JP6750384B2 - Tube pump and liquid ejection device - Google Patents

Description

The present invention relates to a tube pump and a liquid ejecting apparatus including a tube pump.

As an example of the liquid ejecting apparatus, there is an inkjet printer including a tube pump that sucks a fluid. In a tube pump, the middle part of the tube is housed in an annular shape in a cylindrical pump case, and a roller that revolves along with the rotation of a rotating body arranged in the pump case presses the tube, thereby causing the fluid inside the tube to move. To pump. Further, when the roller reaches the leak point on the orbit, the tube is not sufficiently pressed and the suction is released (for example, Patent Document 1).

JP 2012-144003 A

The tube pump described above can reverse the flow direction of the liquid accompanying suction by reversing the rotation direction of the rotating body. However, the suction is released each time the roller passes through the portion where the tube ring that is the leak point on the orbit is broken. Therefore, there is a problem that suction cannot be continued even if the rotating body is continuously rotated. Such a problem is not limited to the tube pump included in the printer, but is common to tube pumps that pump fluid in the rotational direction of the rotating body.

The present invention has been made in view of these circumstances, and an object of the present invention is to provide a tube pump and a liquid ejecting apparatus that can continuously pump a fluid as the rotating body rotates.

A tube pump that solves the above problems is a tube pump in which a hollow portion is provided in the middle of a tube forming a flow path, and a frame that accommodates the tube in an annularly curved state, and by the power of a drive source, A rotating body that rotates in a first rotating direction and a second rotating direction that is the opposite direction of the first rotating direction around a rotating shaft that is located on the inner peripheral side of the ring of the tube, and the rotating body that rotates around the rotating body. A pressing roller that revolves while pressing the tube by being locked, wherein the rotating body has a first locking portion that locks the pressing roller when rotating in the first rotation direction; A second locking portion that locks the pressing roller when rotating in the second rotation direction, a first guide curved portion that is curved in a spiral shape so as to approach the rotation axis from the first locking portion, and the first locking portion. A second guide curved portion that is curved in a spiral shape so as to approach the rotation axis from the two locking portions, and the pressing roller is configured such that when the rotation direction of the rotating body is reversed, the first guide curved portion. The tube and the second guide curved portion to release the pressing of the tube.

FIG. 3 is a perspective view showing an embodiment of a liquid ejecting apparatus. The front view of the liquid ejecting apparatus of FIG. FIG. 2 is a schematic diagram showing the overall configuration of the liquid ejecting apparatus of FIG. 1. FIG. 2 is a schematic diagram showing a planar configuration inside a housing included in the liquid ejecting apparatus of FIG. FIG. 2 is a schematic diagram showing a flow path configuration of the liquid ejecting apparatus of FIG. Sectional drawing which shows 1st Embodiment of a tube pump. The perspective view of the rotary body and press roller with which the tube pump of FIG. 6 is equipped. Sectional drawing which shows 2nd Embodiment of a tube pump. The perspective view which shows 3rd Embodiment of a tube pump. The disassembled perspective view of the tube pump of FIG. The disassembled perspective view of the tube pump of FIG. The schematic diagram which shows the internal structure of the tube pump of FIG. Sectional drawing which shows the example of a change of a pumping mechanism. Sectional drawing which shows the example of a change of a liquid ejecting apparatus.

Hereinafter, embodiments of the liquid ejecting apparatus will be described with reference to the drawings. The liquid ejecting apparatus is, for example, an inkjet printer that performs recording (printing) by ejecting ink, which is an example of a liquid, onto a medium such as paper.

<Embodiment of liquid ejecting apparatus>
As shown in FIG. 1, the liquid ejecting apparatus 11 of the present embodiment is a large format printer (LFP) that prints on a medium S having a relatively large size, such as JIS standard A0 size or B0 size.

The liquid ejecting apparatus 11 includes a housing 12, support legs 13 that support the housing 12, and a liquid supply device 14 that is disposed on the housing 12. The liquid supply device 14 is provided on one or a plurality (four in the present embodiment) of container holders 16 to which a liquid container 20 for containing a liquid can be attached, and on the base end side of the container holder 16. And a rotating shaft 17. The container holding unit 16 holds the mounted liquid container 20.

When the side of the housing 12 on which the printed medium S comes out is referred to as the front side, an operation unit 18 for operating the liquid ejecting apparatus 11 is provided on the front side of the housing 12. Further, from the front surface portion of the housing 12, a support projection 19 that supports the printed medium S and guides it downward is projected.

As shown in FIG. 2, the housing 12 has, in its longitudinal direction (the left-right direction in FIG. 2 ), a central portion in which the transport path for the medium S is arranged, such as the support protrusions 19, and both ends outside the transport path. It is divided into parts. The liquid supply device 14 is preferably arranged at the central portion in the longitudinal direction where the transport path for the medium S is arranged.

When there are a plurality of container holding parts 16, the plurality of container holding parts 16 may be arranged side by side in the longitudinal direction of the housing 12. The liquid container 20 is attached/detached to/from the container holder 16 when the container holder 16 is in the attachment/detachment position shown in FIG. 2. Therefore, it is preferable that the container holding portion 16 is in a flat posture in which the width and the depth are longer than the height of the liquid container 20 at the attachment/detachment position. In such a flat posture, even the large liquid container 20 can be stably attached and detached while suppressing its height. When the liquid container 20 is horizontally attached and detached to and from the container holder 16, the own weight of the liquid container 20 is unlikely to affect the attachment/detachment operation.

As shown in FIG. 3, the liquid ejecting apparatus 11 includes a feeding mechanism 25 that rotatably holds a medium S (for example, roll paper) wound in a cylindrical shape before use, and printing that has come out from the housing 12. A winding mechanism 26 that winds up the completed medium S and a tension bar 27 that applies tension to the medium S that has exited from the housing 12 may be provided. With this configuration, it is possible to continuously perform the recording process on the long medium S wound in a cylindrical shape.

Inside the housing 12, a guide shaft 31 extending in the longitudinal direction, a carriage 32 that reciprocates along the guide shaft 31, and one or a plurality of (two in the present embodiment) liquid ejecting portions held by the carriage 32. 33 (see also FIG. 4), a support portion 34 that forms a transport path for the medium S in the housing 12, and a transport mechanism 35 that transports the medium S in the housing 12 are housed.

