perpendicular to Se), which is favorable from the point of view of the space requirement, in a vertical direction (or along the Z axis) of the entire device. In the case of the embodiment of FIG. 4D, the connecting element 350 is represented in this same figure. It allows access at an angle of approximately 45 ° to the XY plane or the Se surface.
As illustrated in FIG. 4A, a second duct 331 'may be arranged parallel to the duct 331, this duct 331' passing through the upper part 33a of the lid and opening directly into the interior of the tank via an orifice 331 "(see FIG. 6): it does not need to be extended, inside the tank, by another conduit, because it simply allows an atmospheric pressure setting of the atmosphere above the liquid in the tank. The interface element 350 may be adapted to connect the inputs of the two conduits 331, 331 'to inputs 351, 351', as illustrated in FIG. 4A.
FIG. 4E shows (in a view from below) the case where the cavity 333 is closed by a wall 347 (which faces the wall into which the opening 341 opens) which itself comes to bear against the inner wall of the tank. This wall 347 advantageously has a curvature which corresponds to the inner surface of the reservoir. Its thickness is of the order of several tenths of a millimeter, for example between 0.2 and 1 mm. This wall is almost confused with the surface Se. The fluid, which exits the conduit 331, is thus directed, in a first time to this wall and to the surface Se (and to the tank wall when the lid is mounted on it). Then, it then flows against the inner wall of the tank, with the same effects as described above.
The means which have been described above in connection with FIGS. 4A-4E make it possible, for example, to bring ink which comes back from a printing head into the reservoir via the gutter 62 (see FIG. 2). .
FIG. 5A shows another embodiment of a lid 33. The references common to those of the preceding figures denote the same elements therein.
Ducts 431, 432 pass through the cover, preferably in a portion near the edge thereof.
These conduits make it possible to bring fluids, in particular liquids, from the upper part 33a of the lid towards the surface Se, in fact towards the inner wall of the tank when the lid 33 is in position thereon. The fluids flow under the action of the circuit pump in which they circulate, but also under the action of gravity. These ducts are substantially parallel to each other and, according to the illustrated embodiment, comprise a first portion 431a, 432a, which extends in a direction substantially perpendicular to the XY plane of the cover (or parallel to the surface Seou to the Z axis). Each of these first portions is extended by a second portion 431b, 432b, which forms an elbow with the first part. Each of the ducts 431, 432 opens into a chamber, or cavity, 433, said chamber or mixing cavity, through a through opening 441, 442. This chamber can be made in a portion 433. In the illustrated embodiment, the latter is prominent from the lower part 33b of the lid. This portion extends the circular ring 33b, under the lower surface 332, over part of its periphery. In addition, this cavity is intended to face the wall 19, when the lid 33 is installed at the top of the tank. This arrangement is shown in FIGS. 5B and 5C. A variant is explained below in connection with FIG. 5E.
This chamber 433 is delimited by an interior surface which comprises, in the illustrated embodiment, side walls 436, 437, whose front face 436a, 437a is almost in the surface Se and bears against the internal wall of the tank when last is closed by the lid 33; these front faces 436a, 437a advantageously have a curvature which corresponds to the inner surface of the tank.
The chamber is thus open in or on the surface Se or the inner wall of the reservoir which will close the side later. A flat gasket (not shown in the figures) may optionally be disposed between the front faces 436a, 437a and the inner surface of the tank.
A wall 449, in which each opening 441, 442 is made, delimits the bottom of the cavity facing the surface Se (and the inner wall of the tank when the latter is closed by the lid 33).
The chamber 433 also comprises in its lower part, flow means 438, for example at least one slot or at least one outlet orifice. According to one embodiment, these means face an upper wall 439 of the chamber, which may be substantially parallel to the XY plane or perpendicular to the surface Se or Z axis. These flow means will allow the liquid, which will have It is mixed in the cavity 433, to flow along the wall 19. Preferably, these flow means provide the fluid with an area greater than or equal to the sum of the surfaces of each of the orifices 441, 442. condition ensures that the cavity 433, if it ensures a mixing function, does not allow to retain liquid, which would lead to slow the flow of the mixture for the tank. These means 438 may be limited, laterally, by portions 436i, 437i which extend the side walls 436, 437 substantially parallel to the plane of XY.
These portions 436i, 437i form in fact a lower wall of the cavity, this lower wall being provided with means 438.
The conduits 431, 432 make it possible to direct the liquids towards the surface Se and towards the internal wall of the reservoir when the latter is closed by the cover 33, preferably under the means 335e of sealing when these are present and / or less in part under a level defined by the lower surface of the lid (the XY plane for example). The chamber 433 makes it possible to mix these liquids directed towards the inner wall, to temporarily confine them and then, by its outlet means, to guide the mixture towards the bottom of the tank (or in a direction opposite to the upper surface 33i).
The cavity 433 advantageously has, on the one hand, a sufficiently small volume so that the fluids that arrive through the orifices 441, 422 are effectively mixed therewith. But it also has, on the other hand, a volume large enough not to create too much pressure drop on the path of the mixture in question. Indeed, it is preferred that a liquid, for example a mixture of ink added from a cartridge and ink which comes from a recirculation from the bottom of the tank, arrives as quickly as possible in the liquid. contained in the tank, or in any case without being too slowed down by the fluid circuit that it is required to borrow. In practice, a volume of between 70 mm 3 and 2000 mm 3 may be suitable.
In the cavity 433 of FIG. 5A, curved arrows are shown which correspond to the turbulences and / or vortex movements which the fluids undergo when they are in the cavity. These swirling movements make it possible to ensure the mixing of the two liquids that arrive via the two ducts or channels 431, 432.
In the zone in which the conduits 431, 432 are made, the second portion 33b of the cover 33 may have a local extra thickness, which extends perpendicularly to the surface Se. FIGS. 5C and 6 show the thickness of this portion 33b, which is smaller than the thickness e2 of the portion in which the ducts 431, 432 are made.
