1. Field of the Invention
The present invention relates to a structure for storing an ink jet head for effecting recording by discharging recording liquid from a discharge port.
2. Related Background Art
Among conventional recording systems, since an ink jet recording system for effecting recording on a recording medium by discharging ink from a discharge port has less noise and can achieve a high speed recording operation with high density, such a system has widely been used recently.
A general recording apparatus having such a system includes an ink jet head for discharging the ink to form an image on the recording medium, and a conveying device for conveying the recording medium.
As the ink jet heads, there are an ink jet head in which an electrothermal converting element such as a piezo-element is provided in a nozzle communicated with a discharge port to discharge an ink droplet from the discharge port, an ink jet head in which an electrothermal converting element such as a heat generating resistance body and an ink jet head in which an electromagnetic wave (such as electric wave or laser)/mechanical converting element or an electromagnetic wave/thermal converting element is used. Among them, in an ink jet recording apparatus of type in which the ink droplet is discharged by utilizing thermal energy, since nozzles can be arranged with high density, recording having high resolving power can be achieved.
Particularly, in an ink jet head using the electrothermal converting element as a thermal energy generating element, compactness can easily be achieved in comparison with the ink jet head using an electrical/mechanical converting element, and, further, high density arrangement can easily be achieved with low cost by adequately utilizing merits of IC techniques and micro-working techniques, progress and reliability of which have been enhanced considerably in a recent semiconductor manufacturing field. A wiring substrate having base material of glass/epoxy for transmitting an electrical signal sent from a main body of the recording apparatus to a heater board provided in a converting portion of the converting element is adhered to the ink jet head. The heater board and the wiring substrate are interconnected by wire bonding. A contact pad contacted with and electrically connected to a flexible wiring substrate of the main body of the recording apparatus is provided on an upper surface of the wiring substrate.
In general ink jet heads, an ink amount required for the recording is stably supplied from an ink tank containing ink to nozzles. Further, in order to prevent leakage of ink through the discharge port, and more particularly, in order to maintain ink meniscus in the discharge port not to be broken, ink supplying pressure from the ink tank to the nozzles is adjusted to be negative pressure. As methods for adjusting the ink supplying pressure to be negative pressure, there are a method utilizing difference in water head from an ink introduction port of the ink tank directly containing the ink to the discharge port and method in which an ink absorbing body as a negative pressure generating member is disposed within the ink tank.
As methods for supplying the ink to the nozzles of the ink jet head, there are a method in which the ink is supplied to the nozzles by integrally or separately mounting the ink tank to the ink jet head on the carriage and a so-called tube supplying method in which the ink is supplied to the nozzles by connecting the ink jet head to the ink tank out of the carriage through a tube. In an ink jet printer consuming a large amount of ink, the ink tank must have a large capacity. In this case, if the ink tank having the large capacity is mounted on the carriage, since the ink jet printer itself becomes bulky, in such a printer, the tube supplying method is adopted.
In the ink jet head of tube supplying type, a buffer portion such as an ink reservoir, a filter or the like for storing the ink auxiliarily is provided between the ink tank and the head to prevent poor discharging and leakage of ink due to abrupt pressure change. Further, nozzles, ink storing space and ink introduction port which constitute an ink droplet discharging portion are also provided.
In such an ink jet head, if the nozzles are dried upon usage, when the ink is supplied into the nozzles, since ink wetting abilities of inner surfaces of the nozzles is changed, poor discharging may occur due to uneven wetting ability. To avoid this, when the head is transported, by filling the nozzles with ink not including color material (transparent ink not including color material), the head (interior of the nozzles) is maintained to a wetting condition. If the color material is included in the ink, when moisture which is main component of the ink is vaporized, the color material solved in the moisture is educed to clog the nozzles. The reason why the color material is not included in the ink not including the color material is that such clogging is prevented.