The liquid ejecting unit 33 has a plurality of nozzles 36, and performs recording processing by ejecting liquid from the nozzles 36 toward the medium S conveyed on the support unit 34 by the conveying mechanism 35. In the present embodiment, the moving direction of the carriage 32 and the longitudinal direction of the housing 12 coincide with each other. Further, the transport path of the medium S on the support portion 34 intersects (preferably orthogonal) with the moving direction of the carriage 32.

The carriage 32 is connected to a supply flow path 37 that causes the liquid contained in the liquid container 20 to flow toward the liquid ejecting unit 33. The container holding unit 16 is arranged at a position where the liquid can be supplied to the liquid ejecting unit 33 by the head generated by the height difference between the liquid contained in the mounted liquid container 20 and the nozzle 36. The "head" is obtained by replacing the pressure of the liquid with the height of the liquid column in the direction of gravity, and has a length dimension (for example, m). For example, when the liquid is water and the head of 1 m is pressure-converted, it becomes 9.8 kPa.

The container holding portion 16 is provided so as to be movable between the attachment/detachment position shown by the solid line in FIG. 3 and the supply position shown by the chain double-dashed line in FIG. In the present embodiment, the container holding unit 16 moves between the supply position and the attachment/detachment position by rotating about 90 degrees around the rotating shaft 17. When there are a plurality of container holding portions 16, the plurality of container holding portions 16 may be individually rotated, or the plurality of container holding portions 16 may be collectively rotated.

The container holding portion 16 can be configured to rotate about the rotation shaft 17 by the driving force of a drive source (not shown) or can be manually rotated. The drive source for rotating the container holding unit 16 is, for example, a motor provided for unwinding the unused medium S wound in a cylindrical shape or winding the printed medium S. You may also use it. When the container holding unit 16 is manually rotated, the container holding unit 16 may be provided with a handle 15.

The rotation angle may be smaller than 90 degrees and the posture in which the liquid container 20 is inclined with respect to the horizontal may be the attachment/detachment position or the supply position of the container holder 16. In any case, a pressure-converted value of the water head generated by the height difference between the liquid contained in the liquid container 20 and the nozzle 36 at the supply position is generated when the liquid is ejected for the recording process. It is preferably larger than the pressure loss.

At the supply position, it is preferable that the liquid container 20 mounted on the container holding portion 16 is in a vertically placed posture in which the height is longer than that at the attachment/detachment position. Further, at the attachment/detachment position, the position of the attached liquid container 20 is preferably lower than the supply position.

The liquid container 20 may be, for example, a cartridge having a liquid container 21 that is a flexible bag and a case 22 that houses the liquid container 21, or a tank that directly contains the liquid. May be. Further, the liquid containing portion 21 made of a flexible bag as the liquid containing body 20 is set on a tray that can be attached to and detached from the containing body holding portion 16, and the liquid containing portion 21 is attached to the containing body holding portion 16 together with the tray. It may be in the form of. The liquid storage portion 21 has a lead-out portion 23 that serves as an outlet for the stored liquid, and when the liquid storage portion 21 is attached to the container holding portion 16, the liquid supply portion 37 is provided so that the liquid can be supplied through the lead-out portion 23. It is connected to the upstream end. When the lead-out portion 23 is arranged below the liquid storage portion 21 at the supply position, the liquid easily flows out of the liquid storage portion 21 due to the head of water.

The liquid ejecting apparatus 11 includes a pressure feeding mechanism 38 that forcibly flows the liquid from the liquid container 20 toward the liquid ejecting unit 33, and a control unit 100 that controls various mechanisms included in the liquid ejecting apparatus 11. The pressing force of the liquid by the pressure feeding mechanism 38 is preferably larger than the pressure-converted value of the head at the supply position. The control unit 100 switches between the liquid supply by the head and the liquid supply by the pressure feed mechanism 38 by controlling the drive of the pressure feed mechanism 38 at a predetermined timing.

In the liquid container 20, when the liquid is stored (filled) in the liquid storage portion 21 formed of a closed bag, the stored liquid has a “water head center”. The “center of the head” corresponds to the liquid surface of the liquid stored in the so-called open-system liquid storage unit whose internal space is open to the atmosphere. Then, the water head (potential energy of the liquid) with respect to the nozzle 36 generated by the liquid stored in the liquid storage portion 21 arranged at the supply position is defined by the height difference between the “water head center” and the nozzle 36.

The “water head center” moves downward in the gravity direction when the remaining amount of the liquid stored in the liquid storage unit 21 becomes small, like the liquid surface of the liquid stored in the open liquid storage unit. The unused liquid storage portion 21 in the present embodiment is filled with liquid such that the “center of the head” is about half the height of the liquid storage portion 21 arranged at the supply position, and the maximum head The value corresponds to the height difference H in FIG.

The supply flow path 37 may be branched into two branch flow paths 37a and 37b on the upstream side connected to the container holding unit 16. In this case, the one branching flow path 37a is provided with the pressure feeding mechanism 38, and the other branching flow path 37b is allowed to flow the liquid downstream and to suppress the flow liquid upstream. A valve 40 may be provided.

An on-off valve 39 is provided in the supply passage 37 upstream of the branch passages 37a and 37b. The on-off valve 39 allows the flow of the liquid when it is in the open state and regulates the flow of the liquid when it is in the closed state. The open/close valve 39 is preferably configured to be switchable between a valve open state and a valve closed state by the open/close control of the control unit 100.

As shown in FIG. 4, the supply flow path 37 is routed in the housing 12 so that the extending direction is reversed at the end portion in the longitudinal direction, and the downstream side thereof is connected to the carriage 32.
The supply channel 37 is preferably provided with a filter unit 41 that captures foreign matter such as bubbles mixed in the liquid. If the filter unit 41 is exposed outside the carriage 32, maintenance such as replacement can be easily performed. If a static mixer 42 (see also FIG. 5) that causes a change in direction or division of the liquid flow is provided in the supply channel 37, for example, on the downstream side of the filter unit 41, the concentration in the liquid can be reduced. Bias can be reduced.

When the right end side in FIG. 4 is the start end of the outward movement of the carriage 32, a maintenance mechanism 50 provided for performing maintenance of the liquid ejecting unit 33 is arranged on the right side portion inside the housing 12 outside the transport path. Has been done. The maintenance mechanism 50 includes a wiping device 52 having a wiping member 51 for wiping the liquid ejecting section 33, a flushing unit 54 having a liquid receiving section 53 for receiving the liquid ejected by the liquid ejecting section 33, and a cleaning of the liquid ejecting section 33. And a cleaning mechanism 55 for performing. The wiping device 52, the flushing unit 54, and the cleaning mechanism 55 are arranged side by side with the support portion 34 in the longitudinal direction.

