EP1604828A1

EP1604828A1 - Printing head assembly comprising a movable closure member

Info

Publication number: EP1604828A1
Application number: EP04102664A
Authority: EP
Inventors: Rolandus Jacobus Nicolaas Van Der Horst
Original assignee: Korthofah BV
Current assignee: Korthofah BV
Priority date: 2004-06-11
Filing date: 2004-06-11
Publication date: 2005-12-14
Anticipated expiration: 2024-06-11
Also published as: ATE355974T1; WO2005120836A1; DE602004005167D1; EP1604828B1

Abstract

The invention relates to a printing head assembly (1) comprising a printing head with a front side having one or more nozzles, said printing head comprising fluid ejection means to eject fluid from said nozzles. The printing head assembly (1) further comprises a moveable closure member (10) facing said front side and arranged to expose said nozzles in an active state of said printing head assembly (1) and to hermetically seal said nozzles in an inactive state of said printing head assembly (1). The closure member (10) avoids drying of ink in the inactive state and clogging up of the nozzles. The invention further relates to a system comprising such a printing head assembly (1).

Description

The invention relates to a printing head assembly comprising a printing head with a front side having one or more nozzles, said printing head comprising fluid ejection means to eject fluid from said nozzles.
Nowadays, printing of characters is a common phenomenon. Such characters not only are printed on paper, but on a variety of products and enclosures of products. Information on enclosures and products becomes more and more obligatory for e.g. food manufacturers. The characters may e.g. be a use-by date of the product, a bar code, the manufacturer of the product or other valuable information for customers or intermediate parties in the distribution chain. This branch is known as coding and marking.
A commonly used printing system in the coding and marking branch involves an inkjet printing system. The inkjet printing system has a printing head with a plurality of channels from which ink droplets can be fired. The ink is supplied to channels in the printing head from an ink reservoir by capillary action. The ink in the channels can be ejected from nozzles at the front side of the printing head by controlling piezoelectric elements in these channels. The piezoelectric elements generate a pressure pulse in the ink in the channels on receipt of a control signal for each channel individually instructing a particular channel to eject an ink droplet. Subsequently, the capillary action refills the channel for a next droplet to be ejected. A printing head may comprise a plurality of channels, e.g. 64 channels up to 1000 channels.
A problem of such printers is that the nozzles at the front side of the printing head are exposed to air. Accordingly, the ink in the channels is exposed to air as well. For non-porous surfaces, such as plastic surfaces, typically these inks are alcohol based to enable sufficiently fast drying and adhesion of the ink to the non-porous surface to print characters. Consequently, during a state of printing inactivity, the ink also dries in the channels and nozzles such that the printing head channels may get clogged up after a certain time.
Typically, the way to solve this problem in the field of marking and coding of products for inkjet print heads is the spit-technique. This technique involves firing one or more ink droplets from all nozzles every now and then to avoid clogging up the channels of the print head. This spit-technique generally works well.
A problem of this spit-technique is that, although the channels in the printing head normally get not clogged up any more, the environment gets polluted and the use of expensive inks increases.
It is an object of the invention to solve at least one of these problems of the prior art spit-technique.
This object is achieved by providing a printing head assembly characterized in that said printing head assembly further comprises a moveable closure member facing said front side and arranged to expose said nozzles in an active state of said printing head assembly and to hermetically seal said nozzles in an inactive state of said printing head assembly.
The closure member avoids that the nozzles are exposed to air when the printing head assembly is not used, i.e. the inactive state. Therefore, fluid will not dry in the nozzles and the nozzles cannot get clogged up. Consequently there is no longer a need to apply the prior art spit-technique and fluid is no longer wasted. The fluid ejection means preferably comprise piezoelectric elements as typically used for inkjet print heads, but may also refer to heating elements as typically encountered in bubble jet printing heads. Further, it should be appreciated that the fluid preferably is ink.