Preferably, the conduits 431, 432 bring the liquids into the cavity 433 with an inclination, towards the means 438. This inclination is a compromise between the fact of not splashing the wall and the constraint of limiting the length of the duct (and therefore the necessary material and to work to realize it). For example, this inclination is approximately 45 ° with respect to the XY plane (or with respect to the surface Se or to the Z axis) or, more generally, from an angle of between 30 ° and 60 ° (relative to plane XY or with respect to the surface Se or to the axis Z). Thus, in the illustrated embodiment, the second portion 431b, 432b of the channels which bring the fluids to the cavity 433 is inclined, for example at an angle of about 45 °.
In the zone in which the conduits 431, 432 are made, the second portion 33b of the cover 33 may have a local extra thickness, which extends perpendicularly to the surface Se. FIGS. 5C and 6 show the thickness of this part 33b, which is smaller than the thickness e2 of the portion in which the ducts 431, 432 are made.
A variant, also covered by the invention, is shown in Figure 5D, wherein the first portion 432a of the duct forms, relative to the XY plane, an angle other than 90 °, for example an angle of 45 °. If the second portion 432b, is also inclined by about 45 ° relative to the XY plane (or with respect to the surface Se), then these 2 parts form, between them, an angle of about 90 °.
After being discharged by the means 438, the mixture of fluids flows along the cavity 19: it can not therefore create splashes (which could occur if drops of liquid were dropped on the surface of the liquid contained in the tank) or disturb any measurements, for example level measurements, that would be carried out inside the tank. This is particularly the case when 516-522 level measurement rods are provided, as shown in Figure 5C.
An interface or connector element 450 may be disposed on the upper part 33i of the cover, to connect two ducts external to the ducts 431, 432. FIGS. 5C and 5A respectively show a sectional view and a face of FIG. Such an element 450. This element makes it possible to bring inputs 454, respectively 455, of fluid (each in the form, for example, of a connection "fir") in communication with the conduit 432, respectively 431. It is crossed by two ducts. 452, 455, each having two parts, which form, between them, an angle of about 90 °. This makes it possible to have inputs 450, 455 disposed parallel to the plane XY (or perpendicular to Se), which is favorable from the point of view of accessibility, in a vertical direction (or along the Z axis) of the entire device. In the representation of Figure 5C, the inlet 454 is extended by a second chord 456, directed towards the bottom of the tank, which allows to bring a flow of ink, which is pumped into the bottom of the tank, to this input 454 to form a recirculation flow.
In the case of the embodiment of FIG. 5D, the connecting element 450 'is represented in this same figure. It allows access at an angle of approximately 45 ° to the XY plane or the Se surface.
FIG. 5E shows (in a view from below) the case where the cavity 433 is closed by a wall 447 (which faces the wall into which the orifice 341 opens) which comes, itself, to lean against the inner wall of the tank. This wall 447 advantageously has a curvature which corresponds to the inner surface of the tank. Its thickness is for example between 0.2 and 1 mm. This wall is almost confused with the surface Se. The fluids coming out of the ducts 431, 432 are thus directed firstly towards this wall and towards the surface Se (and towards the wall of the tank when the lid is mounted on it). Then, their mixture can then flow against the inner wall of the tank.
The means which have been described above in connection with FIGS. 5A-5E make it possible, for example, to bring into the reservoir a mixture of ink, which comes from the bottom of the tank, by recirculation, and ink, or respectively solvent, which comes from an ink cartridge, respectively solvent. The chamber 433, as described above, makes it possible to mix these two liquids before the mixture can flow against the inner wall of the tank, towards the reserve of liquid that it already contains. .
The two aspects that have been presented above can be combined in one tank lid. Thus, FIG. 6 shows a view from below of a cover which comprises a chamber 333 as described above in connection with FIGS. 4A-4E and a chamber 433 as described above in connection with FIG. Figures 5A-5E. References identical to those of the preceding figures denote the same elements.
It can be seen in this figure that the conduit 331 'opens, through an opening or an orifice 331' ', into a cavity formed or delimited by the lower part 33b.
It can also be seen in this figure that, in each of the four corners of the upper part 33a, an orifice 35, (i = 1-4) can be provided; these 4 holes will allow the attachment of the entire lid on the upper part of the tank.
The lid may be provided with means for receiving one or more measuring rods for measuring the level of liquid in the tank.
Thus, in FIGS. 4C and 5C, there are 4 measuring rods 516, 518, 520, 522 which dive into the reservoir and which pass through the upper part 33a of the cover 33. They are held by means 517, 519, 521 (the means for holding the rod 522 are not shown because they are behind the means 517), for example nuts, each of which is screwed onto a threaded portion which extends each of the rods. To reinforce the maintenance, insulating plates 530, 531 may be provided, on either side of the upper part 33a of the cover. These plates, as well as the upper part 33a, have orifices that allow each of the rods 516-522 to be inserted. We find the same elements in Figure 5C.
The operation of this set of measuring rods will be explained, in connection with Figure 7, in which the reference 19 further designates the wall of the tank.
In this figure are represented 2 rods, or electrodes, 516, 518 measurement and 2 rods, 520, 522 reference.
Each of the reference rods comprises an electrode covered, over a large part of its length, with a coating, or a sleeve, 524, 526, which leaves only an end portion of the corresponding electrode of length Ir Thus, it makes it possible to measure a liquid level, of depth Ir + p, p being the distance between the free end of the reference electrode and the bottom of the reservoir.
Each of the measuring rods 516, 518 comprises an electrode which is not covered by a sleeve, at least on the portion which is between the free end of the electrode, intended to be closest to the bottom. of the reservoir, and the maximum level hmax that one wishes to be able to measure. The different electrodes are made of conductive material, for example stainless steel.
The pairs of electrodes are supplied with current by means 530 forming a generator. The electrodes of each pair are electrically arranged in series. Preferably, the current supplied is an alternating electric current, at zero average to avoid any electrolysis.
Means 532 make it possible to measure a voltage Vm between the two measuring rods. For example, these means 532 comprise a resistor which makes it possible at the same time to measure the intensity by measuring the voltage and to limit the current in the circuit.