By the way, some ink jet heads of tube supplying type mounted on the carriage are designed so that air is housed in the ink storing portion containing the ink to be supplied to the nozzles. However, when the ink jet head of the type in which the air is housed in the ink storing portion is reserved, if inner pressure of the head is increased due to environmental change in a reserving step from the manufacture of the head to forwarding of the head or environmental change in a transporting step from the forwarding of the head to the transferring of the head to the user, the ink not including the color material may leak from the discharge ports of the nozzles or the ink introduction port.
Further, such leakage of the ink not including the color material may be further noticeable in dependence upon the posture of the head during the transportation.
In order to prevent the ink from leaking from the nozzles, it is considered that a tape or rubber sheet is directly adhered to the face surface to seal the nozzles. However, when the air is housed as mentioned above, pressure increase due to expansion of air becomes great, and, thus, in order to prevent the ink leakage, the tape or rubber sheet must be urged against the face surface with a considerably strong force. However, if the tape or rubber sheet is urged against the face surface with the strong force, the nozzles may be deformed. Further, foreign matters such as diry may be pinched between the tape or rubber sheet and the face surface to clog the nozzles, or adhesive of the tape may transfer to the face surface to change the ink wetting ability or damage the face surface.
In consideration of the above-mentioned problems, an object of the present invention is to provide a storing structure having high reliability, in which nozzles can be wetted positively and ink leakage and influence upon an electrical connection due to environmental change can be prevented and a face surface and the nozzles are not damaged.
To achieve the above object, according to a first aspect of the present invention, there is provided a storing structure for storing or reserving an ink jet head comprising a nozzle communicated with an opening for discharging liquid, a liquid storing portion for storing the liquid to be supplied to the nozzle, and a liquid introduction portion for introducing the liquid into the liquid storing portion from exterior, wherein, in the ink jet head, air is housed in the liquid storing portion and the liquid is contained at least in the nozzle, and a cap unit including an elastic cap for covering an area of the opening and a liquid absorbing member disposed in the elastic cap is closely contacted with and attached, around the opening, to a face in which the opening is formed, and the liquid introduction portion is communicated with atmosphere at least when inner pressure of the liquid storing portion is increased, thereby maintaining a space within the cap unit to a wetting condition.
Further, there is provided a storing structure for storing or reserving an ink jet head comprising a plurality of nozzles communicated with openings for discharging liquid, a plurality of liquid storing portions for storing the liquid to be supplied to the nozzles, and a plurality of liquid introduction portions for introducing the liquid into the liquid storing portions from exterior, wherein, in the ink jet head, air is housed in the liquid storing portions and the liquid is contained at least in the nozzles, and a cap unit including an elastic cap for covering an area of the openings and a liquid absorbing member disposed in the elastic cap is closely contacted with and attached, around the openings, to a face in which the openings are formed, and the liquid introduction portions are communicated with atmosphere at least when inner pressure of the liquid storing portions is increased, thereby maintaining a space within the cap unit to a wetting condition.
Further, the liquid introduction portion may comprise an elastic member in which a slit is formed.
Further, a communication pipe for communicating the interior of the ink jet head and the exterior of the ink jet head may be inserted into the liquid introduction portion.
Preferably, an insertion portion of the member to be inserted into the liquid introduction portion has a base end diameter greater than a tip end diameter.
Furthermore, preferably, the insertion portion is tapered to increase the diameter from the tip end to the base end.
The liquid contained in the nozzle may be ink not including color material.
The liquid contained in the nozzle may be ink.
The liquid is held by a capillary force of the nozzle.
A contact pad for electrically connecting the ink jet head to an ink jet printer may be provided on an outer surface of the ink jet head.
The liquid absorbing member in the cap unit attached to the ink jet head my not be contacted with the face in which the opening of the nozzle is formed.
The ink jet head in which the cap unit is attached to the face in which the opening of the nozzle is formed and an atmosphere releasing member is inserted into the liquid introduction portion and the liquid absorbing member is urged against an atmosphere release port of the atmosphere releasing member may be contained in a tray which may be in turn housed in a bag made of material low gas permeability.