In an embodiment of the invention, the printing head assembly further comprises a carriage holding said printing head and at least one shaft for moving said printing head between a first position associated with said active state and a second position associated with said inactive state. The movement of the carriage can be used to open the movable closure member in the active state and to close the closure member in the inactive state. Alternatively, the movable closure member may be moved otherwise, e.g. by electrically controlling the position of the closure member. Preferably air pressure means are provided for moving said carriage by air flow along said shaft to said first position. The shaft functions as a guide rod in this embodiment. The air pressure means are a simple yet effective means to control the motion of the carriage. More preferably, the air pressure means comprise throttle means to regulate said air flow. The throttle means provide for a gentle motion of the carriage avoiding shock waves in the ink channels of the print head. Otherwise unintended leakage of ink from the nozzles during the translation of the carriage might result.
In an embodiment of the invention the printing head assembly further comprises biasing means arranged to exert a force on said carriage substantially along said shaft in a direction towards said second position. Accordingly, a fail safe assembly is obtained, wherein the printing head assembly is forced in the inactive state by having the biasing means acting on the carriage with the printing head when power and/or air pressure fall away. The biasing means may comprise a spring.
In an embodiment of the invention, the carriage further comprises a printing head interface arrangement and said printing head comprises a first connector plug arranged to cooperate with a second connector plug of said printing head interface arrangement. Although the printing head may be connected directly to control means not deployed on the carriage, the connections between the printing head and the control means typically are fragile and therefore not suitable for an industrial environment. Accordingly, preferably at least a printing head interface arrangement is positioned on the carriage together with the print head, such that this printing head interface arrangement moves along with the print head, while the printing head and the printing head interface arrangement are connected by reliable plug connections. The printing head interface arrangement comprises more robust connectors to connect to control means via a flexible signal cable allowing motion of the carriage.
In an embodiment of the invention, the printing head assembly further comprises a housing and said closure member is pivotally arranged in said housing. Although the closure member may be movable in other ways to expose or hermitically seal the nozzles, such as translation or rolling it up, rotational motion of the closure member is preferred since such an embodiment combines simplicity and minimum space consumption in the housing. Preferably, the housing comprises a front plate with an opening and said closure member is pivotally attached to said front plate. The front plate provides for a robust printing head arrangement. Spacers are provided to enable rotation of said closure member within said housing. The spacers are preferred means to enable the accommodation of the closure member in the housing. Accordingly, the closure member is not present outside the housing and cannot be easily damaged. Adequate positioning of the closure member is relevant to maintain a state of hermetic sealing of the nozzles in the inactive state. Therefore damage of the closure member may result in decreased performance of the sealing function of the closure member.
In an embodiment of the invention, the printing head is arranged on a carriage movable along at least one shaft in an axial direction of the housing, said carriage comprising a first structure adapted to contact a second structure of said closure member to rotate said closure member when moving along said at least one shaft. Accordingly the translation of the carriage is used to rotate the closure member over the pivot point. Preferably the first structure of the carriage comprises a bearing member to enable smooth rotation of the closure member during translation of the carriage.
In an embodiment of the invention, the closure member comprises a base with a plastic top structure arranged to abut said front side of said printing head in said inactive state. The base, which is preferably metallic, supports the plastic top structure. The plastic top structure facilitates hermetic sealing of the nozzles as a result of the resilient nature of this structure. Preferably, the plastic top structure is arranged to abut a dummy area around the nozzles without abutting said nozzles. Consequently, the nozzles can be sealed by abutting the front side of the printing head without pushing dirt particles into the nozzles when the closure member abuts the front side of the printing head. The plastic structure may comprise a circular structure, such as an integral O-ring, to minimize contact forces to arrive at a state of hermetic sealing of the nozzles.
In an embodiment of the invention, the printing head assembly comprises a fluid supply tube, said fluid supply tube comprising a fluid filter. The filter serves to filter impurities or dirt particles from the ink as well as to avoid shock waves in the ink supply tube when translating the carriage.