The wiping device 52 wipes the liquid ejecting unit 33 by moving the wiping member 51 relative to the liquid ejecting unit 33. The flushing unit 54 receives the discharged liquid by the liquid receiving portion 53 when performing the flushing for discharging the liquid droplets from the nozzle 36 for the purpose of preventing or eliminating the clogging of the nozzle 36. The liquid receiving portion 53 can be configured by, for example, a rotating endless belt.

As shown in FIG. 5, the cleaning mechanism 55 includes a cap 56 that forms a closed space in which the nozzle 36 opens between the liquid ejecting unit 33, a waste liquid container 57 that stores waste liquid, a cap 56 and the waste liquid container. A suction flow channel 58 connecting 57 and a suction pump 59 provided in the suction flow channel 58 are provided. The waste liquid container 57 may be arranged outside the housing 12 (see FIG. 1).

The cleaning mechanism 55 performs suction cleaning in which the negative pressure is generated in the closed space and the liquid is discharged from the nozzles 36 by driving the suction pump 59 with the closed space of the cap 56. By the suction cleaning, foreign matters such as bubbles in the liquid ejecting unit 33 are discharged together with the liquid. The liquid discharged from the nozzle 36 is stored as a waste liquid in the waste liquid container 57 through the suction flow path 58.

The supply channel 37 connected to the carriage 32 may be provided with the liquid storage section 43, the degassing mechanism 45, and the pressure adjusting mechanism 70. In the supply flow path 37, the liquid storage section 43 provided between the opening/closing valve 39 and the pressure adjusting mechanism 70 is configured by a flexible member 43a whose part of the wall surface is bendable and displaceable to form a space of variable volume. Form. The liquid storage portion 43 stores the liquid in a volume-variable space that is pressurized by the urging force of the spring 44, and relaxes the pressure fluctuation of the liquid.

The degassing mechanism 45 includes a degassing chamber 46 for temporarily storing a liquid, a decompression chamber 48 defined by the degassing chamber 46 and a degassing film 47, a decompression channel 49 connected to the decompression chamber 48, a pump 86, Equipped with. The degassing film 47 has a property of passing gas but not liquid, and by driving the pump 86 to depressurize the depressurizing chamber 48 through the depressurizing channel 49, the degassing film 47 is mixed with the liquid stored in the degassing chamber 46. Remove bubbles and dissolved gas.

The pressure adjusting mechanism 70 includes a supply chamber 71 provided in the middle of the supply flow path 37, a pressure chamber 73 that can communicate with the supply chamber 71 through a communication hole 72, and a valve body 74 that can open and close the communication hole 72. The pressure receiving member 75 has a base end side housed in the supply chamber 71 and a tip end side housed in the pressure chamber 73. The valve body 74 is made of, for example, an elastic body attached to the base end portion of the pressure receiving member 75 located inside the supply chamber 71. The supply channel 37 may be provided with a filter 76 for filtering the liquid flowing into the supply chamber 71.

A part of the wall surface of the pressure chamber 73 is formed by a flexible film 77 that can be flexibly displaced. The pressure adjusting mechanism 70 also includes a first urging member 78 housed in the supply chamber 71 and a second urging member 79 housed in the pressure chamber 73. The first biasing member 78 biases the valve element 74 in a direction of closing the communication hole 72 via the pressure receiving member 75.

The pressure receiving member 75 is displaced by the flexible film 77 bending and displacing in the direction in which the volume of the pressure chamber 73 is reduced and pushing. In the valve element 74, the pressure (internal pressure) applied to the inner surface of the flexible film 77 on the pressure chamber 73 side is lower than the pressure (external pressure) applied to the outer surface of the flexible film 77 opposite to the pressure chamber 73. When the difference between the pressure applied to the inner surface and the pressure applied to the outer surface becomes a predetermined value (for example, 1 kPa) or more, the valve closed state is opened.

The predetermined value is a biasing force of the first biasing member 78 and the second biasing member 79, a force required to displace the flexible film 77, and a valve body 74 to close the communication hole 72. It is a value determined depending on the pressing force (seal load), the pressure inside the supply chamber 71 acting on the supply chamber 71 side of the pressure receiving member 75 and the surface of the valve body 74, and the pressure inside the pressure chamber 73.

That is, the greater the biasing force of the first biasing member 78 and the second biasing member 79, the greater the predetermined value. Further, the urging force of the first urging member 78 and the second urging member 79 is a negative pressure state (for example, a flexible film) in a range where the pressure in the pressure chamber 73 can form a meniscus at the gas-liquid interface in the nozzle 36. When the pressure applied to the outer surface of 77 is atmospheric pressure, it is set to be −1 kPa).

When the communication hole 72 is opened and the liquid flows from the supply chamber 71 into the pressure chamber 73, the internal pressure of the pressure chamber 73 rises. Then, when the internal pressure of the pressure chamber 73 reaches the above-mentioned predetermined value, the valve body 74 closes the communication hole 72.

The internal pressure of the pressure chamber 73 decreases as the liquid is ejected from the liquid ejecting unit 33. Then, the valve body 74 autonomously opens and closes the communication hole 72 according to the pressure difference between the external pressure (atmospheric pressure) of the pressure chamber 73 and the internal pressure of the pressure chamber 73. Therefore, the pressure adjusting mechanism 70 is classified into a differential pressure valve (particularly a pressure reducing valve among differential pressure valves).

A valve opening mechanism 81 that forcibly opens the communication hole 72 and supplies the liquid to the liquid ejecting unit 33 may be added to the pressure adjusting mechanism 70. The valve opening mechanism 81 includes, for example, a pressurizing bag 83 housed in a housing chamber 82 that is partitioned from the pressure chamber 73 by a flexible film 77, and a pressurizing flow path 84 that allows gas to flow into the pressurizing bag 83. .. Then, the pressure bag 83 is bulged by the gas flowing in through the pressure flow path 84, and the flexible film 77 is flexibly displaced in the direction in which the volume of the pressure chamber 73 is reduced, thereby forcibly opening the communication hole 72. By forcibly opening the communication hole 72 by the valve opening mechanism 81, it is possible to perform pressure cleaning in which the pressurized liquid flows out from the liquid ejecting unit 33.

