JPH02520A - Ink jet recorder - Google Patents

Abstract

PURPOSE:To perform stable and effective supply of ink to an ink passage by operating a pump operating at a first ink passage and a valve provided at a second ink passage. CONSTITUTION:A first ink tank 102 is pressurized by a pressure pump 101 in a state that a valve 106 is opened and a valve 109 is closed thereby to supply ink to an ink jet head 104 through a first ink passage 103. When the pressurization is stopped in a state that the ink passage to a second ink tank 107 through an ink jet head 104 and a second ink passage 105 communicates with the ink and the valve 109 is opened, the inks of the tanks 102, 107 become equal at the levels through ink pipes 108, 110. When the head 104 discharges the ink, the valves 106, 109 are opened to supply the ink from the first, second passages to the head 104 by means of capillary force.

Description

[Detailed description of the invention] [Industrial application field] The present invention relates to an inkjet recording device.

[Prior art]

Among the various recording methods currently known, the non-impact recording method generates almost no noise during recording, is capable of high-speed recording, and does not require special fixing treatment on plain paper. The so-called inkjet recording method that allows recording is an extremely useful method for realizing printing devices such as various printers and word processors. Regarding this inkjet recording method, various methods have been proposed so far, some have been improved and commercialized, and others are still being worked on to put them into practical use. .

The inkjet recording method uses small droplets of recording liquid (referred to as ink in the following explanation).
) is made to fly using various principles of operation, and recording is performed by attaching it to a recording material such as paper. The ink droplet generating device used in such an inkjet recording method, that is,
An inkjet recording apparatus generally includes an inkjet head for forming ink droplets and an ink supply system for supplying the ink to the inkjet head.

This ink supply system is described in Japanese Patent Application Laid-Open No. 55-12107.
There are two types: a type that constantly circulates and supplies ink as described in Publication No. 4, and a type that constantly supplies ink from a single ink introduction tube as described in Japanese Patent Application Laid-Open No. 55-128465. be done.

[Problem to be Solved 1] By the way, the first form of the above-mentioned inkjet head generally has 1 to 10 ink ejection ports,
There are so-called single-type or semi-multi-type ink supply systems, but since the ink supply systems for these types of heads have few ink ejection ports and low ink consumption, they are not compatible with cartridge-type tanks or single ink supply vibrators. It can be configured relatively easily using .

However, the ink supply system for another type of full-line inkjet head, generally called a full-line multi-type, which is used for the purpose of printing one line of paper almost simultaneously, has an extremely large number of ink ejection ports, and the entire head The amount of ink consumed in this case is also incomparably higher than in the case of tilting, so a large number of ink supply vibrators are required, and a large-capacity tank is required, making the structure complicated and large. This was inconvenient.

On the other hand, as mentioned above, conventional ink supply systems constantly supply ink in a specific direction.
The constant circulation supply type has the disadvantage that it is difficult to stably supply ink in response to various changes in recording by liquid ejection. This problem does not apply to the type of head that performs recording by scanning the head. This has become a significant problem when recording with possible fixed heads.

Therefore, the present invention focuses on the problem of stable supply during recording caused by constant circulation, and provides an ink supply method for an inkjet recording apparatus that is free from problems related to ink supply and can achieve an ink condition suitable for recording. The researchers recognized this as a technical issue.

[Object of the Invention] Therefore, an object of the present invention is to solve the drawbacks of the prior art of slanting. In other words, an object of the present invention is to eliminate inconveniences caused by the configuration of the ink supply system in an inkjet recording apparatus, and to enable nearly perfect formation of ink droplets from all ink ejection ports in a manner faithful to human power. An object of the present invention is to provide an inkjet recording device that can stably supply ink for a long time to an inkjet head of an inkjet recording device.

[Summary of the invention]

The inkjet recording apparatus of the present invention that achieves such objects includes: an ink supply source that receives ink from an ink replenishment tank; a first ink flow path from the ink supply source to the inkjet head; a second ink flow path that is independent from the ink supply source and extends from the inkjet head; a valve provided in the second ink flow path; and when the valve is in an open state, 1 ink flow path, the inkjet head, and the second ink flow path, and the valve is closed and driven to discharge ink from the ink discharge port of the inkjet head. and when the valve is in an open state and ink is supplied from both the first ink flow path and the second ink flow path to the inkjet head, the first ink flow path and the second ink flow path are connected to each other. and a pump that is stopped to apply capillary force to the ink.

