RU2690970C1 - Fluid medium cartridge - Google Patents

Abstract

FIELD: printing equipment.

SUBSTANCE: invention relates to fluid medium cartridges, which are replaceable assemblies with a corresponding fluid dispensing mechanism. Disclosed ink cartridge for jet printer comprises: interfaces on front surface for connection to receiving structure for cartridge, wherein said interfaces include an ink receptacle near the lower surface and a gas socket, a guide interface for guiding the cartridge along a straight line for connecting to said interfaces, wherein guide interface is located in lower surface and has guide receiving opening, located on front surface and lower surface, latch stop and latch track in lower surface to guide and hold latch of receiving structure for cartridge and electric circuit including memory containing data with characteristics of cartridge, wherein electric circuit is located near upper surface, which is opposite and parallel to lower surface, and the electric circuit is located near the front surface, passes behind the front surface and is recessed relative to the front surface so as to establish electrical contact after other interfaces are connected, wherein the electric circuit comprises electrodes which extend in a plane perpendicular to the front surface and are located on a line parallel to the front surface and located behind the front surface, wherein height of ink cartridge between upper surface and lower surface is greater than width of ink cartridge, guide receiving hole, receptacle for ink, gas socket and electric circuit are arranged in that order along the line in direction of cartridge height, and electric circuit is designed to establish connection along lateral side (X, B) with appropriate connection circuit within cartridge outer periphery.

EFFECT: technical result consists in elimination of deviations of engaged elements, as well as incorrect connection of interface, leaks, wear or damage of material.

7 cl, 15 dwg

Description

Background of the invention

Fluid cartridges are replaceable assemblies with an appropriate fluid dispensing mechanism. A well-known fluid cartridge is an ink cartridge. A well-known fluid dispenser is a printer. Basically, there are two types of ink cartridges. The first type is a cartridge made integral with the print head, where the cartridge contains a print head. The second type is a separate ink container. The ink container is connected to the printer's receiving construction. The ink cartridge's receiving structure is equipped with appropriate interfaces for directing ink from the cartridge to the print head for printing. In addition to the ink interface, an air interface, a key interface, an electrical interface, and a leveling interface may be present in the ink cartridge and in its receiving structure. The air interface moves air into and out of the cartridge, mainly to control the pressure inside the cartridge. The key interface ensures that the corresponding cartridge is seated in the corresponding receiving structure of the ink cartridge. The equalization interface ensures that the interfaces are mechanically aligned with each other to provide a connection. The electrical interface sends electrical signals between the printer's control circuit and the ink cartridge. These signals may refer to the characteristics of the ink cartridge.

To maintain substantially complete air and fluid tightness of the connections between the cartridge and its receiving structure, an additional lock is usually installed. This additional lock must also maintain electrical connection. Known locking methods are based on the use of loops to hold the cartridge in a sealed position relative to the receiving port. Another known method of locking uses a deformable "snap finger", which enters the recess and thereby maintains the tightness of the cartridge.

Known locking mechanisms, as a rule, occupy a relatively large amount of space inside the printer. In addition, it can take a significant amount of effort to lock. In some cases, the cartridge is inserted with an oblique orientation, after which it is turned back to the normal position to grip the interfaces. Usually this entails a deviation of the interlocking elements, so that the wrong connection of the interface, leakage, wear or damage to the material is possible.

Brief Description of the Drawings

Further, for illustrative purposes, some embodiments of the present invention will be described with reference to the accompanying schematic drawings, in which:

figure 1 shows a drawing of the front view of a variant of the delivery system for a fluid;

FIG. 2 shows a side view drawing of an embodiment of the dispensing system for the fluid of FIG.

Figure 3 shows a sectional side view of a part of an embodiment of a delivery system for a fluid with a fluid cartridge in an unconnected position;

figure 4 shows a front view of a variant of the element of the receiving structure of the cartridge for the fluid;

Figure 5 shows a perspective view of one embodiment of a fluid cartridge;

6 shows another perspective view of one embodiment of the fluid cartridge of FIG. 5, which clearly shows the guide track and the latch track;

FIG. 7 shows a sectional side view of an embodiment of a part of the fluid dispensing system of FIG. 3, in which the fluid cartridge is connected to the receiving structure of the cartridge;

8 shows a block diagram of an embodiment of a method for connecting a fluid cartridge to a receiving structure;

Fig.9 shows a block diagram of a further embodiment of the method of connecting and disconnecting a fluid cartridge with a corresponding receiving structure;

Figure 10 shows a conditional sectional view from below of an embodiment of the cartridge for the fluid and the receiving structure of the cartridge in the first step of connecting the cartridge for the fluid, and the latch mechanism is shown as "translucent" for illustration purposes;

11 shows a conventional sectional view from below of an embodiment of the cartridge for the fluid and the receiving structure of the cartridge of FIG. 10 in the second step of connecting the cartridge for the fluid, and the latching mechanism for the purpose of illustration is depicted as "translucent";

FIG. 12 shows a conditional section view from below of an embodiment of the cartridge for the fluid and the receiving structure of the cartridge of FIG. 10 in the third step of connecting the cartridge for the fluid, while the latching mechanism for the purpose of illustration is shown as “translucent”;

FIG. 13 shows a conditional sectional view from below of an embodiment of the cartridge for the fluid and the receiving structure of the cartridge of FIGS. 10-12 in the last step of connecting the cartridge for the fluid, with the latching mechanism being illustrated as “translucent” for illustration;

FIG. 14 shows a conditional sectional view from below of an embodiment of the cartridge for the fluid and the receiving structure of the cartridge of FIGS. 10-12 in the first stage of disconnecting the cartridge for the fluid, and the latching mechanism for illustration purposes is depicted as “translucent”;

Fig.15 shows a conditional section of a bottom view of an embodiment of the cartridge for the fluid and the receiving structure of the cartridge of Figs 10-12 in the second step of disconnecting the cartridge for the fluid, and the latch mechanism is shown as "translucent" for illustration.

