Patent Grant
11993086
An inkjet printer may record an image generally by discharging ink from a recorder at a recording medium, e.g., a recording sheet.
As illustrated in
As shown in
In particular, the ink tank body 30 mainly has a resin housing 52, a first film 53, and a second film 54. The resin housing 52 may be formed in injection molding. The first film 53 covers one side, e.g., a leftward side, of the resin housing 52. The second film 54 covers another side, e.g., a rightward side, of the resin housing 52. The resin housing 52 has a hollow recess having a plurality of inner compartments that form, for example, the ink reservoir chamber 31 and the buffer chamber 34. The inner recess has sideward openings, e.g., a leftward opening, which is open leftward, and a rightward opening, which is open rightward. The first film 53 covers the leftward opening by being, for example, adhered to the resin housing 52 and thereby form the ink reservoir chamber 31 in cooperation with the resin housing 52. The second film 54 covers the rightward opening by being, for example, adhered to the resin housing 52 and thereby form the buffer chamber 34 in cooperation with the resin housing 52. The ink inlet 33, the ink supplying section 35, the air communication section 36, and the leaked-ink flow path 55 are arranged in the resin housing 52.
The ink reservoir chamber 31 may store the ink to be supplied to the recorder 51. The ink inlet 33 is located above the ink reservoir chamber 31, and the ink may be poured into the ink reservoir chamber 31 through the ink inlet 33. The ink supplying section 35 is located above the ink reservoir chamber 31 and may supply the ink in the ink reservoir chamber 31 to the recorder 51. The air communication section 36 is located at a lower position in the ink tank body 30. The buffer chamber 34 connects the air communication section 36 and the ink reservoir chamber 31, and the air communication section 36 is continuous with the atmosphere. The leaked-ink flow path 55 is arranged on an outer surface of the ink tank body 30 and may guide the ink leaking out of the ink inlet 33 and the ink supplying section 35 to a predetermined position.
The first electrode member 61 and the second electrode member 62 extend from the outside of the ink tank body 30 into the inside of the ink reservoir chamber 31. The first electrode member 61 is arranged in the leaked-ink flow path 55, and the second electrode member 62 is arranged on the outside of the leaked-ink flow path 55. The first electrode member 61 and the second electrode member 62 form parts of an electrode-styled sensor. When the ink contacts both the first electrode member 61 and the second electrode member 62, the ink conducts electricity between the first electrode member 61 and the second electrode member 62, and the electrode-styled sensor may detect an amount of the ink in the ink reservoir chamber 31.
When, for example, the user supplies the ink in the ink reservoir chamber 31 through the ink inlet 33, the ink may leak from the ink inlet 33. For another example, when an ink supplying tube connected to ink supplying section 35 is damaged, the ink may leak outside the ink supplying tube. The leaked ink may flow downward along the leaked-ink flow path 55 and may be absorbed by an absorber, which is arranged outside the ink tank body 30; thereby, the ink may be prevented from flowing to other areas in the inkjet printer 1.
Meanwhile, the first electrode member 61 is arranged in the leaked-ink flow path 55, and, when the ink leaks in the circumstances as described above, the ink may adhere to remain on a surface of the first electrode member 61. Therefore, when the ink adheres to a surface of the second electrode member 62 simultaneously with the first electrode member 61, the ink may conduct electricity between the first electrode member 61 and the second electrode member 62, and the sensor may erroneously detect the adhered ink as the ink remaining substantially in the ink reservoir chamber 31.
The present disclosure is advantageous in that an ink tank and an inkjet printer, in which at least a part of the problems described above is overcome, are provided.
In the paragraphs below, on one hand, detailed description of embodiments may help a reader to understand the present disclosure. On the other hand, in order to avoid confusion of the embodiments of the present disclosure with the known configurations, description of the configurations that may be easily understood by those with ordinary skills in the art may be herein omitted.