In this case, the pressurizing flow path 84 may be connected to the depressurizing flow path 49, and the pump 86 may be configured to be capable of driving both pressurization and depressurization. Then, the one-way valve 85 is provided in the depressurizing flow path 49, and the pump 86 is driven to pressurize to send the gas to the pressurizing bag 83, and the pump 86 is depressurized to depressurize the depressurizing chamber 48.

The liquid ejecting unit 33 includes a liquid chamber 91 that communicates with the nozzle 36, a storage unit 93 that is partitioned by the liquid chamber 91 and the vibration plate 92, an actuator 94 that is stored in the storage unit 93, and a liquid that flows out from the pressure chamber 73. And a common liquid chamber 95 that temporarily stores the liquid and supplies the liquid to the plurality of liquid chambers 91. A filter 96 for filtering the liquid may be arranged between the pressure chamber 73 and the common liquid chamber 95.

The actuator 94 is, for example, a piezoelectric element that contracts when a drive voltage is applied. When the vibration plate 92 is deformed due to the contraction of the actuator 94 and then the application of the drive voltage is released, the liquid in the liquid chamber 91 whose volume has changed is ejected from the nozzle 36 as a droplet.

At this time, if bubbles are mixed in the nozzle 36, the droplets are not properly ejected, resulting in ejection failure. Further, when the nozzle 36 is clogged with a foreign substance such as a solid substance, or when the viscosity of the liquid increases due to drying or the like, defective ejection occurs. In order to prevent such ejection failure, it is preferable that the supply channel 37 be provided with a filter unit 41 and filters 76 and 96 to remove foreign matters such as bubbles.

To the common liquid chamber 95, for example, a return flow passage 97 for returning the liquid to the supply flow passage 37 between the filter unit 41 and the opening/closing valve 39 is connected, and the liquid flows from the common liquid chamber 95 toward the return flow passage 97. A circulation pump 98 that allows the return flow passage 97 may be arranged. According to this configuration, the circulation pump 98 is driven to circulate the liquid between the return flow path 97 and the supply flow path 37, so that the filter unit 41 and the filters 76 and 96 in the supply flow path 37 can remove bubbles and the like. A foreign substance can be supplemented. When the liquid contains a sedimentary component such as a pigment, the liquid can be agitated to make the concentration uniform by circulating the liquid or passing it through the static mixer 42.

Next, the configuration of the pressure feeding mechanism 38 will be illustrated.
The pumping mechanism 38 is, for example, a diaphragm pump, and is provided with a pump chamber 61 provided in the middle of a branch flow passage 37 a forming the supply flow passage 37, a displacement member 62 forming a part of the wall surface of the pump chamber 61, and a pump chamber. A spring 63 arranged outside 61 and a displacement mechanism 64 are provided. The displacement member 62 is displaced in a direction in which the volume of the pump chamber 61 is increased or decreased. The spring 63 biases the displacement member 62 in a direction of reducing the volume of the pump chamber 61. However, it is preferable to provide a communication groove 61a in a part of the wall surface of the pump chamber 61 so that the liquid flows even when the volume of the pump chamber 61 is minimized by the biasing force of the spring 63.

The displacement mechanism 64 includes, for example, a gas chamber 65 defined by the pump chamber 61 and the displacement member 62, and an intake pump 67 that sucks the gas chamber 65 through the ventilation path 66. The displacement member 62 is displaced in the direction of increasing the volume of the pump chamber 61 against the urging force of. When the intake pump 67 stops driving, the gas flows into the gas chamber 65 through the air passage 66, and the displacement member 62 is displaced by the biasing force of the spring 63 in the direction of reducing the volume of the pump chamber 61. Good to do.

The pressure feeding mechanism 38 also includes a suction valve 68 provided between the container holding unit 16 and the pump chamber 61, and a discharge valve 69 provided between the pump chamber 61 and the liquid ejecting unit 33. The suction valve 68 is a one-way valve that allows the flow of the liquid flowing into the pump chamber 61 and restricts the flow of the liquid flowing out of the pump chamber 61. The discharge valve 69 is a one-way valve that allows the flow of the liquid flowing out from the pump chamber 61 and restricts the flow of the liquid flowing into the pump chamber 61. Then, the suction pump 67 is driven to perform a suction drive in which the liquid flows into the pump chamber 61, and the suction pump 67 is stopped to drive the suction pump 67 to discharge the liquid from the pump chamber 61 by the urging force of the spring 63. Is done.

Next, the operation of the liquid ejecting apparatus 11 will be described together with the content of control performed by the control unit 100.
When the remaining amount of liquid is large, such as immediately after the liquid container 20 is replaced with a new one, the control unit 100 does not drive the pumping mechanism 38, and the head of the liquid contained in the liquid container 20 with respect to the nozzle 36 causes Supply liquid.

When the communication groove 61a is provided in the pump chamber 61 of the pressure feeding mechanism 38 or the branch flow channel 37b having a different route from the branch flow channel 37a in which the pressure feeding mechanism 38 is arranged is provided, the volume of the pump chamber 61 becomes the largest. Even in the small state, the communication state of the supply flow path 37 between the liquid container 20 and the liquid ejecting unit 33 can be maintained, and the liquid can be supplied by the head of the water.

In the case where the liquid is stored in the liquid storage portion 21, when the remaining amount of the liquid becomes small, it becomes difficult for the liquid to flow out due to the reaction force of the liquid storage portion 21 that is a bag. It is preferable to drive the pumping mechanism 38 to switch to supply. According to this configuration, by driving the pressure feeding mechanism 38, the liquid in the liquid storage portion 21 can be sucked and supplied under pressure to the liquid ejecting portion 33.

<First Embodiment of Tube Pump>
Subsequently, a first embodiment of the tube pump will be described with reference to the drawings.
As shown in FIG. 6, the tube pump 110 of the present embodiment is a tube pump provided in the middle of the tube 111 in which the hollow portion 111a forms a flow path, and for example, the pump 86 of the liquid ejecting apparatus 11 shown in FIG. Alternatively, it can be used as the suction pump 59.

The tube pump 110 includes a frame 112 having a cylindrical inner peripheral surface 112c, and accommodates the tube 111 in a state of being curved in an annular shape along the inner peripheral surface 112c. Further, the tube pump 110 includes a rotating body 120 having a rotating shaft 114 and arranged on the inner peripheral side of the ring 111c of the tube 111, and pressing rollers 113F and 113S rotatably supported by the rotating body 120. Prepare

The frame 112 has two insertion ports 112a and 112b through which the tube 111 is inserted. In the tube 111, the portions that enter the frame 112 from the insertion openings 112a and 112b and start to curve along the inner peripheral surface 112c intersect with each other in the axial direction of the inner peripheral surface 112c. Therefore, there is no portion (leak point) that is interrupted by the ring 111c of the tube 111 in a plan view.