Detailed Description of the Invention

The following is a detailed description with reference to the accompanying drawings. The embodiments given in the description and in the drawings are to be regarded as illustrative, and should not be construed as limiting the present invention to a specific embodiment or to the described element. From the following description and / or drawings, by modifying, combining or modifying some elements, numerous variants of execution can be obtained. In addition, it should be understood that those skilled in the art on the basis of this description and drawings may obtain other designs or elements that are not literally described here.

In the present description, a three-dimensional space with coordinate axes X, Y, Z can be used as a reference system. The one-dimensional direction of insertion and extraction of the cartridge parallel to the axis Y. This Y axis is also called a straight line Y.

1 and 2 show a fluid delivery system 1. The fluid delivery system 1 comprises a fluid delivery device 2 and fluid cartridges 3. The fluid delivery device 2 may comprise a printer. This printer may be an inkjet printer, such as a thermal inkjet printer, a piezoelectric inkjet printer, or a continuous inkjet printer. The fluid delivery device 2 comprises one or more receiving structures 4 for receiving and replacing one or more fluid cartridges 3. Each cartridge of the same fluid dispenser 2 may contain a different fluid. If the fluid delivery device 2 is a printer, the fluid in each cartridge may contain ink of its own color, such as cyan, magenta, yellow, black, and / or gray. The cartridge 3 is made with the possibility of interchangeability with respect to the corresponding receiving structure 4.

The receiving structures 4 are intended to connect the cartridge 3 to the print head 5. There is a fluid communication channel 6 for receiving fluid from the respective cartridges 3 and to supply this fluid to the print head 5. In the shown embodiment, the receiving structures 4 and the cartridges 3 , being installed, are off-axis. The printhead 5 may be a matrix printhead to the width of the page or a scanning printhead. The receiving structure 4 is designed to create a fluid interface between the cartridge 3 and the print head 5 by means of the communication channel 6. During printing, the print medium 7 passes under the printhead 5. In other versions (not shown), the receiving structures 4 and the cartridges 3, when installed, are located on the scanning axis. In the following versions of the cartridge 3 contains a built-in printhead, in which the cavity for the fluid and the actual printhead are made together in one cartridge feeder designed to be connected to the receiving structure 4.

The fluid delivery device 2 is equipped with a control circuit 8 and a memory 9. The fluid cartridge 3 is equipped with an electrical circuit 10, for example, including a cartridge memory 11. The control circuit 8 is configured to receive data from the electrical circuit 10. These data contain some characteristics of the cartridge, for example, product characteristics, characteristics of the type of fluid and / or characteristic of the amount of fluid.

Figure 3 shows the receiving structure 4 and the cartridge 3 for the fluid and in the right position before its installation or after installation. When installed (see Fig. 7), all interfaces of the receiving structure 4 and the fluid cartridge 3 are interconnected. The receiving structure 4 may contain a hole in the form of a notch into which the cartridge 3 is inserted. A part of the receiving structure 4 may be configured to guide the cartridge 3 into the connection with the guide 17 and then move along a straight line Y. Arrow A shows the direction of insertion of the cartridge 3 along a straight one-dimensional the Y line represented by the Y axis. As soon as the cartridge 3 enters the guide 17, its input movement is essentially limited to moving along a straight line Y. In principle, along the Z and X axes there is essentially no In addition, there is essentially no rotational movement of the cartridge 3 during input and output along the guide 17. However, it will be understood by those skilled in the art that between the mutually mating elements of the cartridge 3 and the receiving structure 4, such as guide 17, a certain amount of backlash, error, or tolerance may be acceptable. In one embodiment, the deviation error is approximately 3 millimeters or less in a direction perpendicular to the straight line Y, and approximately 3 or less around the straight line Y, or the Z axis, or the X axis. These errors, however, allow the correct connection of the cartridge 3 with receiving structure 4.

The receiving structure 4 contains two fluid interfaces. These fluid interfaces include one nipple 12 of the first fluid and one nipple 13 of the second fluid. The first fluid medium may be a printing fluid, such as ink. The second fluid may be a gas, such as air. The fittings 12 and 13 are designed to create fluid communication channels between the respective first and second fluid interfaces of the cartridge. The first and second fluid interfaces of the cartridge may contain, respectively, the slots 14 and 15. The fittings 12, 13 have, respectively, the central axes C1, C2, which are parallel to the axis Y. In one embodiment (not shown), the receiving structure 4 has only one fluid interface, such as choke. In another embodiment (not shown), the receiving structure 4 has more than two such fluid interfaces.

In one embodiment, the first fluid fitting 12 comprises an ink fitting. The first fluid fitting 12 has a relatively small diameter at its bore 16. The first fluid fitting 12 has an elongated shape. The first fluid fitting 12 has a truncated conical shape. The first fluid fitting 12 may be made of molded plastics. The receiving structure 4 comprises a guide 17 for guiding the movement of the cartridge 3 when inserting and removing along the straight one-dimensional direction Y. This guide 17 can be longer than the first fluid nozzle 12, or at least about the same length, for correct insertion of the nozzle 12 into the corresponding socket 14, as well as to avoid breakage or bending of the fitting 12 when it is inserted or removed. This makes it possible to manufacture fitting 12 from relatively cheap cast plastics.