In the following paragraphs, the embodiments of the present disclosure will be described with reference to the accompanying drawings. In the description below, terms related to positions or directions such as “up,” “down,” etc. may not necessarily limit the scope of the present disclosure. Moreover, ordinal numbers assigned to some items in the embodiment below, such as “first,” “second,” etc., are used merely in a purpose to distinguish them clearly from one another in the context and may not necessarily imply specific meanings, such as order or significance. Furthermore, for example, terms such as “first member” may not necessarily imply presence of “second member”, or “second member” may not necessarily imply presence of “first member.”
Below described will be an inkjet printer according to the embodiments of the present disclosure. The inkjet printer according to the embodiments of the present disclosure has a printing function and may be in a generally similar configuration to the above-mentioned known inkjet printer 1. Optionally, the inkjet printer according to the present disclosure may have multiple functions, including an image scanning function, a facsimile transmission/receiving function, and a copying function, additionally to the printing function. The printing function may include a double-side printing function, by which images may be recorded on both sides of a recording sheet.
As shown in
The printer body 102 has a substantially rectangular parallelepiped form. In the printer body 102, a feeder device for feeding recording sheets and an ejection device for ejecting the sheets are arranged (not shown). Inside the printer body 102, a recorder 151 having, for example, a plurality of nozzles is arranged, and the recorder 151 may discharge ink at the recording sheet being fed from the feeder device. On a front side of the printer body 102, optionally, an operation panel may be arranged. The operation panel may have a display member, through which various types of information and settings may be displayed, and operation keys, through which operations and setting information may be entered. Optionally, the operation panel may not have the display member but may have the operation keys alone. The operation keys may not necessarily be located on the front side but may optionally be located on, for example, an upper side of the printer body 102.
The printer body 102 of the inkjet printer 100 has a housing 150. The inkjet printer 100 has four (4) ink tanks 110, which are arranged inside the housing 150. One of the ink tanks 110 is located in a leftward-front area in the printer body 102 and may contain ink in black. The other three (3) ink tanks 110 are located in a rightward-front area in the printer body 102 and may contain colored inks in cyan, magenta, and yellow, in this given order from left to right. Thereby, the inkjet printer 100 may record multicolored images in the combined inks in the four colors of black, cyan, magenta, and yellow. However, the number of the ink tanks 110 may not necessarily be limited to four but may be other number than four. Optionally, the ink tanks 110 may be arranged at different positions in the printer body 102. Moreover, optionally, the ink tanks 110 may be inseparably attached to the printer body 102 or may be detachably attached to the printer body 102.
Some items of the ink tank 110 according to the first embodiment may be in a substantially similar configuration to the known ink tank 10 mentioned above. Those items will be referred to by similar reference signs, in which lower two digits may be the same as those in the known ink tank 10.
As shown in
The ink reservoir chamber 131 may store the ink to be supplied to the recorder 151. The ink inlet 133 is continuous with the ink reservoir chamber 131, and the ink may be poured into the ink reservoir chamber 131 through the ink inlet 133. The ink supplying section 135 is continuous with the ink reservoir chamber 131 and is located on a first surface 191 of the ink tank body 130. Through the ink supplying section 135, the ink in the ink reservoir chamber 131 may be supplied to the recorder 151. The ink inlet 133 is located at a position higher than the first surface 191 and frontward with respect to the ink supplying section 135. The air communication section 136 is located at a lower position in the ink tank body 130. The buffer chamber 134 connects the air communication section 136 and the ink reservoir chamber 131, and the air communication section 136 is continuous with the outside atmosphere.
As shown in
More specifically, the first surface 191 is located to be higher than the second surface 192, an upper end of the connecting surface 193 is connected with the first surface 191, and a lower end of the connecting surface 193 is connected with the second surface 192. In the present embodiment, the first surface 191, the second surface 192, and the connecting surface 193 are plane surfaces.
When the inkjet printer 100 is in a usable condition, the first surface 191 is located frontward with respect to the second surface 192, the first surface 191 and the second surface 192 are horizontal planes, and the connecting surface 193 is a vertical plane.