In the present invention, two independent ink flow paths are formed from an ink supply source to a head, and a first ink flow path and a second ink flow path are formed.
With a simple configuration consisting of a pump that acts on the ink flow path side and a valve installed on the second ink flow path side, just by operating these, you can create the above-mentioned ink flow, discharge the ink from the ejection port, and also control the independent ink flow during recording. 1 ink flow path, 2nd
Since stable and reliable ink supply to both ink channels can be achieved, excellent inkjet recording can be achieved stably over a long period of time.

In this way, the independent 1st. Since the above-mentioned operation can be performed with a simple configuration of the second ink flow path, there is no need to provide any additional structure for performing the above-mentioned operation, and the compactness of the apparatus can be improved.

In particular, the present invention can exhibit particularly excellent effects when applied to a full-line type inkjet recording apparatus.

[Example J Hereinafter, the present invention will be explained in detail with reference to the drawings.

FIG. 1 is a block diagram outlining an embodiment of the invention.

In this FIG. 1, 101 is a pressure pump, 102, 10
7 is an ink tank constituting an ink supply source; 103 is an ink vibrator as a first ink flow path; 105 is an ink vibrator as a second ink flow path; 108 and 110 are ink vibes; 104 is a multi-nozzle inkjet head;
106 and 109 are valves, and 111 is an ink replenishment tank. Initial supply of ink to the inkjet head 104 is performed as follows. That is, with the valve 106 open and the valve 109 closed, the pressure pump 1
A first ink tank 10 constituting an ink supply source at 01
2, the ink is transferred from the first ink tank 102 to the ink vibrator 10 as the first ink flow path.
3 and is supplied to the inkjet head 104. The ink tank 102 is pressurized by the inkjet head 104.
The air in the ink vibrator 105 is discharged, and an ink supply source is configured from the first ink tank 102 through the ink vibrator 103 as a first ink flow path, the inkjet head 104, and the ink vibe 105 as a second ink flow path. This process is continued until the ink path leading to the second ink tank 107 is communicated with ink.

As described above, when pressurization is stopped and the valve 109 is opened with the ink path communicating with the ink, the first ink tank 102 and the second ink tank 107 are connected to the ink vibrator 1.
Through 08 and 110, the ink levels of the first ink tank 102 and the second ink tank 107, that is, the ink supply source become equal.

Ink is supplied as follows when the inkjet head 104 is discharging ink.

That is, by opening the valves 106 and 109, ink flows from the first ink tank 102 of the ink supply source through the ink vibrator 103 as the first ink flow path, and from the second ink tank 107. Through the ink vibrator 105 as the second ink flow path, two independent ink flow paths are formed by capillary force.
The ink is supplied to the inkjet head 104 from the ink vibrator of the book.

Ink tanks 102 and 10 forming an ink supply source
To replenish ink to the second ink tank 10, open the valve 109 and open the ink replenishment tank 111.
By refilling the ink tank 7 at a constant level, it is possible to replenish the first ink tank 102 and the second ink tank 107 with ink at the same level.

Note that if air bubbles are mixed in the inkjet head 104 and a stable ejection state cannot be obtained, the valve 109 is closed and the first ink tank 102 is pressurized by the pressurizing pump 101, and the first ink flow path is closed.

Air bubbles can be easily removed by forming an ink flow in the order of the inkjet head and the second ink flow path.

Also, if the inkjet nozzle tip is clogged, please check the valve 10.
6 and 109 and pressurizing the first ink tank 102 with a pressurizing pump lot. FIG.

In FIG. 2, 201 is an ink tank body serving as an ink supply source, and two ink chambers 202,
It is divided into 203 parts. Ink chambers 202 and 203
The ink chambers are communicated with each other through a communication pipe 204 provided with an open hole in the lower part of the ink chamber, and a valve 205 is attached to the communication pipe 204.

The ink tank body 201 also has ink passage holes 210 and 210' provided with openings 208 and 208' at the bottom of the ink chamber 202, and ink passage holes 210 and 210' provided with openings 208 and 208' at the bottom of the ink chamber 203.
Ink conducting holes 211 and 211' with diameters 09 and 2o9'' are provided, and ink conducting holes 210, 21
0'211.211' has a valve 212°2, respectively.
12', 213.213' are attached.

The ink chamber 202 has an opening 240 at the top,
Pressure pump 20 via pressure pump joint 206
7 can be connected. 215 is a grooved plate, which is provided with ink conduction grooves 218, 218'219, 219' and an ink replenishment opening 237;
218'219.219' is the ink tank body 20
Ink conduction holes 210, 210'211.
Through hole 216216', 2 at the position corresponding to 211'
17 and 217' are provided, respectively. 214 is a backing for bringing the ink tank body 201 into close contact with the grooved plate, and has through holes (not shown) at positions corresponding to the ink passage holes 210, 210', 211, and 211' provided in the ink tank body 201, respectively. A hole is provided, and an ink replenishment opening 2 of the grooved plate 215 is provided.
An opening (not shown) is provided at a position corresponding to 37.