In one embodiment, the fitting 13 of the second fluid contains a gas interface for controlling the pressure in the internal volume of the fluid cartridge 3. This gas may be ambient air. In another embodiment, the nipple 13 of the second fluid is configured to connect to the second nest-shaped interface 15 of the fluid, which in turn can be connected to the pressure package in the internal volume of the cartridge 3. The nipple 13 of the second fluid has an elongated shape. The fitting 13 of the second fluid has a truncated conical shape. The fitting 13 of the second fluid may be made of molded plastics. The guide 17 may be longer than the nozzle 13 of the second fluid, or at least about the same length, to properly insert the nozzle 13 of the second fluid into the corresponding interface 15 of the second fluid, as well as to avoid breaking or bending the nozzle 13 of the second fluid as you type or retrieve it. This makes it possible to manufacture fitting 13 from relatively cheap cast plastics.

Guide 17 and / or the corresponding guide interface restricts movement when inserting and removing the cartridge 3 and leads them to one-dimensional movement. This allows interfaces 12, 13 and 14, 15, respectively, to be relatively long and deep. The corresponding fittings 12, 13 may be at least 5 millimeters long or at least 10 millimeters long. The respective sockets 14, 15 may have a depth of at least about 3 millimeters or at least about 5 millimeters or about 10 millimeters.

In one embodiment, the receiving structure 4 comprises a connection circuit 18 for interconnecting the control circuit 8 of the fluid delivery device 2 and the cartridge electrical circuit 19. Figure 3 shows the back side of the chain 18 connection. Figure 4 shows a variant of the circuit 18 of the connection in the plane formed by the axes X and Z. The chain 18 of the connection contains the electrodes 20 of the connection. These electrodes 20 may extend along the line P approximately parallel to the Z axis, perpendicular to the straight line Y. When the cartridge is inserted or removed along the straight line Y, the cartridge electrical circuit 19 moves along the electrodes 20 until they are connected. The connection circuit 18 is arranged to be connected along the side with the electrical circuit 19 of the cartridge, i.e. in the direction B, transverse to the straight line Y. In the drawings, the transverse direction B is parallel to the X axis. continue one after another, as is evident from the direction of movement along a straight line Y. In the shown embodiment, the electrodes 20 are pins. The connection electrodes 20 are arranged to move in the transverse direction B. The electrodes 20 may contain elastic elements that are displaced in the direction of the electrical circuit 19 of the cartridge to provide an electrical connection. When you enter the cartridge 3, the electrodes 20 are pressed back by the electric circuit 19 of the cartridge. When inserting the cartridge, the connection electrodes 20 may slide along the cartridge electrical circuit 19 until the cartridge 3 is locked in the receiving structure 4 and the electrodes 20 do not make proper contact with the corresponding electrical circuit 19 of the cartridge. At the same time, for better electrical connection, the elastic elements press the electrodes 20 to the electrical circuit 19. When the cartridge 3 is again removed, the electrodes 20 are again pulled out to the outside by the action of the elastic force.

The fluid delivery device 2 may comprise at least two different receiving key interfaces 22. In one embodiment, each receiving structure 4 is equipped with one specific receiving key interface 22, which is different from other receiving key interfaces 22 of other receiving structures 4. Receiving key interface 22 Corresponds to a specific ink color, such as cyan, magenta, yellow, or black. In one embodiment, the fluid delivery device 2 comprises a specific receiving key interface 22 for each individual fluid cartridge 3. In one embodiment, the fluid delivery device 2 comprises four receiving structures 4 with four corresponding receiving key interfaces 22, each of which corresponds to a cartridge 3 for fluids of different colors having a corresponding key interface 24 of the cartridge.

The fluid delivery device 2 comprises receiving structures 4 having corresponding receiving key interfaces 22 configured to provide connection to the cartridge 3 with matching interfaces 24 and not allowing connection with fluid cartridges 3 which are equipped with inconsistent key interfaces 24 of the cartridge. For example, the first receiving key interface 22 comprises the first groove 23 or cutout. The matching first key interface 24 of the corresponding cartridge 3 contains the corresponding inverse groove 25 or cutout, which during input is not blocked by the first receiving key interface 22, but is blocked when inserted into other receiving structures with other receiving key interfaces 22. Similarly, other cartridges 3 have a second, third, fourth, and / or subsequent key interface 24 of the cartridge, which is inconsistent with the first receiving key interface 22. Others are the second, third, fourth, and ( Do) following receiving the key interfaces are not suitable first key interface 24. These key interfaces 22, 24 prevent the respective colors of ink cartridges 3 and 4 receiver designs do not match each other.

The key interface 22 of the receiving structure 4 may be located adjacent to the connection circuit 18. The corresponding key interface 24 of the cartridge 3 may be located near the electrical circuit 19 of the cartridge. If the key interfaces 22 and 24 match each other, then they can interlock the side elements in such a way that the chains 18 and 19 can be pressed before making contact. If the key interfaces 22 and 24 do not match, no electrical contact can be established. On the one hand, if the key interfaces do not match, no electrical contact is established between the connection circuit 18 and the electrical circuit 19 of the cartridge. On the other hand, proper electrical contact between connecting circuits 18 and 19 is facilitated by the respective key interfaces 22, 24 of the receiving structure 4 and cartridge 3, respectively.