Preferably, these measuring means perform a sampling on the peak values, then an amplification.
Means 534, such as multiplexing means, may be provided to perform, alternately, a measurement at the terminals of the two measuring rods and a measurement at the terminals of the two reference rods. Thus, the pair across which no measurement is made is completely disconnected and has no influence on the measurement made across the other pair, and any coupling effect of the electrode pairs is avoided. In this configuration, the same voltage measurement means 532 can be used to measure a voltage Vr between the two measuring rods and to measure a voltage Vr between the two reference rods.
For example, a measurement is carried out for 100 ms with the two measuring rods, then for 100 ms with the two reference rods. The measurement times with the two measuring rods and the two reference rods can be equal or different: for example, the ratio of the measurement time with the two measurement rods to the measurement time with the two reference rods can be between 5 and 10.
Measurements of voltage Vm and Vr, it is possible to deduce an impedance, respectively a measurement impedance RM and a reference impedance Rr.
Rr / Rm is then calculated to deduce the level Iim of the liquid height by the following formula:
Rr / Rm is therefore calculated to deduce the ink level. This formula is independent of the conductivity of the liquid, which, as will be seen below, is confirmed by the experimental measurements. Surprisingly, it has been found that the reference resistance, per mm of ink, is different from the measuring resistance, per mm of ink.
A good measurement can be performed when the reference electrodes are totally immersed (this is the case in FIG. 7) and / or the measurement electrodes have a distance p ', with respect to the bottom of the reservoir, equal to p increased a length corresponding to the active part of the reference electrodes (this is also the case in FIG. 7). As a variant, the ends of the measurement electrodes may be protected by an insulating coating or insulating sleeves, of length equal to or greater than the active part Ir of the reference electrodes.
In the opposite case, the formula Ιίμ = K. (Rr / Rm) - Ko is not valid in the bottom of the tank as long as the ends (on the distance Ir) of the reference electrodes are not completely immersed (in this case In this case, the measurement and reference impedances are equal, which gives a value of constant hm). But, once the reference electrodes are totally immersed, we can then apply the formula above, the coefficients Ko and Ki being determined experimentally.
Electronic means can be programmed, for example in the printer controller, to calculate Iim as a function of the values of Rr and Rm. The measurement data is transmitted from the ink tank to the controller, which then performs the processing. data and the calculation of the ink or liquid level.
If the ink level thus calculated is below a predetermined threshold level, the controller can trigger a filling operation of the reservoir.
It is understood that the implementation of level measurement means by rods, directly in the reservoir, is a sensitive operation. In particular, such a measure must not be disturbed by inadvertent liquid flows, which would result from the introduction into the reservoir of ink or solvent. A lid according to the invention allows, as explained above, to bring the different liquids to the tank wall, so as far as possible from the level measuring rods. Any disturbance of the latter is avoided. Even in the absence of measuring rods, the maintenance in the tank of a level of undisturbed ink is preferred. In particular, this ink level must not be disturbed by inadvertent liquid flows, which would result from the introduction into the reservoir of ink or solvent. A lid according to the invention allows, as explained above, to bring the different liquids to the tank wall, so as far as possible from the level measuring rods. Any disruption of the ink level is avoided.
A lid according to the invention closes an ink tank. The lère and, optionally, the second chamber is / are closed laterally by the inner wall of the tank.
Fig. 8A is an exemplary embodiment of an ink tank 10 to which the invention can be applied, for an ink circuit of a continuous ink jet printer.
This reservoir 10 is delimited by one or more side walls 19 and covered with the cover 33, preferably according to one of the embodiments which has been described above. The bottom 622 of the reservoir is preferably conical and without any horizontal surface or with a small horizontal surface, so as to accumulate the least possible material. The tip of the cone is oriented towards the bottom of the device, in the direction of flow of a liquid when the reservoir is arranged vertically. To satisfy the sliding condition on an inclined surface, the angle of the cone, relative to the horizontal, is chosen so that it is greater than about 30 ° (and less than 60 ° or 80 °), or, with respect to the vertical or sedimentation direction of the pigments, less than about 60 ° (but greater than 10 ° or 30 °). The example of a portion of the tank whose wall is cone-shaped is given here, but other forms are possible, for example a pyramidal-shaped wall, or, more generally, a wall of convergent shape to a portion which has an ink flow orifice. The section of the part thus delimited is reduced in the direction of this flow orifice.
Such a flow orifice, or outlet, 621 of ink is in fact made in an end portion of the reservoir, preferably by the lower end thereof, here constituted by the tip of the cone. From this output, a first pipe or conduit 623 connects a pump 625 to said lower end. Preferably, the pump 625 is disposed under a level which passes through the lower part of the tank or under this lower part. This ensures that it is still charging and primed. More generally, any device for moving the ink from the bottom to the top of the tank can be used.
A second pipe or conduit 627 connects the outlet of the pump 625 to the inlet 454 of the interface means 450 disposed on the cover 33, as already described above (see for example Figure 5A). The ink therefore enters the tank again, at a point above the maximum level of the ink in the tank, so above the surface 635 of the ink present in the tank, which is at, for example, 10 mm or 50 mm from the top of the tank (defined by the lower face 332 of the lid 33).
Preferably, the pump 625 ensures a permanent circulation of the ink, with a flow rate greater than or equal to the sedimentation speed of the ink. The flow rate of the pump is for example between 10 l / h and 20 l / h, it is for example 14 l / h This circulation is carried out in one direction, from the bottom of the tank to its upper part.
The pump may be of the membrane pump type, or peristaltic pump, or gear pump, or centrifugal pump, or of any other type.
Preferably, it makes it possible to reach a flow rate greater than the sedimentation rate of the pigments over the entire surface of the cylindrical portion of the reservoir. For example, a flow rate greater than 0.5 cm3 / hour is sufficient for a tank whose largest section is 50 cm 2 of surface.