The rotating body 120 is rotated by the power of the driving source 109 about the rotation shaft 114 located on the inner peripheral side of the ring 111c of the tube 111 in the first rotation direction (counterclockwise direction indicated by an arrow in FIG. 6) and the first rotation. It rotates in the second rotation direction (clockwise direction in FIG. 6) which is the opposite direction. The pressing rollers 113F and 113S are revolved while pressing the tube 111 by being locked to the rotating body 120 that rotates in the frame 112. As a result, the fluid in the tube 111 is pumped in the rotation direction of the rotating body 120.

The rotating body 120 includes a first locking portion 121 that locks the first pressing roller 113F when rotating in the first rotation direction, and a second engaging portion that locks the second pressing roller 113S when rotating in the second rotation direction. And a stop 122. Further, the rotating body 120 includes a first guide curved portion 123 that is curved in a spiral shape so as to approach the rotating shaft 114 from the first locking portion 121 toward the first rotation direction, and a second locking portion 122 to a second. The second guide curved portion 124 is curved in a spiral shape so as to approach the rotation shaft 114 in the rotation direction. The pressing rollers 113F and 113S are arranged such that the axial direction of the pressing rollers 113F and 113S is parallel to the rotating shaft 114, and engaging shaft portions 113a that engage with the rotating body 120 are provided on both end sides thereof.

The rotating body 120 of the present embodiment includes a groove-shaped first guide portion 125 in which a first locking portion 121 and a first guide curved portion 123 are formed, and a second locking portion 122 and a second guide curved portion 124. It has the groove-shaped 2nd guide part 126 formed. In the plan view shown in FIG. 6, it is preferable that the first guide portion 125 and the second guide portion 126 are arranged in line symmetry with a straight line passing through the axis of the rotation shaft 114 as an axis of symmetry.

The tube pump 110 of the present embodiment includes, as pressing rollers, a first pressing roller 113F that engages with the first guide portion 125 and a second pressing roller 113S that engages with the second guide portion 126. Then, the first pressing roller 113F and the second pressing roller 113S press different areas of the ring 111c of the tube 111 that is annular in the frame 112.

As shown in FIG. 7, the rotating body 120 includes a rotating shaft 114, a disk-shaped large-diameter plate 115 arranged on one end side of the rotating shaft 114, and a small-diameter plate 116 arranged on the other end side of the rotating shaft 114. And. The large-diameter plate 115 has a first guide portion 125 and a second guide portion 126 formed as through holes, and the small-diameter plate 116 has the first guide portion 125 and the second guide portion 126 formed as cutouts having notched outer edges. Has been formed.

In the pressing rollers 113F and 113S, the engaging shaft portions 113a protruding at both ends in the axial direction are engaged with the guide portions 125 and 126 of the large diameter plate 115 and the small diameter plate 116, respectively. It revolves around the rotating shaft 114. The position where the pressing rollers 113F and 113S are locked to the locking portions 121 and 122 is referred to as a pressing position, and the pressing rollers 113F and 113S are opposite to the locking portions 121 and 122 of the guides 125 and 126. The position when locked to the side end is called the release position. Further, the end portions of the guide portions 125 and 126 opposite to the locking portions 121 and 122 are also part of the guide curved portions 123 and 124, respectively. Even if the pressing rollers 113F and 113S do not necessarily reach the releasing position, the pressing rollers 113F and 113S release the pressing of the tube 111 by moving away from the locking portions 121 and 122, respectively.

Next, the operation of the tube pump 110 will be described.
In FIG. 6, when the fluid is caused to flow from the right side (upstream) to the left side (downstream) of the tube 111 outside the frame 112, the rotator 120 is driven by the power of the drive source 109 in the first rotation direction (indicated by an arrow in FIG. 6 ). Rotate counterclockwise).

Then, as shown in FIG. 6, the first pressing roller 113F is arranged at the pressing position where it is locked by the first locking portion 121 of the first guiding portion 125, and the second pressing roller 113S is positioned at the second guiding portion 126. It is placed in the release position. After that, the first pressing roller 113F revolves along the inner peripheral surface 112c of the frame 112 while pressing the tube 111, and the second pressing roller 113S does not press the tube 111. As a result, the fluid in the tube 111 is pushed out in the first rotation direction, which is the downstream side, and at the same time, the tube 111 in the released portion spreads to suck the fluid from the upstream side.

In addition, when reversing the flow direction of the fluid from this state, the rotation direction of the rotating body 120 is reversed from the first rotation direction to the second rotation direction (clockwise direction in FIG. 6). Then, the first pressing roller 113F locked by the first locking portion 121 moves to the release position while being guided by the first guide curved portion 123. Further, the second pressing roller 113S, which was at the release position of the second guide portion 126, moves to the pressing position while being guided by the second guide curved portion 124, and is locked by the second locking portion 122. In the process of such inversion, one pressing roller 113F releases the pressing of the tube 111, and the two pressing rollers 113F and 113S engage with the guide curved portions 123 and 124 at the same timing to bring the inside of the tube 111 to the atmospheric pressure. After returning, the other pressing roller 113S starts pressing the tube 111.

After that, the first pressing roller 113F revolves along the inner peripheral surface 112c of the frame 112 while the tube 111 is not pressed and the second pressing roller 113S is pressing the tube 111. As a result, the fluid in the tube 111 is pushed out in the second rotation direction, and at the same time, the released portion spreads to suck the fluid.

When the pressure feeding of the fluid is finished, the rotation direction of the rotating body 120 is reversed and the rotation of the rotating body 120 is stopped at the positions where the two pressing rollers 113F and 113S engage with the guide curved portions 123 and 124, respectively. As a result, the driving of the tube pump 110 is stopped while the inside of the tube 111 is returned to the atmospheric pressure. In this way, releasing the pressing by the pressing roller 113 and returning the inside of the tube 111 to the atmospheric pressure is called pump release.

In the guide portions 125 and 126, the shape and length of the guide curved portions 123 and 124 about the rotation shaft 114 may be matched. Then, when the rotating body 120 is reversed, the second pressing roller 113S engages with the second guiding curved portion 124 at the same timing as the first pressing roller 113F engages with the first guiding curved portion 123.