The guide 17 is designed to guide the corresponding fluid cartridge 3 along a straight line Y. The guide 17 is configured to connect the corresponding guide interface of the cartridge 3, for example, the guide track 21. The guide 17 includes a rail that extends parallel to the axis Y. This guide 17 to provide correct axial alignment of the fittings 12, 13 with the corresponding sockets 14, 15 is longer than the fitting 13. This can guarantee a good interconnection without leakage, as well as prevent The deformation of the unions 12, 13. The guide 17 may include a T-shaped rail for entering the corresponding guide track 21 of the cartridge 3. This T-shaped rail prevents the cartridge 3 from turning relative to the straight line of movement Y, as well as relative to other X and Z axes.

The receiving structure 4 has a latch mechanism 26 for locking the cartridge 3. In the shown embodiment, the latch mechanism 26 includes a latch 27 designed so that between the locked and unlocked position it is guided by the corresponding latch 28 of the cartridge 3. The latch 27 can be located at the bottom receiving structure 4 for fixing the cartridge 3. The latch mechanism 26 may comprise a latch pin 29 and a pin shoulder 29B allowing the latch 27 to move between the locked and unlocked position by turning it ota axis L relative to the latch. In the drawing, the latch axis L is perpendicular to the straight line Y and parallel to the axis Z. In one embodiment, the latch 27 is rotated around the axis L of the latch, so that after removing the cartridge 3 to return to its original position, as well as to grip the corresponding walls of the latch 27.

In one embodiment, the latch 27 includes a pin. In the locked position, the latch 27 abuts against the corresponding latch 30 of the cartridge 3. In the unlocked position, the latch 27 is separated from the latch 30, so that the cartridge 3 can be removed from the receiving structure 4. The latch 27 can continue along the upper portion of the latch shoulder 29B. In the installed position of the cartridge 3, the latch 27 extends along the latch track 28, while the pin 29 and the shoulder 29B continue below the bottom of the cartridge 3. In the shown embodiment, the latch mechanism 26 includes latch edges 29C for limiting the movement of the latch 27. In one embodiment the edges 29C of the latch are adapted to engage with the shoulder 29B of the pin and restrict its movement. In the inserted position of the cartridge 3, the edges 29C of the latch continue under the cartridge 3.

The receiving structure 4 of the cartridge comprises an ejector 31. FIG. 3 shows the ejector 31 in an expanded state, after ejection or before inserting the cartridge 3. The ejector 31 is pressed in a direction parallel to the straight line Y. The ejector 31 may contain a spring or other elastic element, for example, made of rubber material. The spring may be a helical spring. When the cartridge 3 is inserted and locked, the front end 44 of the ejector 31 cooperates with the front surface 33 of the cartridge 3. In the embodiment shown, the central axis C2 of the spring coincides with the central axis C2 of the choke 13 of the second fluid. The fitting 13 of the second fluid continues inside the spring. This helical spring is attached to the base 32 of the nozzle 13 of the second fluid. The size of the ejector spring is such that, in the decompressed state of the helical spring (see FIG. 3), the cartridge 3 can be removed to the outside by hand.

The ejector 31 is designed to push the cartridge out of the receiving structure 4. In the installed and locked position, the cartridge 3 is held in the receiving structure 4 by the latch 27, while compressing the ejector 31. The latch 27 can be guided from the locked position to the unlocked position by further pushing the cartridge 3 along a straight line Y against the force of the compressed ejector 31, which will be explained below. In the locked position, the latch 27 releases the cartridge 3, and the ejector 31 expands so as to push the cartridge 3 along a straight line Y outwardly from the receiving structure 4.

Figures 5 and 6 illustrate an embodiment of the fluid cartridge 3 in a perspective view. FIG. 5 clearly shows the front surface 33, and FIG. 6 more clearly shows the bottom surface 35. In the illustrated embodiments, the fluid, electrical and key interfaces are located on the front surface 33. The guide interface, the latch track 28 and the latch stop 30 are located on the bottom surface 35

The fluid interfaces of the cartridge 3 comprise the first fluid interface of the cartridge for the first fluid and the second fluid interface of the cartridge for the second fluid. In one embodiment, the first fluid is a fluid or liquid used for printing, such as ink, and the second fluid is a gas, such as air. In the shown embodiment, the first and second fluid interfaces of the cartridge contain, respectively, the first and second slots 14, 15, made with the ability to receive fluid from the corresponding fittings 12, 13 and (or) to transfer it to them. The first port 14 may be connected to the interior of the cartridge 3. The second port 15 may be connected to a pressure package in the interior of the cartridge 3.

The depth of the respective sockets 14, 15 is approximately the same or shorter than the length of the guide 17 or the guide track 21, in order to receive the corresponding fitting 12, 13 after the cartridge 3 is engaged with the guide 17, to ensure a proper axial exhibition with the corresponding fittings 12, 13. The central axes C1, C2 of the sockets 14, 15 are parallel to the straight line Y. In the installed position of the cartridge 3, the central axes of C1, C2 of the sockets 14, 15 are approximately the same as the central axes C1, C2 of the corresponding fluid receiving interfaces 12, 13.