Preferably, the pumping is ensured permanently, whether the printer is in operation or not. This possibility can in particular be offered if the pump 625 is dedicated to the circulation of the ink, and is not subject to the operating rhythm of another feature.
The reservoir 10 may furthermore be provided with means 630 and / or 631 which allow the ink to be withdrawn, with a view to pressurizing and sending it to the print head. Each of these means may consist of a conduit, connected to a pump, 637, 639 respectively, which will allow to send the ink under pressure to the print head.
This sampling can take place at a minimum distance from the bottom of the tank and the surface of the liquid in the tank, which can, for example, be calculated with Stokes' law, as a function of the particle size of the largest particles of the tank. pigment of the ink, the density of the pigment, the density of the dispersing medium:
where v is the sedimentation rate in m / s, r the radius, D the particle diameter in m, g the gravitational constant 9.81 m / s2, Δρ the difference in density between the pigment and the liquid medium in kg / m3 , η the dynamic viscosity in Pa.s, and t is the time, with d = vt, d being the distance from the lowest point of the tank.
It is possible to define a median zone 115 of the reservoir, for example situated between: a first level A, defined by the outlet orifice of the ink or a level located at least 1 / 20th or 1 / 10th or 1/3 of the height of the tank, measured from its lowest point, in proportion to the height H of the tank (itself measured between the lowest point of the tank and the highest point of the tank, when the it is in operation), - and a second level B defined by the third or the upper quarter (again, measured in proportion to the height H of the tank, as explained above). In this zone 115, the concentration of the pigment ink remains substantially constant and equal to the initial nominal concentration.
An interesting place for the point of taking the ink is substantially in the middle zone 115, between the surface of the ink and the outlet orifice 621 disposed in the bottom of the reservoir. The distance D, measured vertically, or the direction of sedimentation of the pigments when the reservoir is in use, between the point of sampling of the ink and the orifice 621, is for example at least 10 mm, or 20 mm. mm, or 50 mm. The positioning of this sampling point 19i is preferably vertical to the orifice 621. It can be determined according to the physical parameters of the ink (in particular: granulometry of the pigment, density of the pigment, density of the dispersing medium) as explained above. The place of sampling is the one where the pigment concentration remains nominal, or substantially constant, preferably as long as possible, when the recycling will not be present.
A fixed sampling point is thus chosen, making it possible to maximize the stopping time of recycling depending on the use of the machine.
With a sampling point 19i positioned in the manner just indicated above, a sampling can be implemented at any time, without waiting for the recirculation provided between the bottom of the tank and the surface could homogenize the ink on the full height of the liquid, after a restart of the printer following a rest period. In this way, the printer can be put into operation without delay, at least with a much shorter lead time than in previous implementations.
In addition, or alternatively, a sampling of the ink for feeding the pressurized head can be carried out from the recirculation conduit 623 at the bottom of the reservoir. For this purpose, means 631 then make it possible to take a sample of liquid on this conduit. A sample from the conduit 623 makes it possible to supply the print head even when the level of ink in the reservoir is below the possible means 19i.
A device according to the invention may comprise one and / or the other of the sampling means 630, 631, each with the respective advantages which have been indicated above.
FIG. 8B is another embodiment of an ink tank to which the invention can be applied, for an ink circuit of a continuous inkjet printer, the cover 33 also having means, described above in connection with Figs. 4A-4E for recovering ink from the print head. The reservoir illustrated in this figure comprises the means which have already been described above in connection with FIG. 7A, but it also comprises means 350 of interface disposed on the cover 33, as already described above ( see for example Figure 4A). A pipe 357 leads the ink out of the channel 62 to the inlet 351. This recovered ink therefore enters the tank again, also at a point above the maximum level of the ink in the tank. , therefore above the surface 35 of the ink present in the tank.
The covers 33 of FIGS. 8A, 8B may be provided with measurement rods, as explained above with reference to FIG. 7.
A continuous ink jet printer according to the invention may comprise: an ink circuit comprising at least one reservoir according to the invention, a print head 1 (FIGS. 1 and 2), means 119 of hydraulic connection, for bringing from the ink tank an ink to print to the print head.
Electrical connection means are also provided for electrically powering the printer.
Collecting ink from the bottom of the tank and moving it or bringing it up the tank, using the cover according to the invention, even with an extremely low flow rate, is sufficient to maintain the homogeneity of the ink in the entire tank. This therefore represents a particularly interesting economy of means.
On the other hand, particles of solids sediment more quickly by sliding on an inclined surface than in a liquid, if the angle of the surface inclined relative to the horizontal is greater than the sliding angle of the particles.
These considerations are applied to the embodiments described below.
An example of a fluid circuit to which a tank according to the invention can be applied is illustrated in FIG. 9.
References identical to those already used previously designate identical or corresponding elements. In particular, there is the flexible umbilicus 119, which brings together the hydraulic and electrical connections and the print head 1, to which the printer architecture described below can be connected.
In this figure, we see that the fluid circuit 4 of the printer comprises a plurality of means 10, 50, 100, 200, 300, each associated with a specific feature. To this circuit 4 are associated a removable ink cartridge 30 and a cartridge 40 of solvent, also removable.
The reference 10 designates the main tank, which can accommodate a mixture of solvent and ink.
Reference 100 denotes the set of means which make it possible to take and possibly store solvent from a cartridge 40 of solvent and to supply the solvent thus taken from other parts of the printer, which it this is to supply the main tank 10 with solvent, or to clean or maintain one or more of the other parts of the machine.
Reference 300 denotes the set of means for taking ink from an ink cartridge 30 and supplying the ink so taken to feed the main reservoir 10. As seen in this figure, according to the embodiment presented here, the sending, to the main tank 10 and from the means 100, of solvent passes through these same means 300.
