JP2021194900A - Liquid discharge device - Google Patents

Abstract

To provide a liquid discharge device which can inhibit sagging and scattering of a liquid.SOLUTION: A liquid discharge device includes: a liquid storage part 37 including an introduction part 37a which may introduce a liquid to be stored; a passage part in which the liquid may circulate and which can make connection and release the connection in conjunction with the introduction part sliding on its interior; and a connection part where the passage part and the introduction part are connected. The connection part is provided with an atmosphere communication part 51 which allows the passage communicating with the liquid storage part to communicate with atmospheric air.SELECTED DRAWING: Figure 5

Description

The present invention relates to a liquid discharge device provided with a replaceable liquid storage unit for storing liquid.

Patent Document 1 discloses a technique for preventing ink from dripping from a waste liquid flow path by increasing the volume of the waste liquid flow path member to generate a negative pressure when the waste liquid discharge device is replaced.

Japanese Unexamined Patent Publication No. 2018-114624

However, the configuration described in Patent Document 1 is a configuration in which the waste liquid flow path and the waste liquid storage unit are not connected, and cannot be applied to a configuration in which the waste liquid flow path and the waste liquid storage unit are connected.

In a configuration in which the waste liquid flow path and the waste liquid storage portion are connected by a tube or the like, a negative pressure is generated inside the connection portion when the tube is pulled out from the waste liquid storage portion when the waste liquid storage portion is replaced. When the connection is disconnected in the state where the negative pressure is generated in this way, there is a problem that the waste liquid is drawn out from the waste liquid storage portion and the tube due to the influence of the negative pressure, and dripping or scattering occurs.

Therefore, an object of the present invention is to provide a liquid discharge device capable of suppressing the occurrence of dripping or scattering of liquid.

Therefore, the liquid discharge device of the present invention can store a liquid and can flow a liquid between a liquid storage unit having an introduction unit capable of introducing the liquid to be stored and a liquid storage unit, which can be slid with the introduction unit. A flow path portion that can be connected and disconnected, a connection portion that connects the flow path portion and the introduction portion, and a connection portion.
A liquid discharge device comprising the above, characterized in that the connection portion is provided with an atmospheric communication portion in which a flow path communicating with the liquid storage portion communicates with the atmosphere.

According to the present invention, it is possible to provide a liquid discharge device capable of suppressing the occurrence of dripping or scattering of liquid.

It is an external perspective view which showed the liquid discharge device. It is a side view which showed the inside of the liquid discharge device so that it can be seen. It is a figure which showed the ink storage part, the print head, and the maintenance part. It is a figure which showed the connection part which connected the waste liquid storage part and a tube. It is a figure which showed the connection part. It is a figure which showed the connection part. It is a figure which showed the connection part. It is a figure which showed the connection part.

(First Embodiment)
Hereinafter, the first embodiment of the present invention will be described with reference to the drawings.

FIG. 1 is an external perspective view showing a liquid discharge device 10 to which the present invention can be applied. The liquid ejection device 10 includes a print medium charging unit 11 for charging a print medium such as paper, a printed matter discharging unit 12 for discharging printed matter, and an ink storage unit 13 for storing liquid (hereinafter, also referred to as ink) for printing. , Is equipped. Further, the liquid ejection device 10 includes an operation panel unit 14 for performing a printing operation and a maintenance unit 15 for maintaining the print head.

FIG. 2 is a side view showing the inside of the liquid discharge device 10 so as to be visible. The printing portion of the liquid ejection device 10 includes a cassette 24, a paper feed roller 25, a positioning roller 27, a print head 23, an ink tube 22, and an ink storage unit 13. The cassette 24 is a so-called box container that holds a plurality of sheets of paper as a printing medium in a stacked state. The cassette 24 has a slide mechanism that can be horizontally taken in and out of the main body of the liquid ejection device 10. When setting the paper, the cassette 24 is pulled out, and after the paper is set, the cassette 24 is pushed in. The cassette 24 also supports different paper sizes such as A4 size and postcard size, and there are two movable guides inside the cassette 24 in the width direction and the depth direction so that each paper can be centered. It is installed in.