Next, the operation of the tube pump 110 will be described.
In the tube pump 110, when the rotating body 120 rotates in any rotation direction, one of the pressing rollers 113F and 113S can continuously rotate while keeping the state of pressing the tube 111. It can be continuously pumped.

Here, for example, the pressure in the tube 111 that pumps the fluid from upstream to downstream is negative pressure (reduced from the initial pressure at the time of starting the pumping) upstream of the portion pressed by the first pressing roller 113F. State), and a positive pressure (a state in which pressure is higher than the initial pressure at the time of starting pressure feeding) is provided downstream of the position. Therefore, when the guide portions 125 and 126 do not include the guide curved portions 123 and 124, respectively, and when the revolving direction of the pressing rollers 113F and 113S is simply reversed to start the pressure feeding in the reverse direction, the initial pressure at the start of reversal There is a problem that the value of fluctuates. Then, in order to solve this problem, it is necessary to measure the pressure in the tube 111 with a pressure sensor or the like and rotate the rotating body 120 until the target pressure is reached.

In that respect, in the tube pump 110 of the present embodiment, after one of the pressing rollers 113F and 113S releases the pressing of the tube 111 to eliminate the pressurized state and the depressurized state in the tube 111, the pressing rollers 113F and 113S are then pressed. The other one starts to press the tube 111.

That is, when the rotating direction of the rotating body 120 is reversed, the pressing rollers 113F and 113S engage with the first guide curved portion 123 and the second guide curved portion 124 to release the pressing of the tube 111, and thus the tube 111 is released. When the hollow portion 111a is open to the atmosphere at the end of the tube, the pressure inside the tube 111 is reset to atmospheric pressure during the reversal process. Therefore, without providing a pressure sensor or the like, the drive of the tube pump 110 is controlled based on the number of rotations or the rotation angle of the rotating body 120, with the initial pressure when starting pressure feeding in the other direction by reversing being atmospheric pressure. You can

Further, when the driving of the tube pump 110 is stopped, the pressing of the tube 111 can be released by engaging the two pressing rollers 113F and 113S with the guide curved portions 123 and 124, respectively. Therefore, the fluid can be caused to flow through the tube 111 upstream and downstream of the tube pump 110. Further, the load applied to the tube 111 by pressing can be reduced.

According to the above embodiment, the following effects can be obtained.
(1) Since the tube pump 110 includes the one rotating body 120 having the two guide portions 125 and 126 and the pressure rollers 113F and 113S that engage with the guide portions 125 and 126, respectively, the first pressure roller 113F is pressed. Thus, the fluid can be pressure-fed in the first rotation direction, and the fluid can be pressure-fed in the second rotation direction by the pressing of the second pressing roller 113S.

<Second Embodiment of Tube Pump>
Next, a second embodiment of the tube pump will be described with reference to the drawings.
As shown in FIG. 8, the tube pump 110S of the second embodiment is a tube pump in which the hollow portion 111a is provided in the middle of the tube 111 that forms a flow path, as in the first embodiment, so the first embodiment The same reference numerals are given to the same configurations as those, and the description thereof will be omitted. The configurations different from the first embodiment will be mainly described.

The rotating body 120 included in the tube pump 110S has a first locking portion 121 and a second locking portion 122 at both ends, and a first guide curved portion is provided between the first locking portion 121 and the second locking portion 122. It has one guide part 127 in which 123 and the second guide curved part 124 are arranged in series. Then, when one pressing roller 113 is engaged with the guide portion 127 and the rotating direction of the rotating body 120 is reversed, the pressing roller 113 passes through the first guide curved portion 123 and the second guide curved portion 124. , Between the first locking portion 121 and the second locking portion 122.

For example, in FIG. 8, when the fluid is caused to flow from the right side (upstream) to the left side (downstream) of the tube 111 outside the frame 112, the power of the drive source 109 causes the rotating body 120 to rotate in the first rotation direction (see FIG. 8). Rotate counterclockwise (indicated by the arrow).

Then, as shown in FIG. 8, the pressing roller 113 is arranged at the pressing position where it is locked by the first locking portion 121 of the guide portion 127, and then the inner peripheral surface of the frame 112 is pressed with the tube 111 being pressed. Revolves along 112c. As a result, the fluid in the tube 111 is pumped in the downstream first rotation direction.

Further, from this state, when the rotation direction of the rotating body 120 is reversed from the first rotation direction to the second rotation direction (clockwise direction in FIG. 8), the pressing roller 113 locked by the first locking portion 121 is rotated. The engaging shaft portion 113a moves to the release position (shown by the chain double-dashed line in FIG. 8) while being guided by the first guide curved portion 123. As a result, the pressure of the tube 111 by the pressure roller 113 is released, and when the hollow portion 111a is open to the atmosphere at the end of the tube 111, the inside of the tube 111 returns to atmospheric pressure.

Subsequently, when the pressing roller 113 in the release position moves to the pressing position where it is locked by the second locking portion 122 while being guided by the second guide curved portion 124, the pressing roller 113 presses the tube 111. It revolves along the inner peripheral surface 112c of the frame 112. As a result, the fluid in the tube 111 is pumped in the second rotation direction.

When the fluid pumping is completed, the rotation direction of the rotating body 120 is reversed, and the rotation body 120 is stopped at the position where the pressing roller 113 engages the first guide curved portion 123 or the second guide curved portion 124. As a result, the driving of the tube pump 110 is stopped in a state where the pressing of the ring 111c by the pressing roller 113 is released and the inside of the tube 111 is reset to atmospheric pressure.

According to the above embodiment, the following effects can be obtained.
(2) Since only one pressing roller 113 and one guiding portion 127 need be provided, the configuration can be simplified.

<Third Embodiment of Tube Pump>
Next, a third embodiment of the tube pump will be described with reference to the drawings.
As shown in FIG. 9, the tube pump 110T of the third embodiment is a tube pump in which the hollow portion 111a is provided in the middle of the tube 111 that forms a flow path, as in the first embodiment, so the first embodiment The same reference numerals are given to the same configurations as those, and the description thereof will be omitted. The configurations different from the first embodiment will be mainly described.

The tube pump 110T of the present embodiment includes a first pump 108F and a second pump 108S that are arranged in the axial direction (the center of the axis is shown by a dashed line in FIG. 9). The tube pump 110T includes, as the frame 112, a first frame 112F that configures the first pump 108F and a second frame 112S that configures the second pump 108S. Further, the tube pump 110T includes a power transmission mechanism 131 that transmits the power of the drive source 109 to the first pump 108F and the second pump 108S.