A part of the first surface 191, a part of the connecting surface 193, and a part of the second surface 192, which are located between the first restrictive side wall 137 and the second restrictive side wall 138, the first restrictive side wall 137, and the second restrictive side wall 138 form the leaked-ink flow path 155. In other words, the leaked-ink flow path 155 is formed at least of a part of the first surface 191, a part of the connecting surface 193, and a part of the second surface 192, which are located between the first restrictive side wall 137 and the second restrictive side wall 138, the first restrictive side wall 137, and the second restrictive side wall 138. The leaked-ink flow path 155 may guide the ink leaked out of the ink inlet 133 and the ink supplying section 135 to a predetermined position.
The first electrode member 161 is arranged on the second surface 192 and extends from the outside of the ink tank body 130 into the inside of the ink reservoir chamber 131. The first electrode member 161 is located in the leaked-ink flow path 155. The second electrode member 162 is arranged on the second surface 192 and extends from the outside of the ink tank body 130 into the inside of the ink reservoir chamber 131. The second electrode member 162 is located apart from the first electrode member 161 and is located on the outside of the leaked-ink flow path 155.
In the present embodiment, for avoiding erroneous detection of the ink, the ink tank body 130 has a restrictive section 194 on the second surface 192. The restrictive section 194 is located between the first restrictive side wall 137 and the second restrictive side wall 138. Moreover, the restrictive section 194 is at least partly located between the connecting surface 193 and the first electrode member 161. Therefore, the ink splashing on the leaked-ink flow path 155 may be restrained from reaching the first electrode member 161 and may be restrained from adhering to the first electrode member 161.
It is preferable that the restrictive section 194 is separated from at least one of the first restrictive side wall 137 and the second restrictive side wall 138 by a gap. In the present embodiment, the restrictive section 194 has a form of a plate extending along the vertical direction. The restrictive section 194 is separated from the first restrictive side wall 137 on the rightward side and from the second restrictive side wall 138 on the leftward side. In this arrangement, the ink in the leaked-ink flow path 155 may flow downward through a gap between a rightward edge of the restrictive section 194 and the first restrictive side wall 137 and a gap between a leftward edge of the restrictive section 194 and the second restrictive side wall 138 to a predetermined position. Moreover, the restrictive section 194 is closer than the first electrode member 161 to the first restrictive side wall 137 and is closer than the first electrode member 161 to the second restrictive side wall 138.
It is preferable that a position of an upper end of the restrictive section 194 is higher than an upper end of the first electrode member 161 and is higher than the first surface 191.
Referring back to
The first wall 158 may restrict the ink in the leaked-ink flow path 155 from flowing outside the leaked-ink flow path 155. Moreover, in cooperation with the restrictive section 194, the first wall 158 may restrict the ink in the leaked-ink flow path 155 from splashing onto the first electrode member 161.
The ink tank body 130 may further have a first cover section 156 and a second cover section 157 on the second surface 192. The first cover section 156 is arranged to surround an outer circumference of the first electrode member 161. An upper end of the first cover section 156 is lower than the upper end of the first electrode member 161. In this arrangement, the ink in the leaked-ink flow path 155 may be restrained from adhering to the first electrode member 161. The second cover section 157 is arranged to surround an outer circumference of the second electrode member 162. An upper end of the second cover section 157 is lower than an upper end of the second electrode member 162. In this arrangement, the ink leaked out of the ink inlet 133 and the ink supplying section 135 may be restrained from adhering to the second electrode member 162. Preferably, the upper end of the first cover section 156 may be located to be higher than the upper end of the second cover section 157.
Below will be described an ink tank 210 according to a second embodiment. As shown in
In particular, the ink tank 210 includes, similarly to the ink tank 110 in the first embodiment, an ink tank body 230, a first electrode member 261, and a second electrode member 262. The ink tank body 230 includes, similarly to the ink tank 110, a resin housing 252, a first film 253, and a second film 254. The first film 253 together with the resin housing 252 forms an ink reservoir chamber 231, similarly to the first film 153. The second film 254 together with the resin housing 252 forms a buffer chamber 234, similarly to the second film 54. An ink inlet 233, an ink supplying section 235, an air communication section 236, and a leaked-ink flow path 255, a first cover section 256, and a second cover section 257 are arranged in the resin housing 252, similarly to those in the resin housing 152. The leaked-ink flow path 255 is formed at least of a first restrictive side wall 237, a second restrictive side wall 238, a first surface 291, a second surface 292, and a connecting surface 293.