The bag made of material low gas permeability may be aluminum bag.
In an ink jet head for effecting recording by discharging recording liquid from an opening of a nozzle, the cap unit detachable with respect to the face in which the opening of the nozzle is formed may comprise a protection member for protecting the face of the ink jet head in which the opening of the nozzle is formed, an elastic cap secured to the protection member and closely contacted with the face in which the opening of the nozzle is formed to cover a nozzle area, and a liquid absorbing member disposed within the elastic cap, and the elastic cap may be provided with an annular rib for closely contacting with outer periphery of the nozzle area to afford a closed space to the nozzle area.
Ink not including color material may be loaded in the liquid absorbing member, and the liquid absorbing member may not be contacted with the face in which the opening of the nozzle is formed in a condition that the cap unit is mounted to the ink jet head.
The protection member may be provided with a positioning portion capable of being positioned with respect to the ink jet head, and a clip-shaped engagement portion capable of being expanded and then hooked with respect to the ink jet head.
The present invention further provides a liquid filling method in a storage of an ink jet head comprising a nozzle communicated with an opening for discharging liquid, a liquid storing portion for storing the liquid to be supplied to the nozzle, and a liquid introduction portion for introducing the liquid into the liquid storing portion from exterior, comprising the steps of filling the liquid in the liquid storing portion, discharging the liquid within the liquid storing portion by sucking the liquid filled in the liquid storing portion from the opening for a predetermined time period, and attaching a cap unit to a face in which the opening is formed in a condition that the cap unit is closely contacted around the opening.
By adopting such a storing structure, in comparison with the conventional ink jet head in which the ink storing space is filled with the ink not including color material, since leakage of the ink not including color material caused by increase in inner pressure due to environmental change can be prevented and leakage of the ink not including color material caused in dependence upon the posture of the head can be prevented, an ink jet head having high reliability can be provided.
The present invention will now be explained in connection with preferred embodiments thereof with reference to the accompanying drawings.
First of all, an example of an ink jet recording apparatus having an ink jet head to which a head storing structure of the present invention is applied will be described.
The ink jet recording apparatus shown in
In
The ink jet head 201 has a plurality of nozzle arrays for discharging different color inks. In correspondence to the colors of inks discharged from the ink jet head 201, a plurality of discrete main tanks 204 are detachably mounted to an ink supply unit 205. The ink supply unit 205 is connected to the ink jet head 201 through a plurality of ink supplying tubes 206 corresponding to the ink colors so that, when the main tanks 204 are mounted to the ink supply unit 205, the respective color inks contained in the main tanks 204 can be supplied to the respective nozzle arrays independently.
Within a reciprocal shifting movement range of the ink jet head 201 and in a non-recording area out of a recording sheets passing area, a recovery unit 207 is disposed in a confronting relationship to the ink discharge face of the ink jet head 201.
Next, a detailed construction of an ink supplying system of the ink jet recording apparatus will be explained with reference to FIG. 2.
First of all, the ink jet head 201 will be described.
The ink is supplied to the ink jet head 201 through a connector insertion port 201a to which a liquid connector provided on a tip end of the ink supplying tube 206 is sealingly connected. The connector insertion port 201a is communicated with a sub-tank portion 201b formed in an upper part of the ink jet head 201. Below the sub-tank portion 201b in a gravitational direction, there is provided a liquid chamber 201f for directly supplying the ink to a nozzle portion having a plurality of nozzles 201g arranged in parallel. The sub-tank portion 201b and the liquid chamber 201f are defined by a filter 201c, and a partition portion 201e having an opening 201d is disposed at a boundary between the sub-tank portion 201b and the liquid chamber 201f, and the filter 201c is rested on the partition portion 201e.
With this arrangement, the ink supplied to the ink jet head 201 through the connector insertion port 201a is supplied to the nozzles 201g through the sub-tank portion 201b, filter 201c and liquid chamber 201f. An area from the connector insertion portion 201a to the nozzles 201g is sealed with respect to atmosphere.
