1. Field of the Invention
The present invention relates to a liquid supply device and an image forming apparatus, and more particularly to a structure of a sub tank used in a liquid supply device installed in an inkjet recording device.
2. Description of the Related Art
Conventionally, there is an inkjet recording device among image forming apparatuses such as a printer, a fax machine, a copier, and a plotter. In the inkjet recording device, a low-volume sub tank (liquid container) for supplying ink (liquid) to an inkjet head (liquid jet head) is provided on a carriage, and a high-volume ink cartridge (main tank/liquid storing tank) is provided in the main body of the inkjet recording device. Accordingly, the sub tank is replenished with ink supplied from the main body.
In the above configuration using a sub tank, there is no need to install a large ink tank on the carriage, and therefore when the carriage is moved, the kinetic load for driving the carriage can be reduced and the carriage can be prevented from oscillating.
The ink (liquid) in the main tank is supplied to the sub tank with the use of predetermined pressure. The inside of the sub tank has a negative pressure tendency so that ink is prevented from needlessly flowing to the nozzles. Accordingly, the ink is prevented from needlessly flowing to the head, so that liquid is prevented from dropping out.
As shown in
At a position facing the disk-type sheet 104 across the film 102, a force is generated at a point of effort 108A of a lever member 108. A valve member 105 is provided at a point of load 108B. The valve member 105 is operated via a fulcrum 108C to open an ink injection part 100A. Accordingly, the ink in a supply path connected to the main tank is supplied to the negative pressure chamber 101. The valve opening pressure of the valve member 105 is set to a static pressure by a spring 107.
The above configuration uses the function of a lever, and therefore it is possible to generate a force that is greater than or equal to the pressure-receiving area of the film 102.
There is proposed a mechanism for preventing the oscillation of a film in a structure using the film. Specifically, flexible films and resin plates that are integrally combined with the flexible films are used as walls of the sub tank. Accordingly, the oscillation of the flexible film can be mitigated by the resin plates (see, for example, patent document 2).
In a configuration in which the sub tank and the ink tank are placed at different positions, and the sub tank and the ink tank are connected by a tube, the following problem may arise. That is, as the main scanning width increases, the length of the tube needs to be increased. Accordingly, inertia occurs when the speed of the carriage is increased or decreased. Due to this inertia, the ink moves, and the liquid pressure changes from a predetermined pressure. Changes in the liquid pressure affect the negative pressure tendency in the sub tank. Consequently, the liquid ink may needlessly drop out from the head.
The present invention provides a liquid supply device and an image forming apparatus, in which one or more of the above-described disadvantages are eliminated.
A preferred embodiment of the present invention provides a liquid supply device and an image forming apparatus with which liquid can be prevented from dropping out due to changes in the liquid pressure in a liquid supply path caused by inertia.
According to an aspect of the present invention, there is provided a liquid supply device including a main tank that stores a recording liquid; a sub tank that is connected to the main tank via a supply path; and a nozzle that jets the recording liquid retained in the sub tank, wherein the recording liquid is supplied into the sub tank from the main tank by a predetermined pressure, and the sub tank includes a supply chamber that causes the recording liquid to move toward the nozzle, the supply chamber including an opening/closing valve provided at an injection part through which the recording liquid enters the supply chamber from the main tank, and a pressure control chamber that supplies the recording liquid from the main tank into the supply chamber, the pressure control chamber being connected to the supply path, wherein the pressure control chamber includes a pressure resistor having a filter function provided near a connection part between the pressure control chamber and the supply chamber, the pressure resistor being placed in such a manner as to extend across a flow direction of the recording liquid, and a pressure mitigating unit provided on a wall of the pressure control chamber near the connection part, on at least a downstream side with respect to the pressure resistor in the flow direction of the recording liquid, wherein the pressure mitigating unit changes a volume of the pressure control chamber in accordance with a change in a liquid pressure that has occurred in the supply path, to mitigate an impact of the changed liquid pressure applied on the connection part.
According to one embodiment of the present invention, a liquid supply device and an image forming apparatus are provided, in which increased pressure can be reduced to static pressure with a simple configuration including a volume changing member that only uses pressure changes in the pressure control chamber and a speed reduction mechanism, so that the liquid can be reliably prevented from dropping out due to changes in the pressure.
Other objects, features and advantages of the present invention will become more apparent from the following detailed description when read in conjunction with the accompanying drawings, in which:
A description is given, with reference to the accompanying drawings, of embodiments of the present invention.
The inkjet recording device 10 includes recording heads 13 that jet ink droplets 12. The ink droplets 12 are formed with ink supplied from ink cartridges 11 corresponding to different colors. Furthermore, the inkjet recording device 10 includes a carriage 14 equipped with the recording heads 13. The carriage 14 moves back and forth above a recording sheet 20.
Sub tanks 15 are integrally combined with the recording heads 13, for supplying ink to the recording heads 13. The ink cartridges 11 corresponding to main tanks are placed at positions away from the carriage 14. A pump 17 is used to apply pressure to air chambers 18, so that ink in ink packs 16 of the ink cartridges 11 is supplied to the sub tanks 15 through supply paths such as tubes 19.
The reason why pressure is used to assist the ink to be supplied is to prevent supply failures. Specifically, the longer the supply path, the larger the flow path resistance, and consequently the ink may not be properly supplied (supply failure). In accordance with image information, the recording sheet 20 is intermittently conveyed in the sub scanning direction, while the recording heads 13 installed in the carriage 14 move back and forth in the main scanning direction above the recording sheet 20 and jet the ink droplets 12, so that an image is formed on the recording sheet 20.