At the outlet of the tank 10, a set of means, generally designated by the reference 200, makes it possible to pressurize the ink taken from the main tank, and send it to the print head 1. According to one embodiment, illustrated here by the arrow 25, it is also possible, by these means 200, to send ink to the means 300, then back to the reservoir 10, which allows recirculation of the ink inside. of the circuit. This circuit 200 also makes it possible to drain the reservoir in the cartridge 30 as well as to clean the connection of the cartridge 30 (in the case of the embodiment of FIG. 12, by changing the position of the valve 37).
The system shown in this figure also comprises means 50 for recovering the fluids (of the ink and / or the solvent) which comes back from the printing head, more precisely from the gutter 62 of the printing head or the circuit rinsing the head. These means 50 are therefore disposed downstream of the umbilicus 119 (with respect to the direction of circulation of the fluids coming back from the print head).
As can be seen in FIG. 9, the means 100 can also make it possible to send solvent directly to these means 50 without passing through the umbilicus 119, the print head 1 or the salvage groove 62.
The means 100 may comprise at least 3 parallel solvent feeds, one to the head 1, the second to the means 50 and the third to the means 300.
Each of the means described above is provided with means, such as valves, preferably solenoid valves, which guide the fluid concerned to the chosen destination. Thus, from the means 100, it is possible to send solvent exclusively to the head 1, or to the means 50 or to the means 300.
Alternatively, with the same means, it is possible to send solvent to all the constituent means of the ink circuit, for example for a general rinsing circuit.
Each of the means 50, 100, 200, 300 described above is provided with a pump which makes it possible to treat the fluid in question (respectively: 1st pump, 2nd pump, 3rd pump, 4th pump). These different pumps provide different functions (those of their respective means) and are therefore different from each other, even if these different pumps can be of the same type or similar types (in other words: none of these pumps). provides 2 of these functions). The means 20 make it possible to ensure recirculation (they play the role of the pump 625 of FIGS. 8A, 8B).
In particular, the means 50 comprise a pump (1st pump) which allows to pump the fluid, recovered, as explained above, from the print head, and to send it to the main tank 10. This pump is dedicated the recovery of this fluid from the print head and is physically different from the 4th pump of the means 300 dedicated to the transfer of the ink or the third pump of the means 200 dedicated to pressurizing the ink at the outlet of the tank 10.
The means 100 comprise a pump (the 2nd pump) which makes it possible to pump the solvent and send it to the means 50 and / or the means 300 and / or to the print head 1.
FIG. 10 illustrates a more detailed representation of the means 100 which make it possible to take solvent from a cartridge 40 and to send it to the various parts of the device to carry out cleaning or unclogging operations.
These means comprise a pump 41 (the 2nd pump) and various fluidic connection means, each comprising one or more conduits or one or more valves 39, 42. One of these valves, the valve 42, is used to orient the solvent to 2 possible ways, namely the print head 1 or the ink supply circuit 300. In the latter case, when the means, which allow the entry of solvent into the means 300, are themselves closed, the solvent is directed towards the means 50. One can also find, in series with the pump, a device -pulsation 411 and a filter 412.
An intermediate tank 14 may also be provided, which may be provided with level measuring means 14 ', and which may be fed from a cartridge 40 when connected to the circuit.
This reservoir 14 sends solvent to the various means 50, 300 and / or to the print head 1 and / or the main tank 10, for cleaning or to unclog hydraulic components. Solvent can also be taken from the cartridge 40 and be sent directly to the various elements of the circuit, to perform the same operations (cleaning or unclogging). It is through a valve 39 that the origin of the solvent is selected. In this figure, as on the others, the positions "normally open" (= NO) and "normally closed" (= NC) of each valve are also represented. Here, if the valve 39 is in the "NC" position (FIG. 4), then the solvent is pumped from the cartridge 40, if it is in the "NO" position, then the solvent is pumped from the tank 14.
The reservoir 14 can be fed from the cartridge 40, for example by a calibrated leak, or restriction, 45 disposed at its inlet. This leakage also contributes to the generation of pressure. The filling of the reservoir 14 can be carried out in the following manner: the valve 39 is in the "NC" position (see FIG. 13), which makes it possible to pump, using the pump 41, the solvent from the cartridge 40. The valve 42 is in the closed position (NC), while the inputs of the means 50 and 300 are prohibited to the solvent. It is with the aid of the valve 42 and the means arranged at the inlet of the means 50, 300, for example an inlet valve for each of these means, that the solvent can be sent to these various means 50 (via the leads 335), 300, then possibly to the main tank 10, and / or to the print head 1 (via the conduit 337). Thus, at the output of the means 100, three channels in parallel can be defined which, according to the need, will make it possible to send the solvent to one and / or the other of these elements.
The means 100 may also comprise means 47 forming a pressure sensor, which make it possible to measure the pressure of the solvent at the outlet of the pump 41 and the means 411, 412. This information may be used to detect an increase in the pressure of the solvent, this can translate a clogging of one of the ducts in which the solvent circulates.
FIG. 11 illustrates a more detailed representation of the means 50 which make it possible to recover fluids (of the ink and / or of the solvent) which comes back from the print head. 2 types of fluid can thus be joined at the input of these means 50: ink that comes from the gutter 62 (see Figure 2) recovery, and solvent, which was used to clean or rinse the print head 1 and / or the umbilicus 119. A conduit 511 directs these fluids to the inlet of the means 50.
These include a pump 53 (the 1st pump), possibly a filter 52 arranged in series therewith, for example upstream of the pump, and means 51 forming an inlet valve. These means 51 comprise one or more valve (s), preferably a three-way valve. They make it possible to send, to the pump 53, only either the fluid which comes from the head 1 (position NO of the valve in FIG. 5), via the conduit 511, or the solvent coming from the means 100 (position NC of the valve in Figure 5) via conduit 335.
The fluid pumped by the pump 53 can then be sent to the main reservoir 10, preferably via a set of means as described above in connection with FIGS. 4A-4E.