An opening is formed in an upper surface of the sub-tank portion 201b and the opening is covered by a dome-shaped elastic member 201h. A volume of a space (pressure adjusting chamber 201i) enclosed by the elastic member 201h is changed in accordance with pressure in the sub-tank portion 201b so that the pressure in the sub-tank portion 201b is adjusted, as will be described later.
Each nozzle 201g has a cylindrical shape having a sectional width of about 20 μm. The ink is discharged from the nozzle 201g by applying discharge energy to the ink in the nozzle 201g, and, after the discharging, new ink is introduced into the nozzle 201g by a capilliary force of the nozzle 201g. In order to apply the discharge energy to the ink in the nozzle 201g, the ink jet head 201 has energy generating means for respective nozzles 201g. In the illustrated embodiment, heat generating resistance bodies for heating the ink in the nozzles 201g are used as the energy generating elements, and, by selectively driving the heat generating resistance bodies on the basis of command from a head control portion (not shown) for controlling the driving of the ink jet head 201, film boiling is caused in the ink in the desired nozzle 201g, and the ink is discharged from the desired nozzle 201g by utilizing pressure of a bubble generated by the film boiling.
Although each nozzle 201g is disposed so that a tip end thereof for discharging the ink is faced downwardly, a valve mechanism for closing the tip end is not provided, so that the ink fills the nozzle 201g with meniscus formed therein. To this end, interior of the ink jet head 201 and particularly interior of the nozzle is maintained to a negative pressure condition. However, when the negative pressure is too small, if foreign matters and the ink are adhered to the tip end of the nozzle 201g, the meniscus of the ink may be broken to leak the ink from the nozzle 201g. On the other hand, when the negative pressure is too great, a force for pulling the ink back into the nozzle 201g becomes greater than the energy applied to the ink during the discharging, thereby causing poor discharging. Thus, the negative pressure in the nozzle 201g is maintained to a predetermined range slightly smaller than the atmospheric pressure. The range of the negative pressure is varied with the number of nozzles 201g, a cross-sectional area of the nozzle, performance of the heat generating resistance body and the like.
In the illustrated embodiment, since the ink jet head 201 is connected to the ink supply unit 205 via the ink supplying tube 206 and the position of the ink jet head 201 with respect to the ink supply unit 205 can be set relatively freely, the ink jet head 201 is positioned at a location higher than the ink supply unit 205 in order to generate the negative pressure in the ink jet head 201.
The filter 201c is constituted by metal mesh having fine pores of 10 μm or less smaller than the sectional width of the nozzle 201g in order to prevent foreign matters which may clog the nozzles 201g from flowing from the sub-tank portion 201b to the liquid chamber 201f. The filter 201c has a feature that, when the ink is contacted with only one surface of the filter 201c, ink menisci are formed in the fine pores by a capilliary force to permit passage of ink but to make air flow difficult. The smaller the size of fine pore the stronger strength the meniscus to make the air flow further difficult.
In the filter 201c used in the illustrated embodiment, pressure required for permitting the air flow is about 0.1 atm (10.1325 kPa). Thus, if air exists in the liquid chamber 201f disposed at a downstream side of the filter 201c in the ink moving direction within the ink jet head 201, since the air cannot pass through the filter 201c by buoyancy of the air itself, the air in the liquid chamber 201f remains in the liquid chamber 201f. In the illustrated embodiment, this phenomenon is utilized. Namely, the liquid chamber 201f is not fully filled with air, but a layer of air is provided between the ink in the liquid chamber 201f and the filter 201c. That is, a predetermined amount of ink is stored in the liquid chamber 201f so that the ink in the liquid chamber 201f is spaced apart from the filter 201c by such an air layer. In the illustrated embodiment, by adopting a large liquid chamber in this way, there is provided a structure in which bubbles are easily trapped below the filter, so that the bubbles are hard to reach the nozzles and bubbles generated by the discharging are also apt to be shifted below the filter. With this arrangement, a head structure which is hard to be influenced by the bubbles as a main factor for causing unstable printing is provided.