221 is the upper lid of the ink tank body 201 which is an ink supply source, and the ink conduction groove 218 provided in the grooved plate 215
, 218', 219, 219' have through holes 222, 222', 223, 22 at positions corresponding to the left end in the drawing, respectively.
3' is provided, and furthermore, an ink replenishment opening 236 is provided.
Also provided. 220 is a grooved plate 215 and a top cover 221
This is a backing for tightly adhering the through holes 222, 222', 223, 223 provided in the upper lid 221.
' and a through hole and an opening (both not shown) corresponding to the ink replenishment opening 236 are provided.

224 is an ink relay device, and an ink relay chamber 227227'
, 228, 228', and through holes 222, 222', 223, and 223' provided in the upper JI 221,
They communicate through ink conducting holes 225, 225', 226, and 226', respectively.

Ink tank body 201, backing 214, grooved plate 2
15, the backing 220, the top lid 221, and the ink relay 224 are each crimped and integrated by screwing or the like. In addition, the ink tank body 201. Grooved plate 215,
The upper lid 221 can also be integrated by joining, in which case.

The backings 214 and 220 are not necessary, 233 and 233' are multi-nozzle inkjet heads, and the ink relay chamber 227 is connected to the ink vibrator 231, 232 and 231', 232', join) 229, 230 and 229', 230', respectively. ，
228, 227', and 228'.

234 is an ink replenishment tank, and an ink injection device 235 is used to replenish ink at a constant level into the ink chamber 203 through the upper lid 221, grooved plate 237, and ink replenishment holes 236 and 237 in the backing 214 and 220. The replenishment tank 234 is detachable from the ink tank main body 201 and can be replaced as necessary.

When filling the multi-nozzle inkjet head 233 with ink, the valves 212 and 213 are opened and the pressure pump 207 is used to fill the ink chamber 2, which constitutes the ink supply source.
By pressurizing 02, the valve 205 attached to the communication pipe 204 closes, and the ink flows through the ink passage hole 210, the through hole 216, and the ink passage groove 2 as the first ink flow path.
18, a through hole 222, an ink passage hole 225, an ink relay chamber 227, a joint 229, and an ink pipe 231. After filling the multi-nozzle inkjet head 233, the ink vibrator 232 serves as a second ink flow path that is independent of the first ink flow path.
, joint 230. The ink flows into the ink chamber 203 through a flow path composed of the ink relay chamber 228, the ink conduction hole 226, the through hole 223, the ink conduction groove 219, the through hole 217, and the ink conduction hole 211, and flows from the ink chamber 202 into the multi-nozzle inkjet head. Pressure is applied until the ink flow path leading to the ink chamber 203 constituting the ink supply source via the ink chamber 233 is filled with ink.

When the pressurization of the ink chamber 202 is stopped, the valve 205 attached to the communication pipe 204 is opened, and the ink chambers 202 and 203 are opened.
The ink chambers 202 and 203 .
That is, the ink levels of the ink supply sources become equal. When ink is ejected from the multi-nozzle inkjet head 233 in this state, the ink flows from the ink chamber 202 to the ink conduction groove 218, the ink relay chamber 227, and the ink vibrator 23.
1 and the ink chamber 203 to the ink passage hole 219, the ink relay chamber 228, and the ink vibrator 2.
The multi-nozzle inkjet head 23 is formed by capillary force through two independent flow paths of the second ink flow path passing through the
3.

Similarly, when filling the other multi-nozzle inkjet head 233' with ink, the valve 212
' and 213' are opened and the pressure pump 107 pressurizes the ink chamber 202 constituting the ink supply source, thereby closing the valve 205 attached to the communication pipe 204, and the ink is passed through as the first ink flow path. A multi-nozzle inkjet passes through a flow path composed of a hole 210', a through hole 216, an ink conduction groove 218', a through hole 222'', an ink conduction hole 225', an ink relay chamber 227', a joint 229', and an ink vibrator 231'. The head 233' is filled.

After filling the multi-nozzle inkjet head 233', the ink passes through the ink vibrator 23 as a second ink flow path.
2', joint 230', ink relay chamber 228', ink passage hole 226', through hole 223', ink passage hole 2
19', a through hole 217', and an ink passage hole 211'.
Pressure is applied until the ink flow path from 02 to the ink chamber 203 via the multi-nozzle inkjet head 233' is filled with ink.