FIG. 12 illustrates a more detailed representation of the means 300, in cooperation with the main tank 10 and the means 200.
The main reservoir 10 is preferably provided with means 15 for detecting the level of the ink (in fact, the ink is mixed with solvent) contained therein. In the examples described above, these means may comprise one or more level measuring rods. The lid 33 according to the invention of the tank described above can be adapted, as already explained, for the implementation of these rods.
The reference 301 designates the cannula (or any equivalent means), which will make it possible to connect, from the fluidic point of view, a cartridge 30 to the rest of the circuit.
In operation during printing, when a cartridge 30 is in place and contains ink, ink can be pumped, by means of pumping means 31 (4th pump), towards the main reservoir 10 via fluidic connection means, comprising ducts 346, 343, 344, 347 and one or more valves (or solenoid valves) 133, 135, which may be "3-way" type valves. Thus, the ink transfer pump 31 pumps ink, from the cartridge 30, which passes successively via the valves 135 and 133 (respectively in positions "12", or "NC", and "23", or "NO" in Figure 15), and by the ducts 343, 344, 347 to arrive in the main tank 10. The NO state (respectively NC) of the valve 135 corresponds to the position "23" (respectively "12"). ") And connects the conduits 345 and 343 (respectively 346 and 343).
At the input of the means 300, means 345, 135, for example respectively a conduit and a valve (when it is in position "32" (NO) in FIG. 12), will make it possible to receive solvent from the means The means 300 may carry this solvent at a pressure, for example, in gauge pressure, between 0 and 5 bar, or between 0 bar and 10 bar, in fluidic connection means. . Depending on the open or closed state of the valves 135 and 133, this solvent can be directed via the conduits 343, 344: to the reservoir 10 (via the conduit 347, valve 135 in position "32" ( NO), valve 133 in position "23" (NO); this to send solvent, for example for cleaning, to the tank 10; - to duct 320 (via duct 348, valve 135 in position "32" (NO), valve 133 in position "21" (NC)). With the valve 37 in the NO position, the solvent can then be directed towards the cartridge 30 via the conduits 344, 348 and 320.
The means 200, at the outlet of the main reservoir 10, comprise a pump 20 (3rd pump, called the pump for pressurizing the ink) which makes it possible to pump ink, or the fluid it contains, from the main tank 10, and this again or this fluid can be directed either to the main tank itself (via a return duct 318 and a lid according to the invention, the duct 318 joining the duct 431) is, via one or more conduits 319, 320, to the cartridge 30 itself (and into it). The path of the ink at the outlet of the pump 20 can be controlled using one or more valves 37, preferably a 3-way valve. In FIG. 12, the position "21" ("NC") of the valve 37 makes it possible to direct the fluid towards the duct 319, the "23" ("NO") position towards the duct 318. From the fluid can be sent to the 1, via a conduit 21, which takes it downstream of the pump 20, from a point disposed between the output of the pump 20 and the valve 37. The print head itself contains a valve that allows to authorize, or not, the production of an inkjet and possibly an impression. In general, the instructions for activating the pumps and the valves are sent and controlled by the control means 3 (also called "controller"). In particular, it is these instructions that will make it possible to circulate solvent under pressure, from the means 100, towards the various other means 1, and / or 50, and / or 300 of the circuit (and possibly, via these latter means). means 300, to the main tank 10).
The control means 3 control the opening and closing of each valve, as well as the activation of the pumping means, in order to circulate the ink and / or the solvent as described in the present application. It also stores data, for example data for measuring ink levels and / or solvent, and their possible treatment. The controller is also programmed to handle non-cleaning operations, including print operations.
The control means 3 comprise for example a processor or a microprocessor, programmed to implement any method described in the present application.
An ink circuit in which the circuits and the elements described above, in particular in connection with FIGS. 4A-12, can be used, is illustrated in FIG. 13. The various means 10, 50, 100, 200, 300 described herein above are combined.
Numerical references identical to those of the preceding figures denote identical or corresponding elements.
At the outlet of the main tank 10, there is arranged a filter 22, then the pump 20 and an anti-pulsating device 23. A pressure sensor 24, and possibly a temperature sensor, can be provided, as illustrated in the figure: the data supplied to the controller to enslave the ink pressure to a setpoint, usually when the ink jet speed in the head is not available (for example when jet ejection is stopped, or jet speed is not measurable). As already indicated above, the ink is sent to the print head 1, via the conduit 21, connected downstream of the anti-pulsation device 23, between the pump 20 and the valve 37. The print head contains itself a valve that allows to allow or not, the production of an inkjet and possibly an impression. The ink is filtered by the main filter 27 downstream of the sensor 24 before being sent to the head 1.
The intermediate reservoir 14 has already been described above. A duct 141 makes it possible to put at the same atmospheric pressure the free volume situated above each of the liquids contained in the tanks 10 and 14. This duct may be connected to the duct 331 ', decreasing above in connection with FIG. 4A.
It may be noted that, when the valve 42 is in the "NC" position while the valve 35 is in the "NC" position, the circulation of solvent is blocked, both in the direction of the cartridge 30 and in the direction of the duct 343; the solvent is thus directed towards the valve 51 or to the restriction 45 (to then enter the intermediate tank 14).
It is understood that solvent and / or ink, from the cartridges 30, 40, can be sent to the tank 10. These additions are made in a timely manner, preferably on instruction of the control means. The circulation of the ink, from the bottom of the tank to the lid, as explained in connection with FIGS. 8A and 8B, is preferably continuous in time. The recovery of ink from the head depends on the start of the jet. The invention is of particular interest in the case of an ink containing dispersions of dense particles such as metals or metal oxide pigments. For example, titanium, zinc, chromium, cobalt or iron (such as TiO 2, ZnO, Fe 2 O 3, Fe 3 O 4,...) In the form of micron or submicron particles. Such a pigment ink may, for example based on TiO 2, be used for the marking and identification of black or dark supports.
But it is also interesting in the case of any ink, non-pigmentary, which, as already explained, can dry and form deposits of dry matter in the conduits and connections of the ink circuit.