The cartridge 3 on the front surface may comprise an ejector alignment interface 36. In one embodiment, the ejector alignment interface 36 is located near and / or around one of the fluid interfaces of the cartridge 3, which in the shown embodiment is designed as slots 14, 15. In the shown embodiment, the ejector alignment interface 36 is located around the second slot 15 and It has the same central axis C2 with this second slot 15, and in the inserted position of the cartridge 3 has the same central axis C2 as the second fitting 13. In the example shown, the ejector alignment interface 36 enters the ring, for example, in the form of a rim or flange around the second slot 15, intended to enter the inner circumference of the front end 44 of the spring ejector 31, for axial alignment and to keep the ejector 31 in the correct position when inserting the cartridge 3.

The first seat 14 comprises an o-ring 37 for receiving the first fitting 12. This sealing ring 37 contains an elastic material, for example rubber material, for at least substantially smooth tight coverage of the first fluid fitting 12 in the connected position of this first fitting. As will be explained later, in the insertion and extraction steps, the fitting 12 is inserted inside the first slot 14 further in comparison with the position in which this fitting 12 is connected to be printed. Therefore, the sealing ring 37 is made with the possibility of admitting additional deformation so that it is possible to perform such an additional input of the first fitting 12. The internal diameter of the sealing ring 37 is such that it smoothly and tightly covers the first fitting 12, starting from a narrow section of the conical shape of fitting 12 to wider site. For example, choke 12 may have a smallest diameter of about 2.0, and a largest diameter along a conical configuration of about 2.3 millimeters. In other embodiments, choke 12 may have a smallest diameter of at least about 1.5 and (or), and the largest diameter along the conical configuration of this choke 12 may be about 3.5 millimeters or less. Similarly, other versions may have, respectively, even smaller and (or) even larger diameters.

The sealing ring 37 is designed to smoothly and tightly cover the first fitting 12 along a substantial part of the length of this fitting 12. In one embodiment, the inner diameter of the sealing ring 37 is approximately 1.2 millimeters. Depending on the diameter of the fitting 12, in other versions, the internal diameter of the sealing ring 37 may be between about 0.6 and about 3.0 millimeters. When the fitting 12 slips through the sealing ring 37, the inner diameter of the sealing ring 37 can increase while maintaining the characteristics of its smooth, tight circumference of the ring, for example, at least about 0.3 millimeter or, in another embodiment, at least about 0 , 6 millimeters, or, in another embodiment, at least about 1.6 millimeters. In the shown embodiment, the sealing ring 37 contains a tapered receiving hole 37B for axial exhibition of the first fitting 12 at the input stage. In the shown embodiment, the sealing ring 37 contains protrusions 37C, designed to prevent the sealing ring 37 from sticking to the opposite interacting surface, for example, when entering into a receiving structure and (or) during manufacture.

The cartridge 3 contains an electrical circuit 19 (see figure 3). In the shown embodiment, the electrical circuit 19 is recessed relative to the front surface 33, so that electrical contact with the connection circuit 18 is established only after other interfaces are connected. In one embodiment, this may prevent the printer from receiving electrical signals before the fluid interfaces 12, 14, 13, 15 are connected. Such electrical signals sometimes command the printer to turn on the print head 5 and / or cartridge 3, which may be prevented by some embodiments of the present disclosure.

The electrical circuit 19 of the cartridge is made with the possibility, being inserted into the receiving structure 4, connections on the side. In the connected position, the connection circuit 18, at least partially, continues inside the cartridge 3. The cartridge electrical circuit 19, for example, contains electrodes extending in one plane approximately perpendicular to the cartridge front surface 33 and parallel to the insertion direction and / or the plane formed by the axis Z and the Y axis. In one embodiment, in the installed position of the cartridge 3, the electrodes 38 of the electrical circuit 19 of the cartridge continue along the line PP, which is approximately parallel to the Z axis and / or the front top 33. The PP line extends beyond the front surface 33. The electrodes 38 of the electrical circuit 19 of the cartridge are designed to be connected with the corresponding electrodes 20 of the circuit 18 of the connection. Line PP, which continues through the electrodes 38 of the cartridge 3, is parallel to line P (see FIG. 4), which in the fixed position of the cartridge 3 continues through the electrodes 20 of the connection circuit 18. In the installed position, the connection circuit 18 at least partially extends through or beyond the front surface 33 of the cartridge 3 to connect to the electrical circuit 19 of the cartridge.

In one embodiment, the cartridge 3 includes a cartridge key interface 24 for eliminating connection with the receiving structure 4, which is equipped with a non-compliant key interface 22. In the shown embodiment, the cartridge key interface 24 includes a cutout 25. In other embodiments, the key cartridge interface 24 may include a protrusion and again, other designs may contain both. The key interface 24 of the cartridge is designed to block further entry of the cartridge 3, if the receiving key interface 22 does not fit, so that the electrical connection with the electrical circuit 19 of the cartridge is not established.

Key interfaces 22, 24 can be configured to provide additional alignment of the cartridge 3 relative to the receiving structure 4, in addition to the guide 17, for example, preventing rotation around the straight line of displacement Y. Also, if the key interfaces 22, 24 of the receiving structure 4 and cartridge match each other, the key interfaces 22, 23, due to their respective shape, can engage in such a way that the chains 18, 19 are interconnected properly.

In some embodiments, the cartridges 3 are not equipped with key interfaces 24, so that the cartridges 3 can fit any of the receiving structures 4 of the fluid delivery device 2 and the chains 18, 19 are interconnected independently of the receiving key interface 24.

The cartridge 3 comprises a guide interface for interacting with the guide 17 of the receiving structure 4. In the embodiment shown, the guide interface comprises a guide track 21. The guide interface is for guiding the cartridge 3 along a straight line Y for connecting the interfaces. The guide interface may have an interface with a guide that extends parallel to said straight line Y.