As shown in
According to the ink tank 210 of the second embodiment, with the restrictive section 294 arranged on the second surface, at least a part of the restrictive section 294 is located between the connecting surface 293 and the first electrode member 261; therefore, the ink flowing in the leaked-ink flow path 255 may be restrained from splashing onto the first electrode member 261 and from adhering to the first electrode member 261. Thus, erroneous detection of the amount of the ink in the ink reservoir chamber 231 may be avoided.
Below described will be an ink tank 310 according to the third embodiment. As shown in
In particular, the first surface 391 is located to be higher than the second surface 392, an upper end of the connecting surface 393 is connected with the first surface 391, and a lower end of the connecting surface 393 is connected with the second surface 292. In the present embodiment, the first surface 391, the second surface 392, and the connecting surface 393 are plane surfaces.
When the inkjet printer 100 is in a usable condition, the first surface 391 is located frontward with respect to the second surface 392, the first surface 391 and the second surface 392 are horizontal planes, and the connecting surface 393 is a vertical plane.
The first surface 391, the connecting surface 393, and the second surface 392, which are located between the first restrictive side wall 337 and the second restrictive side wall 338, the first restrictive side wall 337, and the second restrictive side wall 338 form a leaked-ink flow path 355. The leaked-ink flow path 355 may guide the ink leaked out of the ink inlet 333 and the ink supplying section 335 to a predetermined position.
The first electrode member 361 is arranged on the second surface 392 and extends from the outside of the ink tank body 330 into the inside of the ink reservoir chamber 331. The second electrode member 362 is arranged on the second surface 392 and extends from the outside of the ink tank body 330 into the inside of the ink reservoir chamber 331.
The second electrode member 362 is separated from the first electrode member 361, and the second electrode member 362 and the first electrode member 361 are located outside the leaked-ink flow path 355. Therefore, the ink in the leaked-ink flow path 355 may be restrained from splashing onto the first electrode member 361 or the second electrode member 362. Moreover, the ink leaked out of the ink inlet 333 and the ink supplying section 335 may be restrained from adhering to the first electrode member 361 or the second electrode member 362. In this arrangement, erroneous detection of the amount of the ink in the ink reservoir chamber 331 may be avoided. In particular, a minimum distance L5 between the first electrode member 361 and the first restrictive side wall 337 is shorter than a minimum distance L6 between the second electrode member 362 and the first restrictive side wall 337. A minimum distance L7 between the first electrode member 361 and the connecting surface 393 is equal to a minimum distance L8 between the second electrode member 362 and the connecting surface 393.
The ink tank body 330 may further have a restrictive section 394. In the present embodiment, the restrictive section 394 has a form of a plate extending along the vertical direction. A lower end of the restrictive section 394 is connected with the second surface 392, and a frontward end of the restrictive section 394 is connected with the connecting surface 393. The restrictive section 394 is located between the first electrode member 361 and the second electrode member 362. In this arrangement, the first electrode member 361 and the second electrode member 362 are separated, and the ink leaked out of the ink inlet 333 and the ink supplying section 335 may be restrained from splashing onto the second electrode member 362. It is preferable that an upper end of the restrictive section 394 is located to be higher than a position of the upper end of the first restrictive side wall 337, and the upper end of the restrictive section 394 is located to be higher than a position of an upper end of the second restrictive side wall 338.
The ink tank body 330 may further have a first cover section 356 and a second cover section 357 on the second surface 392. The first cover section 356 is arranged to surround an outer circumference of the first electrode member 361. An upper end of the first cover section 356 is lower than the upper end of the first electrode member 361. In this arrangement, the ink leaked out of the ink inlet 333 and the ink supplying section 335 may be restrained from adhering to the first electrode member 361.