The paper feed roller 25 is speed-adjusted and rotates so as to pick up the recording paper held in the cassette 24 one by one. Rubber with a wavy pattern, so-called elephant skin, is wrapped around the contact surface with the paper. The positioning roller 27 conveys the paper with high accuracy by friction between the surface of the positioning roller 27 and the paper so that the distance between the print head 23 and the paper is within a certain range. The surface of the positioning roller 27 is covered with, for example, a paint containing ceramic particles.

The print head 23 receives a document or image data from a PC (not shown) or the like, and ejects ink with high accuracy while moving in a width direction orthogonal to the paper feed to print on paper. The ink tube 22 individually connects the movable print head 23 and the ink storage unit 13 fixed to the main body of the liquid ejection device 10 for each color. The ink storage unit 13 is partitioned so that each color can be individually stored, and ink is replenished to the ink storage unit 13 individually with an ink bottle (not shown) for each color.

FIG. 3 is a diagram showing an ink storage unit 13, a print head 23, and a maintenance unit 15 in the liquid ejection device 10. The liquid ejection device 10 includes a maintenance unit 15 that recovers the ejection state of the print head 23 by sucking the ink in the print head 23. The maintenance unit 15 includes a movable portion 31, a cam mechanism 33 for moving the movable portion 31 in the vertical direction, a pump 34, a cap 30 provided on the movable portion 31, and a tube 32 capable of flowing a liquid. .. The cap 30 and the tube 32 are examples of flow path members through which the ink discharged from the print head 23 flows. The cap 30 is made of an elastic material such as rubber, and is arranged at a position facing the lower surface of the print head 23 in the vertical direction when the print head 23 is located above the movable portion 31.

The cam mechanism 33 moves the movable portion 31 in the vertical direction by transmitting the driving force from the motor 35. The cap 30 comes into contact with the lower surface of the print head 23 when the movable portion 31 moves upward, and separates from the lower surface of the print head 23 when the movable portion 31 moves downward. The cap 30 is configured to cover the opening of the row of nozzles 38 that eject ink of each color when it comes into contact with the lower surface of the print head 23. When the cap 30 is in contact with the lower surface of the print head 23, the space surrounded by the cap 30 and the lower surface of the print head 23 is a substantially sealed space.

One end 32b of the tube 32 is connected to the cap 30. The tube 32 is made of, for example, a flexible resin member. The pump 34 is a rotary type tube pump operated by a driving force from a motor 35. The pump 34 communicates with the closed space surrounded by the cap 30 and the lower surface of the print head 23 when the cap 30 abuts on the lower surface of the print head 23 through the tube 32. When the pump 34 is driven in a state where the cap 30 abuts on the lower surface of the print head 23 and covers the opening of the nozzle 38, the closed space inside the cap 30 becomes a negative pressure, and ink is discharged from each nozzle 38. To. The ink discharged from each nozzle 38 is received by the cap 30. The ink received by the cap 30 is sent out from the inside of the tube 32 toward the other end portion 32a by the pump 34, and flows into the waste liquid storage portion 37 capable of storing the waste liquid via the other end portion 32a.

The liquid discharge device 10 includes a control unit 36 that controls the operation of the motor 35 that drives the cam mechanism 33, the pump 34, and the like.

FIG. 4A is a diagram showing a connection portion 41 in which the waste liquid storage portion 37 and the tube 32 are connected, and FIG. 4B is an enlarged view of the connection portion 41. The waste liquid storage unit 37, which is a liquid storage unit, is connected to the end portion 32a of the tube 32, and the ink flowing in the tube is absorbed by the absorber 40 housed in the waste liquid storage unit 37. Further, the waste liquid storage unit 37 communicates with the atmosphere on the upper surface. When the amount of waste liquid stored in the waste liquid storage unit 37 exceeds a predetermined amount, the tube 32 is pulled out from the waste liquid storage unit 37, and the pulled out tube 32 is connected to the waste liquid storage unit 37 in which ink is not stored.

The liquid discharge device 10 in the present embodiment includes an atmospheric communication port for communicating the inside of the flow path with the atmosphere at the connection portion 41.