The guide track 21 is designed to interact with the guide 17. The guide track 21 is designed to guide the corresponding T-shaped rail guide 17. In the shown embodiment, the guide track 21 includes a T-shaped cutout. The guide track 21 includes flanges 39 for entry under the wings 17B (see FIG. 3) of a T-shaped lath guide 17. The guide lane 21 may include a tapering hole 40 to facilitate the reception of the T-shaped lath guide 17. Flanges 39 near the hole 40 can be beveled. The guide track 21 may further comprise a guide stop 45.

The bottom 35 of the cartridge 3 further comprises a latch track 28. The guide track 21 and the latch track 28 may be one common cut-out at the bottom 35 of the cartridge 3. The bottom 35 may be made of one-piece molded plastic.

The cartridge 3 includes a latch track 28 and a latch stop 30. The latch track 28 is configured to move the latch 27 relative to the latch stop 30. When the latch 27 engages the stop 30, the cartridge 3 is fixed. The position of the latch stop 30 can determine the position of the cartridge interfaces with respect to the interfaces of the receiving structure along the straight line Y.

The latch track 21 comprises a locking track 28A and an unlocking track 28B. The locking track 28A may be fully or partially different from the unlocking track 28B. The latch stop 30 is located between the locking track 28A and the unlocking lane 28B, so that the latch 27 is guided on one side 28A of the latch stop 30, and on the other side 28B during removal. When entering the latch 27 is guided by the locking track 28A. This locking path 28A may comprise a latch guide surface 46 of the stop 30 for guiding the latch 27 along the right side of the latch stop 30. The locking track 28A may further comprise a wall 47 of the guide latch at the end of this locking track 28A. The wall 47 of the guide latch is designed to receive the latch 27 at the end of the locking track 28A and the direction of the latch 27 to the stop 30 of the latch. The latch stop 30 includes a latch stop wall 49 and an abutment heel 50. The latch guide wall 47 is intended to guide the latch 27 to the engaged locking position with the latch stop wall 49 (see FIG. 13). The stop heel 50 includes a protrusion in the stop wall 49 to hold the latch 27 from slipping out of the latch stop wall 49. In the locked position, the latch 27 rests on the thrust heel 50. In the locked position, the ejector 31 is compressed and pushes the cartridge 3 so that the latch stop 30 is pressed against the latch 27.

In addition, the unlocking track 28B includes a latch redirecting wall 48. This latch redirecting wall 48 is designed to receive the latch 27 when the latch stop 30 and the latch track 28A are pushed inward, and to guide the latch 27 to the unlocking lane 28B to push the latch from the engagement position. When pushing out, the latch 27 extends along the opposite side of the latch rest 30 relative to the insertion side. The latch redirecting wall 48 may be located at the end of the latch track 28. When the latch 27 is in the open position, the ejector 31 pushes the cartridge 3 so that it can be removed by hand.

In one embodiment, the latch track 28 comprises an audio and (or) haptic feedback element. The latch 27 may have a rotational offset relative to the axis L of the pin. When the latch 27 moves along the latch track 28, it can slide along the walls of the latch track 28. The one or more latch track walls, for example, may contain one or more feedback elements, such as a plate, to create an audible and / or tactile feedback signal when the latch 27 moves along the latch track 28. These feedback elements can be located near the wall 47 of the guide latch, from where the latch 27 will move to the locking position if the cartridge 3 is released. When receiving an audible and / or tactile feedback signal, the user can know that cartridge 3 can be released and that it is locked in the receiving structure 4. Another feedback element can be located near the latch redirecting wall 48 to indicate unlocking the cartridge 3.

FIG. 7 shows a sectional view of a part of the fluid delivery system 1, where the fluid cartridge 3 and the receiving structure 4 are interconnected. The ejector 31 is compressed and presses the latch stop 30 to the latch 27. In addition, the cartridge 3 is held in place of the guide 17. The fittings 12, 13 extend deep inside the respective sockets 14, 15 and transfer the corresponding fluids between the cartridge 3 and the fluid delivery device 2.

The electrodes 20, 38, respectively, the circuit 18 connection and the electrical circuit 19 of the cartridge are interconnected on the side. For example, the electrodes 20, 38 are mutually connected along a line P or PP, which is parallel to the Z axis, and / or in a plane that is parallel to the plane formed by the Y axis and the Z axis. Since the electrical circuit 19 of the cartridge is recessed relative to the front surface 33 of the cartridge 3, This connection circuit 18 and the cartridge electrical circuit 19 are interconnected inside the outer circumference of the cartridge 3 behind the front surface 33. In the installed position, the connection circuit 18 continues at least partially inside the cartridge 3. In one embodiment, the connection The connection between the connection circuit 18 and the cartridge electrical circuit 19 is installed at the back and / or near the cartridge key interface 24 inside the cartridge 3.

In one embodiment, the cartridge 3 comprises at least one finger rest surface 51 to facilitate and indicate the position of the hand grip of the cartridge 3, for example, when inserting or removing the cartridge 3. The finger rest surface 51 may be a single concave curve or a combination of concave curves, one or more grooves, cuts, etc. This surface 51 of the finger rest can be made on the upper surface 53 of the cartridge near the rear surface 34. As illustrated in the shown embodiment, in the installed state of the cartridge 3, the receiving structure 4 strongly covers the surface 51 of the finger rest. After removing the surface 51 of the finger rest becomes visible and accessible to grip to remove the cartridge 3.