The second cover section 357 is arranged to surround an outer circumference of the second electrode member 362. An upper end of the second cover section 357 is lower than an upper end of the second electrode member 362. In this arrangement, the ink leaked out of the ink inlet 333 and the ink supplying section 335 may be restrained from adhering to the second electrode member 362. It is preferable that the upper end of the first cover section 356 is located to be higher than the upper end of the second cover section 357.
Below described will be an ink tank 410 according to a fourth embodiment. As shown in
In particular, the ink tank 410 includes, similarly to the ink tank 310, an ink tank body 430, a first electrode member 461, and a second electrode member 462. The ink tank body 430 includes, similarly to the ink tank 310, a resin housing 452, a first film 453, and a second film 454. The first film 453 together with the resin housing 452 forms an ink reservoir chamber 431, similarly to the first film 353. The second film 454 together with the resin housing 452 forms a buffer chamber 434, similarly to the second film 354. An ink inlet 433, an ink supplying section 435, an air communication section 436, and a leaked-ink flow path 455, a first cover section 456, and a second cover section 457 are arranged in the resin housing 452, similarly to those in the resin housing 352. The leaked-ink flow path 455 is formed at least of a first restrictive side wall 437, a second restrictive side wall 438, a first surface 491, a second surface 492, and a connecting surface 493.
The ink tank 410 may be different from the ink tank 310 in that a lower end of the restrictive section 494 is connected with the second surface 492, and a leftward end of the restrictive section 494 is connected with the first restrictive side wall 437. In this arrangement, the first electrode member 461 and the second electrode member 462 are separated from each other. A minimum distance L9 between the first electrode member 461 and the first restrictive side wall 437 is equal to a minimum distance L10 between the second electrode member 462 and the first restrictive side wall 437. A minimum distance L11 between the first electrode member 461 and the connecting surface 493 is shorter than a minimum distance L12 between the second electrode member 462 and the connecting surface 493.
According to the ink tank 410 of the fourth embodiment, with the first electrode member 461 and the second electrode member 462 being arranged outside the leaked-ink flow path 455, the ink in the leaked-ink flow path 455 may be restrained from splashing onto the first electrode member 461 or the second electrode member 462 and from adhering to the first electrode member 461 or the second electrode member 462. Thus, erroneous detection of the amount of the ink in the ink reservoir chamber may be avoided.
Unless otherwise noted, the technical terms used in this description should fall in a same range as those usually understood by a person with ordinary skills in the technical field of the present disclosure. The terms used in this description are merely used to explain specific embodiments and are not intended to limit the present invention. For example, a term such as “arranged” may represent a state of an item being coupled directly to another item and a state of an item being coupled to another item indirectly through an intermediate item. The features described in one embodiment in the description may be applied to another embodiment alone or in combination with other features.
While the invention has been described in conjunction with various example structures outlined above and illustrated in the figures, various alternatives, modifications, variations, improvements, and/or substantial equivalents, whether known or that may be presently unforeseen, may become apparent to those having at least ordinary skill in the art. Accordingly, the example embodiments of the disclosure, as set forth above, are intended to be illustrative of the invention, and not limiting the invention. Various changes may be made without departing from the spirit and scope of the disclosure. Therefore, the disclosure is intended to embrace all known or later developed alternatives, modifications, variations, improvements, and/or substantial equivalents.
| Number | Date | Country | Kind |
|---|---|---|---|
| 202020133436.9 | Jan 2020 | CN | national |
| 202020133797.3 | Jan 2020 | CN | national |
This is a Continuation application of International Application No. PCT/JP2021/001618 filed on Jan. 19, 2021, which claims priority from Chinese Utility Model Applications Nos. 202020133797.3 and 202020133436.9, both filed on Jan. 20, 2020. The entire contents of the prior applications are incorporated herein by reference.
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| Number | Date | Country | |
|---|---|---|---|
| 20220339942 A1 | Oct 2022 | US |
| Number | Date | Country | |
|---|---|---|---|
| Parent | PCT/JP2021/001618 | Jan 2021 | US |
| Child | 17812222 | US |