5 (a) to 5 (c) are views showing the connection portion 41 in the present embodiment. The waste liquid storage unit 37 is provided with an introduction port 37a, which is an introduction unit into which the waste liquid storage unit 37 can be connected to the end portion 32a of the tube 32 and the waste liquid can be introduced into the waste liquid storage unit 37. FIG. 5A shows a state in which the end portion 32a and the introduction port 37a are completely connected. At the end 32a of the connecting portion 41, an atmospheric communication port 51 which is an atmospheric communication portion communicating with the atmosphere and a functional member 52 covering the atmospheric communication port 51 are provided. As shown in FIG. 5A, when the end portion 32a and the introduction port 37a are completely connected, the air communication port 51 is closed by the introduction port 37a, and the inside of the tube 32 communicates with the atmosphere. Not. During normal operation of the liquid discharge device 10, the liquid discharge device 10 operates in the state shown in FIG. 5 (a). At this time, the inside of the flow path of the tube 32 and the introduction port 37a are filled with the waste liquid 50.

FIG. 5B shows a state in which the tube 32 is being pulled out from the waste liquid storage unit 37. In order to disconnect the connection between the waste liquid storage unit 37 and the tube 32, a sliding operation of pulling out the tube 32 from the waste liquid storage unit 37 is performed. When the tube 32 is started to be pulled out from the waste liquid storage unit 37 when the waste liquid storage unit 37 is replaced, the air communication port 51 opens and the inside of the tube 32 and the atmosphere communicate with each other as shown in FIG. 5 (b). Here, the functional member 52 is a member that allows water to pass through and only air to pass through. Therefore, even if the inside of the tube 32 communicates with the atmosphere, the ink does not leak from the air communication port 51.

When the tube 32 is pulled out from the waste liquid storage portion 37, the volume in the flow path in the tube 32 increases by the amount that the end portion 32a of the tube 32 moves with respect to the introduction port 37a, and the inside of the flow path is depressurized. With the depressurization in the flow path, the air for the volume change flows in from the open air communication port 51, and the negative pressure in the flow path is eliminated. In this way, the negative pressure in the flow path is relieved with the passage of time, so that the waste liquid 50 is not drawn out to the flow path from the introduction port 37a.

FIG. 5 (c) shows a state in which the tube 32 is further pulled out from the state of FIG. 5 (b), and is a state immediately before disconnection. Further, with the tube 32 pulled out, the volume in the flow path in the tube 32 further increases, but since the air for the volume change flows in from the atmospheric communication port 51, the negative in the flow path with the passage of time. The pressure state is eliminated. In this way, the tube 32 can be pulled out without pulling out the waste liquid 50 stored in the waste liquid storage unit 37. Further, the waste liquid 50 in the tube that is about to drip from the atmospheric communication port 51 is suppressed from drip by the functional member 52.

The time required to eliminate the negative pressure is determined by the opening area of the atmospheric communication port 51 and the gas permeability of the functional member 52. When the functional member 52 is made of porous polytetrafluoroethylene, the galley permeation time is about ^{13 sec / cm 3.} The transmittance is given from permeability = H / (P × S × Q), where H is the volume to be transmitted, P is the transmission pressure (pressure difference between inside and outside), S is the transmission area, and Q is the transmission time. The transmittance of the functional member 52 is 100 cm ^{3 / (} 1.22 kPa ^{× 6.42 cm 2} × 13 sec) ≈1.0 from the Gale transmission time.

As shown in FIG. 5C, the time Q1 at which air permeates through the functional member 52 and all the waste liquid in the flow path is replaced with air is obtained. The cross-sectional area of the inner diameter of the tube 32a is S1, the opening area of the atmospheric communication port 51 is S2, the length of connection between the introduction port 37a and the tube 32a is h, and the pressure due to the volume change is P'. At this time, the time for all the connecting portions to be replaced with air is Q1 = S1 × h / (P'× S2).
When the pressure P'due to the volume change in the flow path is 0.2 atm and the opening area of the atmospheric communication port 51 such that the time Q1 is 1 sec or less is obtained, S2 ≧ 5 × h × S1. The opening area of the air communication port 51 is required to be equal to or larger than the cross-sectional area of the inner diameter of the tube 32a. Since the length of the connecting portion is usually about 0.6 cm, the time for canceling the negative pressure in the flow path can be reduced to 1 sec or less by securing the area of the atmospheric communication port 51 that is three times the cross-sectional area of the tube 32a, which is effective. Can be used as a target.