In one embodiment, the cartridge 3 comprises a finger pushing surface 52, which indicates that the cartridge 3 needs to be pushed into the receiving structure 4, both for locking and unlocking the cartridge 3. The finger pushing surface 52 may contain one concave curve or a concave combination curves, one or more grooves, cuts, etc. The finger pushing surface 52 is formed on the rear surface 34. In the installed state of the cartridge 3, the rear surface 34 and the surface 52 for pushing with a finger are visible outside the receiving structure 4. Although the surface 52 for pushing with a finger may have a predetermined position on the rear surface 34 This description is characterized by the fact that in order to properly connect the interfaces, the cartridge 3 can be pushed anywhere on the back surface 33, since the guide 17 can guide the cartridge 3 along straight Y line regardless of the specific location of pushing or tilting.

FIG. 8 shows in block diagram form an embodiment of the method for connecting the fluid cartridge 3 to the receiving structure 4. In the first step 800 of this method, the fluid cartridge 3 is inserted into the receiving structure 4. Its movement is limited and reduced to one-dimensional, i.e. , the cartridge 3 moves along a straight line Y, as indicated at step 810. At the end of the one-dimensional movement between the cartridge 3 and the fluid dispenser 2, a fluid message channel is formed. At step 820, the latch 27 is moved along a straight line Y to the locking position. The latch 27 holds the flow message channel. Steps 810 and 820 can be performed simultaneously. At step 830, fluid may flow through connected fluid interfaces, for example, to an outlet.

FIG. 9 shows, in block diagram form, the following embodiment of the method for connecting the fluid cartridge 3 to the receiving structure 4. FIGS. 10-15 illustrate the successive positions of the cartridge 3 relative to the latch mechanism 26, corresponding to some of steps 900-914 of FIG. 9 .

At step 900, the cartridge 3 is inserted manually into the receiving structure 4. FIG. 10 corresponds to step 900; it illustrates the position of the cartridge 3 relative to the receiving structure 4 and the latch mechanism 26. In the next step 901, the guide track 21 enters the guide 17. When the cartridge 3 is subsequently pushed into the receiving structure 4, the guide 17 guides the cartridge 3 along a straight line Y in the direction of the ejector 31. In the next step 902, the latch 27 enters the latch track 28. The latch 27, as shown in FIG. 11, is guided along the locking track 28A. The shoulder 29B of the pin rotates around the axis L of the pin (see FIG. 3), thereby allowing the latch 27 to be guided by the walls of the locking track 28A. At step 903, the ejector 31 contacts the front surface 33 of the cartridge and is compressed. The ejector 31 may enter the ring 36, which is made around the receptacle 15 of the second fitting. Mentioned steps 901-903 can be carried out simultaneously.

In the embodiment shown in FIGS. 9-15, the cartridge 3 and the receiving structure 4 have compatible key interfaces 22, 24. At step 904, fluid interfaces 12, 13, 14, 15 are interconnected, and key interfaces 22, 24 The receiving structure 4 and the cartridge 3 are compatible with each other. Compatible key interfaces 22, 24 allow interconnection of the electrical circuit 19 of the cartridge and the circuit 18 of the connection. After pairing the keys in step 905, an electrical connection is established between circuits 18 and 19. The control circuit 8 receives a corresponding signal that the electrical connection is established. The established electrical connection assumes that fluid channels are also created.

At step 906, the user pushes the cartridge 3 inward until it receives a tactile or audible feedback signal. For example, the latch 27 touches the end 47 of the latch track 28 and (or) the guide stops 45 engage with the end of the guide 17, and (or) the ejector 31 cannot be more compressed. On the corresponding figure 12, it is shown that the latch 27 touches the end of the latch track 28, in this embodiment the latch 27 touches the wall 47 of the guide latch so that when released, the latch 27 moves to the locking position. At step 907, the user manually removes the cartridge 3. At step 908, the ejector 31 expands, pushing the cartridge 3 backward until the latch 27 engages the stop 30 of the latch. As you can see on the corresponding Fig, latch 27 holds the cartridge 3, clinging to the wall 49 of the stop. The latch 27 itself is held in its position by the abutment heel 50. Steps 904 and 905 of the pairing of keys and electrical connection, as well as steps 906-908 of locking the latch, can occur approximately simultaneously.

If cartridge 3 was pushed in incorrectly, then the fluid interfaces and / or other interfaces could not connect as they should. In this case, the latch 27 could not reach the wall 47 of the guide latch and could not reach the locked position. Then the cartridge 3 will be automatically ejected by the ejector 31 before any electrical or liquid connections are made.

At step 909, the fluid delivery system 1 produces printing, consuming the first fluid from the cartridge 3 through the first fluid interfaces 12, 13. After printing, for example, when the cartridge is substantially empty, the cartridge may be pushed out for replacement. At step 910, the user pushes the cartridge 3 in the direction of the ejector 31. When the cartridge 3 is pressed, the latch 27 can reach the latch redirection wall 48. In the next step 911, the latch 27, for example, the latch redirection wall 48 (see FIG. 14), is guided to the unlocked position. In the open position, the cartridge 3 latch 27 is no longer held. At step 912, the user can remove the cartridge 3 by hand. At step 913, the ejector 31 expands, pushing the cartridge 3 (see FIG. 15). The pushing out became possible because the cartridge 3 is no longer held (see FIG. 15). At step 914, the user removes the cartridge 3 from the receiving structure 4.