权利要求:
Claims (24)
[1" id="c-fr-0001]
1. A reservoir cover for a continuous ink jet printer, having a so-called upper surface (33i), a so-called lower surface (332), between which are included an upper portion (33a) and a lower portion (33b) of cover, at least the latter being delimited laterally by a peripheral surface (Se), and: at least one first conduit (331, 431, 432), which passes through at least a portion of the cover, to bring a first fluid from said part greater towards said lower part and directing it, at least partly, laterally towards said peripheral surface (Se); at least one chamber (333, 343) delimited by an inner surface into which said duct opens and by said peripheral surface (Se), and means (338, 438) for discharging a liquid contained in this chamber in a parallel direction to said peripheral surface.
[2" id="c-fr-0002]
2. Lid according to claim 1, wherein said first conduit passes through at least a portion of the lid in at least one direction parallel to the peripheral surface (Se).
[3" id="c-fr-0003]
3. Lid according to one of claims 1 or 2, wherein at least a portion (331b, 431b, 432b) of the duct is directed towards said peripheral surface (Se) in a direction forming, with this peripheral surface (Se), an angle between 30 ° and 60 °
[4" id="c-fr-0004]
4. Lid according to one of claims 1 to 3, said peripheral surface (Se) being cylindrical.
[5" id="c-fr-0005]
5. Lid according to one of claims 1 to 4, the lower portion (33b) having at least one peripheral portion (333, 43s) which projects from said bottom surface (332), at least a portion of said lère chamber being made in said peripheral portion.
[6" id="c-fr-0006]
6. Lid according to one of claims 1 to 5, further comprising means (523, 525, 527, 529, 530, 531) for receiving at least one measuring rod (516, 518, 520, 522).
[7" id="c-fr-0007]
7. Lid according to one of claims 1 to 6, further comprising means (350,450) of fluid connection, on the upper surface (33i), for bringing at least the first fluid to an inlet of the first conduit.
[8" id="c-fr-0008]
8. Lid according to claim 7, said means (350, 450) of fluidic connection, having an inlet for bringing the 1st fluid in a direction perpendicular to the peripheral surface (Se).
[9" id="c-fr-0009]
9. Lid according to one of claims 1 to 8, further comprising lateral means (335e) for sealing with the wall of a tank, lateral means (335e) being arranged between said first chamber (333, 343). ) and the upper surface (33i).
[10" id="c-fr-0010]
10. Lid according to one of claims 1 to 9, further comprising at least one conduit (331 ') which passes through the upper part (33a) and which opens into a cavity defined by the lower part (33b).
[11" id="c-fr-0011]
11. Lid according to one of claims 1 to 10, comprising at least a second duct (431, 432), which passes through at least a portion of the cover, for bringing a second fluid from said upper portion to said lower portion and directing at least partly, laterally, towards said peripheral surface (Se), this second duct opening into the 1st chamber.
[12" id="c-fr-0012]
12. Cover according to claim 11, the first conduit and the second conduit (431, 432) being at least partly parallel to each other.
[13" id="c-fr-0013]
13. Lid according to one of claims 11 or 12, the first conduit, respectively the second conduit, opening into the first chamber by a first orifice (441), respectively a second orifice (442), the sum of the surface of the 1st orifice and the second orifice, through which the first fluid and the second fluid, being less than or equal to the surface of the means (438) for discharging the liquid from the chamber.
[14" id="c-fr-0014]
14. Cover according to one of claims 11 to 13, comprising: - at least a third conduit (331), which passes through at least a portion of the lid, for delivering a liquid from said upper portion to said lower portion and directing it, at least in part, laterally to said peripheral surface (Se); at least one second chamber (333) delimited by an inner surface in which said duct opens and by said peripheral surface (Se), and means (338) for flowing the liquid from this second chamber in a direction parallel to said peripheral surface; .
[15" id="c-fr-0015]
15. Lid according to claim 14, said third conduit (331) opening alone in said chamber (333).
[16" id="c-fr-0016]
16. Lid according to one of claims 1 to 10, said first conduit (331) opening alone in said 1st chamber (333).
[17" id="c-fr-0017]
17. Tank comprising a body (19) and a cover (33) according to one of claims 1 to 16, at least the first chamber being closed, laterally, by the inner wall of the tank body.
[18" id="c-fr-0018]
18. Tank according to claim 17, comprising means (23, 25, 27) for transferring ink, contained in the reservoir, to said first conduit (331, 431, 432) of the lid.
[19" id="c-fr-0019]
19. Continuous inkjet printer, comprising: an ink circuit comprising a reservoir according to one of claims 17 or 18, a print head (1), hydraulic connection means, for bringing about from the ink tank, an ink will print the printhead (1), - electrical connection means for electrically supplying said printhead.
[20" id="c-fr-0020]
20. Continuous inkjet printer, comprising: - an ink circuit comprising a reservoircomportantody (19) and a cover (33) according to claim 16, at least the 1st chamber being closed, laterally, by the inner wall of tank body. - a print head (1), - hydraulic connection means, for bringing, from the ink tank, an ink to print the print head (1), - means for bringing an ink to recover from the print head to the first conduit, - electrical connection means for electrically supplying said print head.
[21" id="c-fr-0021]
21. Continuous inkjet printer comprising: an ink circuit comprising a reservoir comprising a body and a cover according to one of claims 11 to 15, at least the first chamber being closed; , laterally, through the inner wall of the tank body, - a print head (1), - hydraulic connection means, for bringing from the ink tank, an ink to print the print head (1 ), - means for feeding to the first conduit an ink recovered at the bottom of the reservoir and, towards the second conduit, an ink or a solvent from an ink supply circuit or solvent, - electrical connection means for supplying electrically said print head.
[22" id="c-fr-0022]
22. Continuous ink jet printer comprising: an ink circuit comprising a reservoir comprising a body and a cover according to one of claims 14 or 15, at least the first chamber being closed; , laterally, through the inner wall of the tank body, - a print head (1), - hydraulic connection means, for bringing from the ink tank, an ink to print the print head (1 ), - means for bringing: * to the first conduit, an ink recovered at the bottom of the reservoir, * to the second conduit, an ink or a solvent from an ink supply circuit or solvent, * to the 3rd conduit an ink to be recovered from the print head; - Electrical connection means for electrically powering said print head.
[23" id="c-fr-0023]
23. The method of operation of a continuous inkjet printer according to claim 20, wherein ink is recovered from the print head and sent to the first conduit, then in the first chamber, that ink. flowing thereafter along the inner wall of the tank.
[24" id="c-fr-0024]
24. A method of operating a continuous inkjet printer according to claim 21 or 22, wherein: - ink is recovered at the bottom of the reservoir and fed into the first conduit, forming a first flow of ink in the first chamber, - ink, or solvent, is sent, by the ink supply circuit, in the second conduit, forming a second fluid flow, in the 1st chamber, the 2 flows mixing together in said first chamber, forming a mixture which flows along the inner wall of the tank.