In this way, an air communication port is provided at the connection portion between the waste liquid storage portion 37 and the tube 32. This makes it possible to provide a liquid discharge device capable of suppressing the occurrence of dripping or scattering of liquid.

(Second embodiment)
Hereinafter, a second embodiment of the present invention will be described with reference to the drawings. Since the basic configuration of this embodiment is the same as that of the first embodiment, a characteristic configuration will be described below.

6 (a) to 6 (c) are views showing the connection portion 42 in the present embodiment. FIG. 6A shows a state in which the end portion 32a and the introduction port 37a are completely connected. The introduction port 37a in the connection portion 42 is provided with an atmospheric communication port 61 that communicates with the atmosphere. As shown in FIG. 6A, when the end portion 32a and the introduction port 37a are completely connected, the air communication port 61 is closed by the end portion 32a of the tube 32, and the introduction port 37a and the tube are closed. The inside of 32 does not communicate with the atmosphere. During normal operation of the liquid discharge device 10, the liquid discharge device 10 operates in the state shown in FIG. 6A. At this time, the inside of the flow path of the tube 32 and the introduction port 37a are filled with the waste liquid 50.

FIG. 6B shows a state in which the tube 32 is being pulled out from the waste liquid storage unit 37. When the tube 32 is started to be pulled out from the waste liquid storage unit 37 when the waste liquid storage unit 37 is replaced, the air communication port 61 opens and the inside of the introduction port 37a communicates with the atmosphere as shown in FIG. 6B. Since the air communication port 61 is provided in the direction opposite to the direction of gravity at the introduction port 37a, ink does not leak from the atmosphere communication port 61 even if the inside of the introduction port 37a communicates with the atmosphere.

When the tube 32 is pulled out from the waste liquid storage portion 37, the volume in the flow path in the tube 32 increases by the amount that the end portion 32a of the tube 32 moves with respect to the introduction port 37a, and the inside of the flow path is depressurized. With the depressurization in the flow path, the air for the volume change flows in from the open atmospheric communication port 61, and the negative pressure in the flow path is eliminated. In this way, the negative pressure in the flow path is relieved with the passage of time, so that the waste liquid 50 is not drawn out to the flow path from the introduction port 37a.

FIG. 6 (c) shows a state in which the tube 32 is further pulled out from the state of FIG. 6 (b), and is a state immediately before disconnection. Further, with the tube 32 pulled out, the volume in the flow path in the introduction port 37a further increases, but since the air for the volume change flows in from the atmospheric communication port 61, it becomes negative with the passage of time in the flow path. The pressure state is eliminated. In this way, the tube 32 can be pulled out without pulling out the waste liquid 50 stored in the waste liquid storage unit 37. Therefore, even if the connection between the tube 32 and the waste liquid storage portion 37 is disconnected, it is possible to prevent the ink from dripping from the end portion 32a of the tube 32 or the introduction port 37a.

The position where the atmospheric communication port 61 is provided and the amount of the end portion 32a moving through the introduction port 37a need to be as follows. That is, as shown in FIG. 6D, the position of the atmospheric communication port 61 is set so that the waste liquid 50 does not remain in the opening 37b of the introduction port 37a with the end 32a at the end of the introduction port 37a. There is a need to. When the distance from the air communication port 61 to the opening 37b of the introduction port 37a is long, the waste liquid 50 is inserted into the opening 37b as shown in FIG. 6D with the end 32a at the end of the introduction port 37a. May remain. Therefore, it is necessary to set the position of the atmospheric communication port 61 so that the waste liquid 50 does not remain in the opening 37b with the end 32a at the end of the introduction port 37a.

In setting the position of the atmospheric communication port 61 at the introduction port 37a, a U-shaped atmospheric communication port 61a may be provided at the end 32a of the tube 32 as shown in FIGS. 7A and 7B.