As described above, the cartridge 3 may comprise a first fluid interface 12, a second fluid interface 13, an electrical interface 19, an ejector alignment interface 36 and / or a key interface 24 located on the front surface 33. The guide interface is located on the bottom surface 35 and has a receiving opening 40 near the front surface 33. Therefore, the interfaces are arranged so as to be interconnected near the front surface 33 of the cartridge 3. In the shown embodiment, the key element The interface 24 and the electrical interface 19 are located near the upper surface 53, the second fluid interface 15 and the ejector alignment interface 36 are located approximately in the middle of the front surface 33, and the first fluid interface 14 and the guide receiving hole 40 are located near the bottom surface 35. These interfaces are distributed over the front surface 33 is relatively uniform, thus ensuring a relatively uniform distribution of the forces of connection of the respective interfaces and a relatively low overall y Ilie compounds, e.g., about 14 Newtons or less. In the mechanisms of the latch and the guide system 1 for dispensing a fluid, there is no need for any deformation of the parts of the latch or the guide. To establish a reliable locking, a relatively easy and simple push is sufficient. In addition, to establish all connections in one direction, the Y guide 17 allows the user to push the cartridge 3 anywhere on the back surface 34.

The cartridge 3 and the receiving device 4 may be relatively thin, occupying only a small volume of the printer. The movement path of the cartridge also takes up relatively little space since it only goes in a straight line Y. Moreover, cartridge 3 can be released using the same pusher movement in the same Y direction. If cartridge 3 is, for example, along a fluid line or electrically connected not as it should, then the cartridge 3 by the ejector 31 is automatically ejected.

The above description is not intended to be exhaustive or to limit the present invention to the disclosed embodiments. As a result of studying the drawings, descriptions and appended claims, specialists in the field of the practical implementation of the claimed invention of the technique can be invented and implemented other changes to the disclosed embodiments. In some embodiments, mechanical inversions may be applied to the illustrated embodiments. For example, the latch track 28 may be provided on the receiving structure 4, and the latch mechanism 26 may be formed on the cartridge 3. The first and second fluid interfaces of the cartridge 3 may include unions, while the respective first and second fluid interfaces of the receiving structure 4 may contain nests.

The signs of the singular number do not exclude multiplicity, and the reference to a certain number of elements does not exclude the possibility of having a greater number of elements. A separate node can perform the functions of several positions mentioned in the description, and vice versa - several positions can perform the functions of a single node.

In the following claims, the fact that certain dimensions are indicated in interdependent different clauses does not mean that a combination of these dimensions cannot be used to obtain benefits. Numerous alternatives, equivalents, variations and combinations may be proposed without deviating from the scope of the present invention.

Claims (14)

1. Ink cartridge (3) for an inkjet printer (2), containing: the interfaces on the front surface (33) for connection to the receiving structure (4) for the cartridge, and these interfaces include a slot (14) for ink near the bottom surface (35) and a slot (15) for gas; guide interface for guiding the cartridge (3) along a straight line (Y) for connecting with the said interfaces, the guide interface located in the bottom surface (35) and has a guide receiving hole (40) located on the front surface (33) and the bottom surface ( 35); a latch stop (30) and a latch track (28) in the lower surface (35) for guiding and holding the latch (27) of the receiving structure (4) for the cartridge; and an electrical circuit (10, 19), which includes a memory (11) containing data with the characteristics of the cartridge, while the electrical circuit (10, 19) is located near the upper surface (53), which is opposite and parallel to the lower surface (35), and the electric circuit (10, 19) is located near the front surface (33), passes behind the front surface (33) and is recessed relative to the front surface (33) so as to establish electrical contact after the other interfaces are connected, with the electric circuit ( 10, 19 ) contains electrodes that extend in a plane (Y, Z) perpendicular to the front surface (33), and are located on a line (PP) parallel to the front surface (33) and located behind the front surface (33), the height of the ink cartridge (3) between the upper surface (53) and the lower surface (35) is greater than the width of the ink cartridge (3), the receiving opening (40) of the guide, the socket (14) for ink, the socket (15) for gas and the electric circuit (10, 19) are arranged in this order along a line in the direction of the height of the cartridge (3), and The electrical circuit (10, 19) is designed to establish a connection along the side (X, B) with the corresponding circuit (18) of the connection within the outer periphery of the cartridge (3). 2. The ink cartridge (3) of claim 1, wherein the interfaces on the front surface (33) comprise an ejector alignment interface (36) comprising an annular shoulder located near the middle portion of the front surface (33). 3. The ink cartridge (3) according to claim 2, wherein the annular collar is located around the nest (15) for gas in the front surface (33) and has the same central axis (C2) as the nest (15) for gas. 4. The ink cartridge (3) according to claim 1, wherein the ink slot (14) comprises an o-ring (37) for receiving a conical fitting of the receiving structure (4), and the o-ring (37) has an internal diameter that is expandable when inserted at least about 0.6 mm to cover and seal the nozzle along its conical shape. 5. The ink cartridge (3) according to claim 1, wherein the guide interface (17) comprises a guide track (21) which runs parallel to said straight line. 6. The ink cartridge (3) according to claim 5, wherein the guide track (21) comprises a T-shaped notch for guiding the corresponding T-shaped bar (17) of the receiving structure (3, 4) for the cartridge. 7. The ink cartridge (3) according to claim 5, wherein the guide track (21) and the latch track (28) are formed by one common cutout in the bottom surface (35) of the cartridge.

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