类似技术:

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同族专利:

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公开号 | 公开日

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EP3124254B1|2020-03-18|

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US9895898B2|2018-02-20|

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US20170028736A1|2017-02-02|

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FR3039457B1|2020-10-02|

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EP3124254A3|2017-03-22|

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CN106393985B|2019-07-30|

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CN106393985A|2017-02-15|

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EP3124254A2|2017-02-01|

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法律状态:
2016-07-29| PLFP| Fee payment|Year of fee payment: 2 |

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2017-02-03| PLSC| Search report ready|Effective date: 20170203 |

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2017-07-31| PLFP| Fee payment|Year of fee payment: 3 |

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2018-07-27| PLFP| Fee payment|Year of fee payment: 4 |

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2019-07-31| PLFP| Fee payment|Year of fee payment: 5 |

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2020-07-31| PLFP| Fee payment|Year of fee payment: 6 |

优先权:

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申请号 | 申请日 | 专利标题

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FR1557326A|FR3039457B1|2015-07-30|2015-07-30|LID FOR INK TANK WITH MIXING FUNCTION|FR1557326A| FR3039457B1|2015-07-30|2015-07-30|LID FOR INK TANK WITH MIXING FUNCTION|

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US15/223,543| US9895898B2|2015-07-30|2016-07-29|Lid for an ink reservoir with mixing function|

---

EP16181969.3A| EP3124254B1|2015-07-30|2016-07-29|A lid for an ink reservoir with mixing function|

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CN201610622576.0A| CN106393985B|2015-07-30|2016-08-01|Lid for the ink container with mixed function|