For example, when the tube pump 110T is the pump 86 shown in FIG. 5, the exposed portion 111f exposed from the first frame 112F of the tube 111 shown in FIG. The pressurizing flow path 84 and the depressurizing flow path 49 are connected to a branching portion so as to communicate with the depressurizing flow path 49 for depressurizing the depressurizing chamber 48. When the pressurized gas is discharged from the end portion 111e of the tube 111 in accordance with the driving of the tube pump 110T, if the end portion 111e is arranged toward the drive source 109 or the like, the exhaust gas is used for cooling the drive source 109. You can The object to be cooled is not limited to the drive source 109, but may be a motor or a power supply circuit that drives other components.

A portion of the tube 111 that is connected to the exposed portion 111f enters the first frame 112F through the insertion opening 112a of the first pump 108F, and the tube 111 that exits from the insertion opening 112b of the first frame 112F is the insertion opening 112a of the second pump 108S. Through the second frame 112S. Then, the end of the tube 111 that has come out of the insertion port 112b of the second frame 112S is the end portion 111e.

As shown in FIG. 10, the tube pump 110T has, as the rotating body 120, a first rotating body 120F having a first guide portion 125 and accommodated in the first frame 112F, and a second guide portion 126. The second rotating body 120S housed in the second frame 112S. Pressing rollers 113F and 113S engage with the guide portions 125 and 126, respectively. In addition, the tube pump 110T includes a first rotating shaft 114F that is a separate body from the first rotating body 120F, and a second rotating shaft 114S that is a separate body from the second rotating body 120S.

The first rotating body 120F and the second rotating body 120S are arranged side by side in the axial direction of the rotating shafts 114F and 114S that are rotated by the power of the one drive source 109 (see FIG. 9). The tube 111 forms a ring 111c in which portions housed in the frames 112F and 112S surrounding the rotating bodies 120F and 120S are different from each other. The pressing rollers 113F and 113S press the regions of the tube 111 forming the different rings 111c, respectively.

For example, when the rotating bodies 120F and 120S rotate in the first rotation direction indicated by the arrow in FIG. 10, the first pressing roller 113F presses the tube 111, and the second pressing roller 113S does not press the tube 111. It revolves in the state, and the fluid is pumped from the end portion 111e of the tube 111 toward the exposed portion 111f. In addition, when the rotating bodies 120F and 120S rotate in the second rotation direction, the first pressing roller 113F revolves without pressing the tube 111, and the second pressing roller 113S revolves while pressing the tube 111. The fluid is pumped from the exposed portion 111f of the 111 toward the end portion 111e.

The power of the drive source 109 (see FIG. 9) is transmitted to the first rotating body 120F via the first rotating shaft 114F, and further, from the first rotating body 120F via the second rotating shaft 114S to the second rotating body 120S. Be transmitted to. Here, the power transmission mechanism 131 preferably includes a rotation delay unit 132 that delays the rotation of the first rotary body 120F and transmits the delayed rotation to the second rotary shaft 114S and the second rotary body 120S.

As shown in FIG. 11, the rotation delay part 132 includes, for example, a first rotating member 133 having an engaging protrusion 133a and a second rotating member 134 having a cam groove 134a with which the engaging protrusion 133a can be engaged. , Composed by. The cam groove 134a has an arc shape extending along a circumference centered on the axis of the second rotating shaft 114S. The second rotating member 134 also has a locking protrusion 134b that forms the start end and the end of the cam groove 134a.

The first rotating member 133 is assembled so as to rotate integrally with the first rotating shaft 114F, and the second rotating member 134 is assembled so as to rotate integrally with the second rotating shaft 114S. In addition, the first rotating member 133 and the second rotating member 134 are combined in such a manner that the engaging protrusion 133a of the first rotating member 133 is inserted into the cam groove 134a of the second rotating member 134.

In this configuration, when the first rotating shaft 114F rotates in the first rotating direction indicated by the arrow in FIG. 11, the first rotating body 120F rotates about the first rotating direction and the first pressing roller 113F presses the tube 111. Further, when the first rotation member 133 rotates together with the first rotation shaft 114F, the engagement protrusion 133a rotates along the cam groove 134a. When the engagement protrusion 133a hits the locking protrusion 134b, the engagement protrusion 133a pushes the second rotation member 134 to start rotation. Then, the second rotating shaft 114S and the second rotating body 120S rotate together with the second rotating member 134 in the first rotation direction. As described above, the rotation of the first rotating body 120F is transmitted to the second rotating body 120S with a delay of the rotation angle at which the engagement protrusion 133a rotates along the cam groove 134a.

When the rotating direction of the first rotating shaft 114F is reversed from this state, the first rotating body 120F rotates in the second rotating direction, and the first pressing roller 113F moves from the pressing position to the releasing position to press the tube 111. To release. During this time, the first rotating member 133 rotates together with the first rotating shaft 114F, but while the engaging protrusion 133a rotates in the second rotating direction along the cam groove 134a, the second rotating member 134 keeps the first rotating member 133. The second rotating shaft 114S and the second rotating body 120S do not rotate because they are not pushed. Therefore, when the first pressing roller 113F moves away from the pressing position to the first guide curved portion 123, the inside of the tube 111 is reset to atmospheric pressure.

When the engaging protrusion 133a rotating in the second rotation direction hits the locking protrusion 134b, the second rotating shaft 114S and the second rotating body 120S together with the second rotating member 134 are allowed to rotate in the second rotating direction. Start. As a result, the second pressing roller 113S moves from the second guiding curved portion 124 to the second locking portion 122, and revolves while pressing the tube 111. In this way, even when the first rotating body 120F is reversed, the rotation thereof is transmitted to the second rotating body 120S with a delay by the rotation angle at which the engagement protrusion 133a rotates along the cam groove 134a. ..

One or a plurality (two in this embodiment) of urging members 129 are respectively interposed between the rotating bodies 120F and 120S and the rotating shafts 114F and 114S, and the pressing roller 113F is interposed via the rotating bodies 120F and 120S. , 113S is preferably biased toward the tube 111. As the biasing member 129, for example, a spring such as a coil spring or a leaf spring can be used. When the urging member 129 is a coil spring, the rotation shafts 114F and 114S are provided with locking recesses 114a for accommodating the base end portions of the urging members 129, and the rotating bodies 120F and 120S accommodate the tip end portions of the urging members 129. It is advisable to provide a locking recess 120a for this.