Further, the ink in the partition portion below the filter is contacted with the filter so that, if the ink below the filter is expanded due to change in environmental temperature, such ink is shifted above the filter, thereby absorbing pressure. However, if an amount of the air below the filter is increased above a predetermined value, since the temperature change cannot be absorbed, suction is effected periodically to maintain the air amount below the filter to a given range.
The amount of the ink stored in the liquid chamber 201f is at least an amount required for filling the nozzles 201g with the ink. If the air from the liquid chamber 201f enters into the nozzle 201g, since the ink is not replenished into the nozzle 201g after the ink discharging thereby cause poor discharging, the nozzles 201g must always be filled with the ink.
The upper surface of the filter 201c is contacted with the ink in the sub-tank portion 201b, and an area contacted with the ink is an effective area of the filter 201c. Pressure loss across the filter 201c depends upon the effective area of the filter 201c. In the illustrated embodiment, the filter 201c is installed horizontally in a use condition of the ink jet head 201 so that the effective area of the filter is maximized by contacting the ink with the entire upper surface of the filter 201c, thereby reducing the pressure loss.
The pressure adjusting chamber 201i is a chamber a volume of which is reduced as inner negative pressure is increased, and, as is in the illustrated embodiment, when the pressure adjusting chamber 201i is constituted by the elastic member 201h, the elastic member 201h is preferably made of rubber material. Further, the chamber may be constituted by a combination of a plastic sheet and a spring, other than the elastic member 201h. By providing such a pressure adjusting chamber 201i, the ink discharging can be stabilized, and influence of pressure loss in the ink supply path from the main tanks 204 to the ink jet head 201 can be suppressed. Thus, diameters of the ink supplying tubes 206 moved together with the carriage 202 can be reduced, thereby reducing shifting burden of the carriage 202.
Next, the ink supply unit 205 and the main tanks 204 will be explained.
The main tanks 204 are detachable with respect to the ink supply unit 205, and each main tank is provided at its bottom with an ink supply port sealed by a rubber cock 204b, and an atmosphere introduction port sealed by a rubber cock 204c. Each main tank 204 is a single sealed container, and ink 209 is contained in the main tank 204 as it is.
On the other hand, the ink supply unit 205 has an ink supply needle 205a for picking up the ink 209 from each main tank 204, and an atmosphere introduction needle 205b for introducing the atmosphere into each main tank 204. The ink supply needle 205a and the atmosphere introduction needle 205b are both constituted by hollow needles and are disposed in a confronting relationship to the ink supply port and the atmosphere introduction port of the corresponding main tank 204 with needle tips thereof facing upwardly. When the main tank 204 is mounted to the ink supply unit 205, the ink supply needle 205a and the atmosphere introduction needle 205b penetrate into and pass through the rubber cocks 204b, 204c, respectively, thereby entering into the interior of the main tank 204.
The ink supply needle 205a is connected to the corresponding ink supplying tube 206 through a liquid path 205c. The atmosphere introduction needle 205b is communicated with the atmosphere through a liquid path 205e, a buffer chamber 205f and an atmosphere communication port 205g. A height of the liquid path 205c located at a lowest position in the ink supply path from the ink supply needle 205a to the ink supplying tube 206 is the same as a height of the liquid path 205e located at a lowest position in the ink supply path from the atmosphere introduction needle 205b to the atmosphere communication port 205g.
With the arrangement as mentioned above, when the ink in the ink jet head 210 is consumed, due to the negative pressure, the ink is supplied from the main tanks 204 to the ink jet head 201 through the ink supply unit 205 and the ink supplying tubes 206 at any time. In this case, the air having the same amount as the ink supplied from the main tanks 204 is introduced into the main tanks 204 from the atmosphere communication ports 205g through the buffer chambers 205f and the atmosphere introduction needles 205b.