It should be appreciated that the previous embodiments or aspects of the previous embodiments of the invention can be combined.
The invention further relates to a printing head assembly comprising a printing head with a front side having one or more nozzles, said printing head comprising fluid ejection means to eject fluid from said nozzles, said assembly further comprising a carriage holding said printing head and at least one shaft for moving said printing head between a first position associated with said active state and a second position associated with said inactive state, wherein said shaft is positioned substantially parallel to an axial direction of a housing of said printing head assembly, said housing comprising a front plate with an opening aligned with said nozzles such that, in said first position, said fluid can be ejected onto a product when said product is positioned in front of said opening.
The invention also relates to a system comprising a printing head assembly as described above, a fluid reservoir (preferably an ink reservoir) and, optionally, a control unit, said system (preferably the control unit) being adapted to receive detection signals from one or more detectors for detecting a product to eject said fluid on, said detectors being arranged to enable said detection signals to trigger said printing head assembly to expose said nozzles. As the exposure of the nozzles by the closure members of the printing head assembly may cause some delay before the active state is obtained, the printing head assembly should be triggered in time that the active state is required. Accordingly, the system provides detectors to warn the printing head assembly that a product is approaching. The detectors may e.g. be photo detectors. Preferably, the system comprises at least two detectors. One of these detectors is positioned to timely trigger the printing head assembly to expose the nozzles by removing the closure member, while the other is positioned at the printer head assembly to instruct the printing head to eject fluid such that the fluid is deposited on the correct position of the product. The detectors may be part of the system. Typically, such detectors are provided along a conveyor belt.
The invention will be further illustrated with reference to the attached drawings, which show a preferred embodiment according to the invention. It will be understood that the invention is not in any way restricted to this specific and preferred embodiment.
In the drawings:
Fig. 1 shows a schematical illustration of a printing head assembly in an inactive state according to an embodiment of the invention;
Fig. 2 shows a schematical illustration of a system comprising a printing head assembly in an active state according to an embodiment of the invention;
Fig. 3 shows a detailed view of a system comprising a printing head assembly according to an embodiment of the invention;
Fig. 4 shows a detailed three-dimensional view of a part of a printing head assembly according to an embodiment of the invention;
Figs. 5A-5D show a top view, a side view, a bottom vies and a view from the opposite side of the printing head assembly of Fig. 4, and
Figs. 6A-6C show a front view, a side view and a three dimensional view of a closure member according to an embodiment of the invention.
Fig. 1 shows a schematical illustration of a printing head assembly 1 in an inactive state according to an embodiment of the invention. The printing head assembly 1 comprises a printing head 2 with a front side 3 having a plurality of nozzles 4. As an example, the XJ128 printing head manufactured by XAAR can be used. The interior of the printing head 2 comprises a plurality of capillary channels 5 connected to nozzles 4 at the front side 3 of the printing head 2. The capillary channels 5 are provided with fluid ejection means 6, which preferably are piezoelectric elements, to generate a pressure pulse in the channel 5. Fluid, hereinafter referred to as ink, present in the channel 5 is ejected from a nozzle 4 as a result of the pressure pulse for that particular nozzle 4.
It is noted that for clarity purposes only a few nozzles 4 are shown. Typically the number of nozzles 4 ranges from 128 up to 1000. The enlarged portion of Fig. 1 shows an example of the arrangement of the nozzles 4. A dummy area 7 is present around the nozzles 4 on the front side 3 of the printing head 2.
The components of the printing head assembly 1 are provided in a housing 8. The housing 8 defines an axial direction indicated by the arrow A. The housing has a front plate 8A with an opening O to allow ejection of ink droplets from the printing head 2 onto a product and a dividing wall 9.