As shown in
The volume of the negative pressure chamber 101 contracts as the film 102 is displaced due to negative pressure generated in the nozzle. Accordingly, ink is supplied toward the nozzle from a supply opening 101A connected to the nozzle. Thus, the negative pressure chamber 101 acts as a supply chamber for supplying ink to the nozzle. In
The pressure control chamber 110 is provided adjacent to the negative pressure chamber 101 that is the supply chamber. The pressure control chamber 110 includes a space connected to an ink injection part 100A that is opened/closed by the valve member 105.
The pressure control chamber 110 is a part of a supply path through which ink in the main tank flows toward the negative pressure chamber 101 through the tube 19. Inside the pressure control chamber 110, there is a mechanism for mitigating changes in the liquid pressure in the supply path. In particular, this mechanism is for reducing increased liquid pressure, so that the increased liquid pressure does not needlessly open the valve member 105.
The reason for reducing the increased liquid pressure is described below.
The tube 19 is filled with ink from the ink cartridge 11. When the valve member 105 is opened, the ink in the tube 19 flows into the negative pressure chamber 101. When the ink inside the tube 19 moves due to inertia caused when the carriage 14 moves or stops, the liquid pressure in the supply path may increase.
If the liquid pressure in the supply path becomes greater than or equal to the static pressure of the valve member 105, the valve member 105 opens. Consequently, an excessive amount of ink flows into the negative pressure chamber 101, and the ink pours out toward the nozzle and drops out of the sub tank 15.
In an embodiment of the present invention, when the liquid pressure increases in the pressure control chamber 110, the increased liquid pressure is reduced by changing the volume of the pressure control chamber 110 with the increased liquid pressure, and by reducing the speed of the ink moving in the pressure control chamber 110.
A description is given of a configuration for mitigating a pressure increase in the sub tank 15.
As shown in
The volume changing members 113 and 114 initialize the volume in the pressure control chamber 110 with the use of springs 113A and 114A. Specifically, the springs 113A and 114A contract when the negative pressure inside the negative pressure chamber 101 increases, i.e., when the pressure inside the pressure control chamber 110 exceeds a static pressure set in the valve member 105. When a pressure higher than the static pressure of the valve member 105 is applied inside the pressure control chamber 110, the volume changing members 113 and 114 contract and move so that the volume inside the pressure control chamber 110 is increased from the initial volume.
In the structure shown in
The present embodiment has the above configuration, and therefore the following functions are achieved. As shown in
Meanwhile, when the liquid pressure in the ink supply path increases and becomes greater than or equal to the valve opening pressure of the valve member 105, as shown in
The contraction/movement is most significant with respect to the volume changing member 113 that is positioned on the upstream side of the pressure resistor 112 in the ink flowing direction. Therefore, the pressure on the ink is reduced, and the ink passes through the pressure resistor 112.
The speed of the ink is reduced when passing through the pressure resistor 112, due to the resistance caused when the ink passes through the pressure resistor 112. After the ink has passed through the pressure resistor 112, the pressure of the ink is reduced compared to that before passing through the pressure resistor 112.
The pressure of the ink that has passed through the pressure resistor 112 is reduced as the speed of the ink is reduced when passing through the pressure resistor 112. When the pressure of the ink is higher than the static pressure of the valve member 105, the volume changing member 114 contracts and moves. As the volume changing member 114 contracts and moves, the volume of the pressure control chamber 110 increases. Therefore, by the time the ink reaches the ink injection part 100A, the pressure of the ink is reduced to the static pressure of the valve member 105. In
As described above, the pressure inside the pressure control chamber 110 is prevented from increasing excessively with the volume changing mechanism and the speed reduction mechanism.
Next, a description is given of another configuration for mitigating excessive increases in the pressure.
In
Next, a description is given of another example for mitigating excessive increases in the pressure.
In
In the above configuration, when the pressure of ink that has passed through the pressure resistor 112 is still higher than the static pressure, the increased pressure is consumed for expanding the volume of the pressure control chamber 110 by using the volume changing member 114 and contracting the gas G. Therefore, it is possible to mitigate the impact of the increased pressure applied on the ink injection part 100A. A sufficient amount of gas G is included in this space such that the gas G can contract, so that the liquid pressure of ink that has passed through the pressure resistor 112 can be reduced to static pressure, in combination with the function of expanding the volume of the space with the volume changing member 114.
Next, a description is given of a modification of a configuration for changing the volume of the space in the pressure control chamber 110.
In the
In the configuration of
In the configuration of
In any case, the elastic film 120 (volume changing member) is provided near the ink injection part 100A on the downstream side of the pressure resistor 112 in the ink flow direction. Therefore, it is possible to mitigate the impact of the increased pressure applied on the ink injection part 100A.
In the configuration of
The configuration of
With the above configurations, when the pressure in the pressure control chamber 110 becomes greater than or equal to the static pressure, the elastic film 120 expands and deforms so that the volume inside the pressure control chamber 110 increases and the pressure can be reduced. Therefore, it is possible to mitigate the impact of the increased ink pressure applied on the valve member 105 that is closing the ink injection part 100A.
The present invention is not limited to the specific embodiments described herein, and variations and modifications may be made without departing from the scope of the present invention.
The present application is based on Japanese Priority Patent Application No. 2010-001964, filed on Jan. 7, 2010, the entire contents of which are hereby incorporated herein by reference.
Number | Date | Country | Kind |
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2010-001964 | Jan 2010 | JP | national |