Further, an outer appearance of the ink jet head 201 used in the above-mentioned ink supplying system is, for example, as shown in
Structure for Storing Head
Next, an ink jet head storing structure according to the present invention will be explained. Here, while an example that the above-mentioned ink jet head 201 is stored or reserved will be explained, the present invention is not limited to such an example but, the storing structure of the present invention can be applied to any head of ink jet type having a nozzle in which a discharge energy generating element is disposed and an ink storing portion connected to the nozzle.
(First Embodiment)
The recording head 201 according to this embodiment is designed to discharge the ink from six nozzle arrays, and the inks are supplied to the arrays of nozzles 201g independently from the respective main tanks 204 shown in FIG. 1 through the respective ink supplying tubes 206, sub-tanks 201b and liquid chambers 201f.
In
As shown in
Each rubber cap 212b is provided with an annular rib for closely contacting with the face surface of the ink jet head 201 around an area in which the plural discharge port arrays are formed. Thus, upper surfaces of the absorbing resins 212c are located below uppermost surfaces of the cap rubbers 212b. As a result, when the capping is effected, as shown in
The protection cap 212a is provided with a positioning guide 214 for a positioning boss (213 in
The cap unit 212 having the above-mentioned construction is positioned by the boss 213 as the positioning member provided on the ink jet head 201 and is detachably mounted to the ink jet head 201 by hooking the pawl portions 217, 218 of the clip portion 219 on the hook portions 215, 216 provided on the ink jet head 201 (FIG. 7).
Next, an ink filling amount in a transporting condition will be explained. In the head according to the illustrated embodiment, as shown in
Thus, in the present invention, when the head is transported, the ink filling amount is selected to a minimum ink amount capable of keeping the head to a saturated condition, i.e., an amount that only the nozzles are filled with the ink. Even if the ink is leaked from the nozzles, the leaked ink is absorbed by the absorbing resin in the closed cap. Concretely, the structure is as shown in
As shown in
Now, an operation when the inner pressure of the head is increased in this condition will be explained.
The sub-tank portion 201b above the filter is communicated with the slit 211a of the joint rubber 211. Although the slit 211a is normally closed, when the inner pressure of the head is increased, the slit is opened to release the pressure. When the filter is not impregnated by the ink, since the liquid chamber 201f is communicated with the sub-tank portion 201b, the pressure is released similarly. However, since the filter is apt to be wetted by the ink, it is considered that the filter becomes the ink impregnated condition. In this case, the ink not including color material in the nozzles may be dropped from the face surface due to the increase in the inner pressure.
In the illustrated embodiment, even if the ink not including color material in the nozzles is dropped from the face surface due to the increase in the inner pressure, since such ink is absorbed by the absorbing resin 212c, the ink is not leaked out of the head. Namely, since the nozzles and therearound are closely sealed to prevent ink leakage, a condition that the nozzles are positively filled with the ink or saturated water vapor is maintained. Further, since the ink is not leaked out of the cap, a bad influence is not affected upon the electrical connections. In addition, since the cap is not contacted with the nozzles, the nozzles are not damaged.
In this way, even in the structure in which the air exists within the ink jet head, an ink jet head having high reliability that the ink can be prevented from leaking outwardly even during the transportation can be provided.
Particularly, in the head in which the air is apt to be remained below the filter, since it is difficult to fill the space between the filter and the nozzles with the ink not including color material, the transporting style according to the illustrated embodiment is advantageous.
In the head in which the face surface is closely sealed in this way, normally, there is a predetermined gap between the head face surface and the absorbing resins 212c of the cap, because of tolerance in fitting portions in a positional relationship between the head 201 and the cap 212a. Upon designing the cap, in consideration of such tolerance, a squeezing amount of the tip end ribs of the cap rubbers 212b and the gap between the face surface and the absorbing resins 212c are determined. It is normal that the absorbing resins are not contacted with the face surface. The reason is that the face surface has normally water repellency, and if the absorbing resins are contacted with the face surface, the face surface is always immesered in the ink not including color material, with the result that the water repellency may be deteriorated. Further, in addition to danger of influence of elution from the absorbing resins 212c and adhesion of dirt to the face surface, there is a danger of damaging the face surface. Further, the cap rubbers 212b are provided with projections (212d in
Further, it is considered that a force for urging the cap 212 against the face surface is generated if the head is dropped or when the cap 212 is mounted. Even in such cases, it is required that the tip end ribs of the cap rubbers be prevented to be further squeezed to contact the absorbing resins 212c of the cap with the face surface.