The printing head assembly 1 further comprises a moveable closure member 10 facing the front side 3 of the printing head 2 that is arranged to expose the nozzles 4 in an active state and to hermetically seal the nozzles 4 in an inactive state. Fig. 1 schematically shows the printing head assembly 1 in an inactive state, i.e. the closure member 10 hermetically seals the nozzles 4 such that the ink in the nozzles 4 and capillary channels 5 is not exposed to air. Accordingly, this ink cannot dry and the nozzles 4 do not get clogged up after a period of printing inactivity. Details for an embodiment of the closure member 10 are discussed with reference to Figs. 6A-6C.
The printing head assembly 1 further comprises a carriage 11 supporting the printing head 2. The carriage 11 is arranged on support members 12 such that it can be moved or translated along a shaft 13 between a first position associated with the active state wherein the nozzles 4 are exposed by the closure member 10 and a second position associated with the displayed inactive state. The housing 8 is configured to allow the translation of the carriage 11 by providing additional space. As an example, the translation of the carriage between the first and second position amounts to 20 mm.
Although the translation of the carriage 11 along the shaft 13 can be arranged in various ways, such as mechanically by e.g. providing the shaft with screw thread or electromagnetically by applying electromagnets, air flow induced motion of the carriage 11 is preferred. Air pressure means 14 are provided for moving the carriage 11 along the shaft 13 by air flow to the first position. The air supply inlets and tubes are shown in Fig. 3. Further throttle means 15, such as an air valve, are provided to regulate the air flow to allow smooth translation of the carriage 11 along the shaft 13. Consequently shock waves in the capillary channels 5 of the printing head 2 can be avoided. Otherwise unintended leakage of ink from the nozzles 4 during the translation of the carriage 11 might result.
The printing head assembly 1 further comprises biasing means 16 arranged to exert a force on the carriage 11 in a direction towards the second position. The biasing means comprises a spring of adequate properties adapted to return the carriage 11 along the shaft 13. The carriage 11 with the printing head 2 is forced in the second position by the spring 16, e.g. when power and/or air pressure fall away. In such a case, the nozzles 4 of the printing head 2 are hermetically sealed by the closure member 10.
The printing head assembly 1 further comprises a printing head interface arrangement 20 provided on the carriage 11 with the printing head 2. The printing head interface arrangement 20 may be an electronic module adapted to perform a variety of functions, such as signal transformation and generation of clock signals for the printing head 2. Further powering or control for other components of the printing head assembly 1 can be executed from the printing head interface arrangement 20, e.g. by controlling a valve of the air pressure means 14 to initiate translation of the carriage 11 to the first position.
The printing head 2 comprises a first plug connector 21 that is arranged to cooperate with a second plug connector 22 of the printing head interface arrangement 20 to transmit signals from a control unit 31 (see Fig. 2). The plug connectors 21, 22 guarantee reliable connection to the printing head 2. A signal transmission module 23 is provided off the carriage 11 behind wall 9 and connected to the printing head interface arrangement 20 by a flexible signal cable 24 to allow motion of the carriage 11.
It is noted that, for clarity reasons, Fig. 1 neither shows an ink reservoir nor shows an ink supply tube to transfer ink from the ink reservoir to the capillary channels 5. These are shown in Fig. 3.
Fig. 2 schematically shows a system 30 in top view comprising the printing head assembly 1 of Fig. 1 in an active state, a control unit 31 and an ink reservoir 32. The printing head assembly 1 and the ink reservoir 32 are together referred to as a coding unit. The system 30 further comprises an air supply unit 33 and photo detectors 34 and 35. The photo detectors 34, 35 are arranged along a conveyor belt 36 that transports products P to be coded by the printing head assembly 1 with an appropriate speed. The positions of the photo detectors 34, 35 enable them to perform the functions to be described next.
In operation, the system 30 functions as follows. A product P is transported by the conveyor belt 36 along the photo detector 34 that is positioned away from the printing head assembly 1. The product P particularly has a non-porous surface on which a coding pattern is to be applied.