When the pressurization of the ink chamber 202 is stopped, the valve 205 attached to the communication pipe 204 is opened, and the ink chambers 202 and 20 are opened.
3 communicate with each other, the ink chambers 202 and 203
That is, the ink levels of the ink supply sources become equal. In this state, when ink is ejected from the multi-nozzle inkjet head 233', the ink flows from the ink chamber 202 to the first ink flow path via the ink conduction groove 218', the ink relay chamber 227', and the ink vibrator 231'. From the chamber 203 to the ink passage hole 219' and the ink relay chamber 228'
The ink is supplied to the multi-nozzle inkjet head 233' by capillary force through two independent ink channels, including the second ink channel, which passes through the ink vibrator 232'. In the diagonal embodiment, the ink chamber 2 is connected to the ink chamber 202 via the multi-nozzle inkjet head 233 or 233'.
03, but in the present invention, the number of pipes that supply ink to the multi-nozzle inkjet head is further increased (however, the device structure It is also possible to supply ink to a plurality of multi-nozzle inkjet heads simultaneously in one operation.

If air bubbles are mixed into the multi-nozzle inkjet head 223, 233' and stable ejection cannot be achieved, remove the air bubbles by circulating the ink in the same manner as when filling the multi-nozzle inkjet head with ink. can be easily removed. In addition, if the tip of the inkjet nozzle becomes clogged, the valve 213,
It is also possible to release the clogging by closing the ink chamber 213' and pressurizing the ink chamber 202 with a pressure pump.

[Effects of the Invention] The present invention forms two independent first ink flow paths and a second ink flow path from an ink supply source to a head.
With a simple configuration consisting of a pump that acts on the ink flow path side and a valve installed on the second ink flow path side, just by operating these, you can create the above-mentioned ink flow, discharge the ink from the ejection port, and also control the independent ink flow during recording. 1 ink flow path, 2nd
Since stable and reliable ink supply to both ink channels can be achieved, excellent inkjet recording can be achieved stably over a long period of time. In this way, the above-mentioned action can be performed with a simple structure of independent first and second ink flow paths, and there is no need to provide any additional structure to perform the above-mentioned action, resulting in a compact device. j can be calculated.

In particular, the present invention can exhibit particularly excellent effects when applied to a full-line type inkjet recording apparatus.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing the concept of the ink supply method for the inkjet recording apparatus of the present invention, and FIG.
FIG. 2 is an exploded view illustrating an inkjet recording device that embodies the Toban Kojiken Toad. In the figure, 101.207...pressure pump 102. 103゜231' 104゜106゜213゜111゜202゜208゜210゜225゜214゜216゜107...Ink tank 105.108,110,231゜232.232'...Ink vibe 233.233
'...Multi-nozzle inkjet head 109.205,212,212'213'...Valve 234...Ink replenishment tank 77...
Ink tank body 203... Ink chamber... Communication hole... Pressure pump joint 208' 209, 209', 240... Opening hole 210', 211, 211'225' 226, 226'...・Ink conduction hole 220...Backing...Grooved plate 216', 217, 217' 222, 222'218.218' 227, 227" 229, 229' 223, 223'...Through hole 219.219 '...Ink conduction groove...Ink relay 228.228'...Ink relay chamber 230.230'...Joint...Ink injection device. Manual retail correction installation (spontaneous) 1982 December 12, 2015, 5, the specification to be amended 6 and the full text of the specification to be amended are amended as attached.Relationship with the name and address of the person making the amendment Patent applicant 3-3O-2 Shimomaruko, Ota-ku, Tokyo (100) Ryu Kaku, Representative of Canon Co., Ltd.

Claims (2)

[Claims] (1) an ink supply source that receives ink from an ink replenishment tank; a first ink flow path from the ink supply source to the inkjet head; a second ink flow path leading to the inkjet head; a valve provided in the second ink flow path; and when the valve is in an open state, the flow from the ink supply source to the first ink flow path, the inkjet head, and the first ink flow path is opened. The valve is driven to form an ink flow in the order of the two ink flow paths and the valve is closed and the ink is discharged from the ink ejection port of the inkjet head, and the valve is opened and the valve is driven to discharge the ink from the ink discharge port of the inkjet head. When supplying ink to the inkjet head from both the first ink flow path and the second ink flow path, the ink flow path is stopped to apply capillary force to the ink in the first ink flow path and the second ink flow path. An inkjet recording device characterized by comprising: a pump that can be used; (2) The inkjet head has multiple ejection ports in one
2. The inkjet recording apparatus according to claim 1, which is a full line type head arranged so as to be able to print lines.