For these reasons, it is desirable that the predetermined gap is always maintained between the head face surface and the absorbing resins 212c of the cap.
Now, a feature for always maintaining such a gap according to the illustrated embodiment will be explained.
As mentioned above, in the illustrated embodiment, since the positioning guide of the cap also acts to protect the head face surface, even if the force for urging the cap 212 against the face surface is generated if the head is dropped or when the cap 212 is mounted, the absorbing resins 212c of the cap are not contacted with the head face surface. Thus, the predetermined gap can always be maintained between the head face surface and the absorbing resins 212c of the cap, thereby providing a cap having high reliability in which the face surface is not damaged.
In place of the positioning guide 214 according to the illustrated embodiment, although it is considered that projections are provided on the cap at positions where the projections abut against the head face surface, since shock acts on the face surface, such projections are not preferable. Particularly, as is in the illustrated embodiment, in the cap of type in which the engagement is established by widening the cap, since there is a danger of rubbing the face surface by the projections, such projections are not more preferable.
By the way, since the face surface is capped, although the ink is not leaked out of the head, there is a danger of flowing the ink not including color material out of the nozzles due to shock upon dropping. Now, an embodiment for preventing ink dropping from the face surface is shown in
In this condition, when the cap is dismounted, the ink droplets 209a remain on the face surface. In such a condition, when the head is handled, the ink droplet 209a may be combined to form larger ink droplets which are in turn dropped from the face surface.
However, in the illustrated embodiment, regarding the face surface and the absorbing resins 212c of the cap, when the cap is dismounted, as shown in
As a result, since there is no large ink droplet after the cap is dismounted, when the head is handled, any ink droplet does not drop from the face surface.
Thus, in comparison with the conventional ink jet head in which the ink storing space is filled with the ink not including color material, even when the inner pressure of the head is increased, the ink not including color material is not leaked, and leakage of the ink not including color material due to the difference in posture of the head can also be prevented. Namely, an ink jet head in which high reliability is maintained even when the environment is changed during the storage can be provided. Further, a cap having high reliability can be obtained by combining with the construction in which the positioning guide of the cap also acts to protect the face surface as shown in
As shown in
Further, even if the closed space cannot be released to the atmosphere in dependence upon the posture of the head, the ink not including color material leaked by the inner pressure of the head is absorbed by the liquid absorbing member and held therein, and, since the cap unit is closely contacted around the discharge ports, the ink is not leaked from the head, thereby keeping the condition that the ink not including color material exists in the nozzles.
Next, the release cap 220 in which a base portion is greater than a tip end portion will be fully explained with reference to FIG. 13.
Since the tip end of the release cap is inserted into the joint rubber 211 in the connector insertion portion 201a as the ink introduction portion of the ink jet head 201, a diameter of the tip end must be equal to or smaller than that of the connector. To the contrary, since the base portion is located out of the joint rubber 211 in the connector insertion portion 201a, the base portion has a diameter greater than that of the tip end and has increased strength in a shearing direction. Further, when the release cap is tapered from the tip end to the base end, the positioning of the cap in the connector insertion portion is facilitated.
With this arrangement, for example, due to the dropping or vibration, even if any load is applied to the base portion by a friction force between the absorbing body 221 and the cap, the release cap 220 is not broken and can securely hold the ink jet head 201.
As shown in
As shown in
(Second Embodiment)
Next, a second embodiment of the present invention will be explained. However, only a difference with respect to the first embodiment will be described.