Photo detector 34 generates a detection signal for the control unit 31, that subsequently instructs the printing head interface arrangement to control the air pressure means 14 to move the carriage 11 with the printing head 2 in the axial direction A of the housing 8 to the first position. Accordingly, the delay before the printing head assembly is ready to print, resulting from the translation of the printing head 2 along the shaft 13, is compensated for by the early detection of the product P by photo detector 34.
Subsequently, the photo detector 35, positioned at the stationary printing head assembly 1, detects the product 2 and generates a detection signal that is transmitted to the control unit 31. The control unit 31 generates a printing instruction for the printing head assembly 1, that now is in the first position wherein nozzles 4 are exposed by the closure member 10, to eject ink as to form an appropriate coding pattern on the product P. The product P subsequently moves further over the conveyor belt 36.
After the deposition of the coding pattern on the non-porous surface of the product P, the carriage 11 will usually not immediately return to the second position associated with the inactive state of the printing head assembly 1. Probably further products P will follow on the conveyor belt 36, making it unnecessary to immediately return to the inactive state. However, if after a certain time interval (which can be set) no further printing activity is required, the air pressure means 14 gets deactivated and the spring 16 makes the carriage 11 with the printing head 2 return to the second position resulting in closing the closure member 10 to hermetically seal the nozzles 4. The time interval is determined by environmental conditions, such as temperature and humidity, and the type of ink. As an example, for a specific type of ink at 20°C and average humidity, the time interval is 5 seconds. If the temperature rises, the interval gets shorter, whereas a higher humidity makes the time interval increase.
Fig. 3 shows a detailed view of a coding unit comprising a printing head assembly 1 and an ink reservoir 32. The printing head assembly 1 and the ink reservoir 32 are mechanically attached to each other by brackets 40. The ink reservoir 32 is appropriately positioned with respect to the nozzles 4 of the printing head assembly 1 to avoid spontaneous leakage of ink from the printing head 2.
Ink can be supplied to the ink reservoir 32 via supply inlet 41. The ink from the ink reservoir 32 is supplied to the printing head assembly 1 via supply tube 42. The printing head assembly 1 comprises a filter 43, provided in the housing 8 behind the wall 9, for filtering dirt particles from the ink before the ink reaches the printing head 2 and to avoid shock waves in the ink supply tube 42 when translating the carriage 11. On the front side of the wall 9, the supply tube 42 is coiled around one of the shafts 13, as more clearly shown in Fig. 5C.
Air supply tube 44 runs via the inkjet reservoir 32 directly to the printing head assembly 1 for the supply of air for the air pressure means 14. The air pressure means 14 comprises a valve that can be controlled from the printing head interface arrangement 20 as described above.
A further tube 45 is connected to the valve of the air pressure means 14 on one side and to a pressure reducing valve (not shown) on the side of the ink reservoir 32. The pressure reducing valves brings the air pressure from 5 to 1 bar. The air pressure can be fed to the ink reservoir 32 by means of an air switch (not shown).
The above mentioned arrangement of air tubes provides a advantageous way for priming the system. Priming involves the initiation of the printing process by supplying ink from the ink reservoir 32 to the printing head 2 up to the level where the ink is further transported in the printing head assembly 1 by the capillary action of the channels 5. Priming is typically applied in the coding and marking field for inkjet printers that do not possess nozzles that can be sealed or closed.
In the priming process of the invention, the ink reservoir 32 can be pressurized by opening the air switch.
Consequently, a pressure of 1 bar is present in the ink reservoir 32 that forces the ink to the printing head 2 via the ink supply tube 42. The ink is ejected from the nozzles 4. If all nozzles 4 eject ink the priming process can be finished. The arrangement is such that in the second position of the carriage 11 (the inactive state), air cannot be supplied to the ink reservoir 32 such that the priming operation cannot accidentally be performed if the closure member 10 seals the nozzles 4.