(Third embodiment)
Hereinafter, a third embodiment of the present invention will be described with reference to the drawings. Since the basic configuration of this embodiment is the same as that of the first embodiment, a characteristic configuration will be described below.

8 (a) to 8 (c) are views showing the connection portion 43 in the present embodiment. FIG. 8A shows a state in which the end portion 32a and the introduction port 37a are completely connected. The introduction port 37a is provided with a groove 71 for communicating with the atmosphere, and a functional member 52 is adhered to a part of the groove 71. As shown in FIG. 8A, when the end portion 32a and the introduction port 37a are completely connected, the inside and outside of the flow path in the tube 32 are blocked. During normal operation of the liquid discharge device 10, the liquid discharge device 10 operates in the state shown in FIG. 8 (a). At this time, the inside of the flow path of the tube 32 and the introduction port 37a are filled with the waste liquid 50.

FIG. 8B shows a state in which the tube 32 is being pulled out from the waste liquid storage unit 37. When the tube 32 is pulled out from the waste liquid storage unit 37 when the waste liquid storage unit 37 is replaced, the inside of the tube 32 and the atmosphere communicate with each other through the groove 71 as shown in FIG. 8 (b). Here, the functional member 52 is a member that allows water to pass through and only air to pass through. Therefore, even if the inside of the tube 32 communicates with the atmosphere, the ink does not leak from the groove 71.

When the tube 32 is pulled out from the waste liquid storage portion 37, the volume in the flow path in the tube 32 increases by the amount that the end portion 32a of the tube 32 moves with respect to the introduction port 37a, and the inside of the flow path is depressurized. With the depressurization in the flow path, air for the volume change flows from the groove 71, and the negative pressure in the flow path is eliminated. In this way, the negative pressure in the flow path is relieved with the passage of time, so that the waste liquid 50 is not drawn out to the flow path from the introduction port 37a.

FIG. 8 (c) shows a state in which the tube 32 is further pulled out from the state of FIG. 8 (b), and is a state immediately before disconnection. Further, with the tube 32 pulled out, the volume in the flow path in the tube 32 further increases, but since the air for the volume change flows in from the groove 71, the negative pressure state in the flow path changes with the passage of time. It will be resolved. In this way, the tube 32 can be pulled out without pulling out the waste liquid 50 stored in the waste liquid storage unit 37. Further, the waste liquid 50 in the tube that is about to drip from the groove 71 is suppressed from drip by the functional member 52.

10 Liquid discharge device 32 Tube 37 Waste liquid storage unit 37a Inlet port 50 Waste liquid 51 Atmospheric communication port 61 Atmospheric communication port 71 Groove

Claims (10)

A liquid storage unit that can store liquid and has an introduction unit that can introduce the liquid to be stored,
A flow path section that allows liquid to flow and can be connected and disconnected by sliding with the introduction section.
A connection portion to which the flow path portion and the introduction portion are connected,
It is a liquid discharge device equipped with
The liquid discharge device is characterized in that the connection portion is provided with an atmospheric communication portion in which a flow path communicating with the liquid storage portion communicates with the atmosphere. The liquid discharge device according to claim 1, wherein the atmospheric communication portion is provided in the flow path portion. The liquid discharge device according to claim 2, wherein the air communication portion is provided with a functional member that allows air to pass through and does not allow liquid to pass through. The atmospheric communication portion is an atmospheric communication port provided with an opening in the flow path portion.
The liquid discharge device according to claim 2 or 3, wherein the opening area of the air communication port is equal to or larger than the cross-sectional area of the inner diameter of the flow path portion. The liquid discharge device according to claim 1, wherein the air communication unit is provided in the introduction unit. The liquid discharge device according to claim 5, wherein the atmospheric communication portion is an atmospheric communication port that opens in a direction opposite to the direction of gravity. The liquid discharge device according to claim 5, wherein the atmospheric communication portion is a groove. The liquid discharge device according to claim 7, wherein the air communication portion is provided with a functional member that allows air to pass through and does not allow liquid to pass through. The liquid discharge device according to claim 1, wherein the atmospheric communication section is provided in the flow path section and the introduction section. The liquid discharge device according to claim 9, wherein the atmospheric communication portion provided in the flow path portion is U-shaped.

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