In the second embodiment, as shown in
The tray 222 containing the ink jet head 201 in this way is housed in an aluminium bag 223 and an opening portion of the bag is sealed by heat seal. In this case, aluminium is best since it has very low gas permeability. However, material of the bag is not limited to aluminium so long as material having low gas permeability is used. for example, a laminated film can be used. With an arrangement as mentioned above, in comparison with a conventional system in which absorbing resins immersed by ink not including color material is housed together with the head in an aluminium bag for preventing evaporation or a conventional system in which a cap member not contacted with the face surface is provided and absorbing resin for absorbing ink not including color material leaked from the nozzles is housed in the cap member, a condition that a large amount of ink is directly contacted with air in the bag is not established. Namely, in the conventional cases, dews were apt to be formed in the bag due to environmental change (temperature change) and the formed dews corroded electrical connection between the head and the main body of the recording apparatus and created short-circuit between the terminals. However, in the illustrated embodiment, such inconveniences can be avoided.
(Third Embodiment)
Next, different from the second embodiment, a storing structure for preventing the ink jet head 201 from being vibrated in the tray 224, according to a third embodiment of the present invention will be explained. However, only a difference with respect to the second embodiment will be described.
In the third embodiment, as shown in
The ink jet head 201 (refer to C portion 250 in
Further, both sides of the ink jet head 201 are held by head side holding portions 224c provided in the tray 224.
According to such a method, by securing the ink jet head 201 within the tray 224 in an inclined condition, the ink jet head can positively be secured in the tray having a tapered interior from bottom to top inherent to the molding technique.
Configurations, positions and/or number of the connector insertion port receiving portion 224, head abutment portion 224b and head side holding portions 224c in the illustrated embodiment may be changed from the illustrated ones so long as the same effect as that of the illustrated embodiment can be achieved.
The tray 224, containing the ink jet head 201 in this way is housed in an aluminium bag 223 and an opening portion of the bag is sealed by heat seal.
As mentioned above, according to the ink jet head storing structure of the present invention, when the ink not including color material is contained only in the nozzles of the ink jet head and the spaces in the head other than the nozzles are sealingly closed under the atmosphere of moisture of the ink not including color material, in comparison with the conventional ink jet head in which the ink storing space is filled with the ink not including color material, since leakage of the ink not including color material by the increase in the inner pressure of the head due to the environmental change does not occur and leakage of the ink not including color material due to difference in posture of the head can be prevented, an ink jet head having high reliability can be provided from the forwarding of the head to the receiving of the head by the user.
In order to sealingly close the spaces within the head under the atmosphere of moisture, the closed space may be given to the nozzle area by using the cap unit and the ink introduction portions of the head may be constituted by the slits. Furthermore, by housing the ink jet head on which the cap unit and the liquid absorbing bodies are mounted within the tray, shock to the ink jet head due to the dropping or vibration is suppressed.
Further, according to the cap unit of the present invention, since the liquid absorbing bosies in the cap unit are not contacted with the face surface in which the nozzle openings are formed, the nozzles of the ink jet head are not damaged and the wetting condition of nozzles can be maintained. Further, since the cap unit is provided with the positioning portion capable of being positioned with respect to the ink jet head, and the clip-shaped engagement portions capable of being once widened and then hooked on the ink jet head, the correct mounting and dismounting with respect to the head can be facilitated.
Further, according to the cap unit of the present invention, since the liquid absorbing bodies in the cap unit are not contacted with the face in which the nozzle openings are formed, the nozzles of the ink jet head are not damaged and the wetting condition of nozzles can be maintained. Even if the ink not including color material in the head is dropped from the face surface due to increase in inner pressure, since such ink is absorbed by the absorbing resins, the ink is not leaked out of the head, and the condition that the interior of the nozzles is filled with the ink or the saturated vapor is maintained. Further, since the ink is not leaked out of the cap, a bad influence is prevented from affecting upon the electrical connections.
Number | Date | Country | Kind |
---|---|---|---|
2001-048426 | Feb 2001 | JP | national |
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