In summary, the fact that in an embodiment of the invention, air pressure is applied to translate the carriage 11 can be used simultaneously for the priming process.
Finally Fig. 3 shows a connector 50 to connect printing head assembly to the control unit 31.
Fig. 4 shows a front portion of the printing head assembly 1 according to an embodiment of the invention. Identical reference numerals indicate identical or corresponding features.
A spacer 60 is attached on one side to the front wall 8A and on the other side pivotally accommodating the closure member 10 in the housing 8. This closure member 10 is discussed in more detail with reference to Figs. 6A-6C. On one side of the spacers 60 a torsion spring 61 is provided to drive the closure member 10 to the closed position if the carriage 11 is moved to the second position.
The carriage 11 comprises a first structure having an upstanding plate 62 and a bearing member 63 that are adapted to cooperate with the closure member 10. If the carriage 11 is moved to the first position, the bearing member 63 interacts with the closure member 10 and pushes it away to expose the nozzles 4 by exerting a force exceeding the counteracting forces of e.g. the torsion spring 61 and the spring 16.
Finally, the printing head assembly 1 comprises alignment means 64 to control the position of the closure member 10 with respect to the printing head 2, since hermetic sealing of the nozzles 4 requires accurate positioning of the closure member 10.
Figs. 5A-5D respectively display a top view, a first side view, a bottom view and an opposite side view. Again, identical reference numerals indicate identical or corresponding features. Reference numeral 70 refers to a micro-switch. This switch signals when the carriage 11 with the printing head 2 is in the first position and accordingly may eject fluid from the nozzles 4.
Figs. 6A-6C show a front view, a side view and a three dimensional view of the closure member 10 according to an embodiment of the invention. The closure member in this embodiment has a height of 50 mm, a width of 20 mm and a thickness of 5 mm. The closure member 10 comprises a metallic base 100 having a recess to define a portion 101 around which said closure member 10 rotates to expose or seal the nozzles 4 and a second structure 102 to cooperated with the bearing member 63 on the carriage 11 to move the closure member 10.
On the base 100, a plastic top structure 110 is arranged to abut the front side 3 of the printing head 2 in the inactive state to hermetically seal the nozzles 4 from air. The plastic top structure 110 preferably is made from a material that does not deteriorate when in contact with ink. Such a material is e.g. EPDM-rubber. The plastic top structure 110 comprises a support plate 111 and an integrally formed plastic circular structure 112, such as an O-ring. A circular structure 112 reduces the force to seal the nozzles 4. The second structure 102 is dimensioned such that, when applied in the printing head assembly 1 as e.g. shown in Fig. 5A, it extends towards the front side 3 to a further extent than the upper surface of the O-ring 112. This is to ensure that in opening the closure member 10, the bearing member 63 abuts this second structure.
The O-ring 112 is integrally formed with the plastic support plate 111 to form the plastic top structure 110. The plastic top structure 110 may be glued in an appropriate position on the recessed portion of the metallic base 100. The O-ring 112 is arranged such that its surface abuts the dummy area 7 of the front side 3 of the printing head 2, as shown in Fig. 1, in the inactive state of the printing head assembly 1. Consequently, possibly present dirt particles are not pushed into the nozzles 4 of the printing head 2.

Claims

A printing head assembly (1) comprising a printing head (2) with a front side (3) having one or more nozzles (4), said printing head (2) comprising fluid ejection means (6) to eject fluid from said nozzles (4)
characterized in that
said printing head assembly (1) further comprises a moveable closure member (10) facing said front side (3) and arranged to expose said nozzles (4) in an active state of said printing head assembly (1) and to hermetically seal said nozzles (4) in an inactive state of said printing head assembly (1).
The printing head assembly (1) of claim 1, further comprising a carriage (11) holding said printing head (2) and at least one shaft (13) for moving said printing head (2) between a first position associated with said active state and a second position associated with said inactive state.
The printing head assembly (1) of claim 2, further comprising air pressure means (14) for moving said carriage (11) along said shaft (13) by air flow to said first position.
The printing head assembly (1) of claim 3, wherein said air pressure means (14) comprise throttle means (15) to regulate said air flow.
The printing head assembly (1) of one or more of the claims 2-4, further comprising biasing means (16) arranged to exert a force on said carriage (11) substantially in a direction towards said second position.
The printing head assembly (1) of one or more of the claims 2-5, wherein said carriage (11) further comprises a printing head interface arrangement (20) and said printing head (2) comprises a first connector plug (21) arranged to cooperate with a second connector plug (22) of said printing head interface arrangement (20).
The printing head assembly (1) of claim 6, further comprising a signal transmission module (23) attachable to a flexible signal cable (24), said flexible signal cable (24) being connectable to said printing head interface arrangement (20).
The printing head assembly (1) of one or more of the claims 2-7, wherein said shaft (13) is positioned substantially parallel to an axial direction (A) of a housing (8) of said printing head assembly (1), said housing (8) comprising a front plate (8A) with an opening (O) aligned with said nozzles (4) such that, in said first position, said fluid can be ejected onto a product (P) when positioned in front of said opening (O).
The printing head assembly (1) according to one or more of the preceding claims, wherein said assembly (1) further comprises a housing (8) and said closure member (10) is pivotally arranged in said housing (8).
The printing head assembly (1) of claim 9, wherein said housing (8) comprises a front plate (8A) with an opening (O) and said closure member (10) is pivotally attached to said front plate (8A).
The printing head assembly (1) of claim 10, wherein spacers (60) are provided to enable motion of said closure member (10) within said housing (8).
The printing head assembly (1) one or more of the claims 9-11, wherein said printing head (2) is arranged on a carriage (11) movable along at least one shaft (13) in an axial direction (A) of said housing (8), said carriage (11) comprising a first structure (62;63) adapted to contact a second structure (102) of said closure member (10) to rotate said closure member (10) when moving along said at least one shaft (13).
The printing head assembly (1) of claim 12, wherein said first structure comprises a bearing member (63).
The printing head assembly (1) according to one or more of the preceding claims, wherein said closure member (10) comprises a base (100) with a plastic top structure (110) arranged to abut said front side (3) of said printing head (2) in said inactive state.
The printing head assembly (1) of claim 14, wherein said front side (3) comprises said nozzles (4) surrounded by a dummy area (7) and said plastic top structure (110) is arranged to abut said dummy area (7) without abutting said nozzles (4).
The printing head assembly of claim 15, wherein said plastic top structure (110) comprises a circular structure (112).
The printing head assembly (1) according to one or more of the preceding claims, wherein said assembly (1) comprises a fluid supply tube (42), said fluid supply tube comprising a fluid filter (43).
A printing head assembly (1) comprising a printing head (2) with a front side (3) having one or more nozzles (4), said printing head (2) comprising fluid ejection means (6) to eject fluid from said nozzles (4), said assembly (1) further comprising a carriage (11) holding said printing head (2) and at least one shaft (13) for moving said printing head (2) between a first position associated with said active state and a second position associated with said inactive state, wherein said shaft (13) is positioned substantially parallel to an axial direction (A) of a housing (8) of said printing head assembly (1), said housing (8) comprising a front plate (8A) with an opening (O) aligned with said nozzles (4) such that, in said first position, said fluid can be ejected onto a product (P) when positioned in front of said opening (O).
A system (30) comprising a printing head assembly (1) according to one or more of the preceding claims, a fluid reservoir (32) and, optionally, a control unit (31), said system being adapted to receive detection signals from one or more detectors (34,35) for detecting a product (p) to eject said fluid on, said detectors (34,35) being arranged to enable said detection signals to trigger said printing head assembly (1) to expose said nozzles (4).