Further, it is preferable that the rotating shafts 114F and 114S are provided with a protruding portion 114b protruding from the center of the shaft so as to widen the outer diameter, and the engaging recess 114a is formed in the protruding portion 114b. Further, in the rotating bodies 120F and 120S, the depth of the locking recess 120a may be set so that the internal space of the locking recess 120a includes the axial center.

By doing so, as shown in FIG. 12, the biasing member 129 can be arranged so as to overlap the axial center. As a result, the diameter of the frames 112F and 112S can be made smaller than in the case where the biasing member 129 is arranged between the shaft center and the pressing rollers 113F and 113S.

Further, for example, in the second pump 108S shown in FIG. 12, when the second pressing roller 113S moves between the second guide curved portion 124 and the second locking portion 122, the biasing force of the biasing member 129 acts strongly. Thus, it is preferable to set the biasing direction (indicated by the arrow in FIG. 12) by the biasing member 129. Similarly, in the first pump 108F, the first pressing roller 113F is urged so that the urging force of the urging member 129 acts when the first pressing roller 113F moves between the first guide curved portion 123 and the first locking portion 121. It is preferable to set the biasing direction by the member 129.

According to the above embodiment, the following effects can be obtained.
(3) Since the pressing rollers 113F and 113S are urged by the urging member 129 via the rotating bodies 120F and 120S, the pressing rollers 113F and 113S have the guide curved portions 123 and 124 and the locking portions 121 and 122, respectively. When moving between, the pressing of the tube 111 can be accurately started or released.

(4) Since the first pressing roller 113F and the first rotating body 120F and the second pressing roller 113S and the second rotating body 120S are housed in different frames 112F and 112S, respectively, they are attached so as to overlap with the axis center. A biasing member 129 can be arranged. On the other hand, when the two pressing rollers 113F and 113S housed in one frame 112 are respectively biased by the biasing member 129, the biasing member 129 should be arranged between the center of the shaft and the pressing rollers 113F and 113S. Therefore, the diameter of the frames 112F and 112S is increased by the length of the biasing member 129. Therefore, according to the present embodiment, it is possible to suppress an increase in the diameter of the frame 112 due to the arrangement of the biasing member 129.

(5) As the diameters of the frames 112F and 112S become smaller, the lengths of the guide curving portions 123 and 124 become shorter, so that the pressing rollers 113F and 113S are engaged with the guide curving portions 123 and 124 at the same timing, respectively. It becomes difficult to release the pressing of 111. In that respect, the rotation delay unit 132 delays the rotation of the first rotating body 120F and transmits the delayed rotation to the second rotating body 120S, so that one of the pressing rollers 113F and 113S releases the pressing for the delayed time. After that, the time until the other of the pressing rollers 113F and 113S moves to the pressing position can be lengthened. Therefore, even if the guide curved portions 123 and 124 are small-diameter frames 112F and 112S having short diameters, it is easy to realize a configuration in which the pressing rollers 113F and 113S release the pressing at the same timing. Further, the timing of starting the next pressure feeding after reversing the rotation can be adjusted by the length of the cam groove 134a.

The above-described embodiment may be modified as in the following modification examples. Further, the configurations included in the above-described embodiment and the configurations included in the following modification examples may be arbitrarily combined, or the configurations included in the following modification examples may be arbitrarily combined.

-As in the modified example shown in FIG. 13, the pumping mechanism 38 may be a tube pump provided in the middle of the flexibly displaceable tube 101 forming the supply flow path 37. In this case, the pressure feeding mechanism 38 includes a pressing roller 102 that presses the tube 101 and a moving mechanism 103 that moves the pressing roller 102, and the moving mechanism 103 moves the pressing roller 102 that presses the tube 101. To pump the liquid.

The moving mechanism 103 includes, for example, a cylindrical frame 104 that houses the tube 101, a rotating body 106 that has a guide groove 105 that locks the pressing roller 102 and is housed in the frame 104, and a drive source (not shown). And a rotating shaft 107 that rotates by a driving force. Then, the rotating body 106 rotates with the rotating shaft 107 to revolve the pressing roller 102. The hollow portion of the tube 101 forms the supply channel 37, the right side in FIG. 13 is the upstream side of the supply channel 37, and the left side in FIG. 13 is the downstream side of the supply channel 37.

The guide groove 105 is changed in distance from the rotation center, and when the pressing roller 102 is locked to the locking portion 105a arranged at the first end of the guide groove 105 farther from the rotation center, the tube 101 is moved. The pressing of the tube 101 may be released when the pressing roller 102 approaches the second end 105b closer to the rotation center of the guide groove 105. In this case, when the rotating body 106 rotates in the first rotation direction shown by the arrow in FIG. 13, the pressing roller 102 locked by the locking portion 105a moves while pressing the tube 101, so that the liquid in the tube 101 Pumped. Further, when the rotating body 106 rotates in the second rotation direction which is the opposite direction to the first rotation direction, the pressing roller 102 moves toward the second end 105b of the guide groove 105, and the pressing of the tube 101 is released. , The liquid is no longer pumped.

In this case, the control unit 100 controls the moving mechanism 103 to release the pressing of the tube 101 by the pressing roller 102 when switching the liquid supply by the pumping mechanism 38, which is a tube pump, to the liquid supply by the water head. Good. According to this configuration, the communication state of the supply flow path 37 between the liquid container 20 and the liquid ejecting unit 33 can be maintained even if the liquid is not pumped by the tube pump, and the liquid head is caused to flow. Can be supplied.

The tube pumps 110, 110S, 110T of the above-described embodiment can reverse the flow direction of the fluid, whereas the tube pump as the pressure feeding mechanism 38 shown in FIG. 13 allows the fluid to flow only in one direction. .. Then, in the tube pump shown in FIG. 13, when the rotation direction is reversed, the pressing of the tube 101 is released and the pressure feeding is completed. On the other hand, in the tube pumps 110, 110S, 110T, when the rotation direction is reversed, the pressure of the tube 111 is released, and then the fluid is started to be pumped in the opposite direction.

The pumping mechanism 38 sends out the pressurized gas to the liquid container 20 (for example, the space between the case 22 and the liquid container 21) mounted on the container holder 16 so that the inside of the liquid container 20 is discharged. The liquid may be pressurized and allowed to flow out to the supply channel 37.

The liquid ejecting apparatus 11 may supply the liquid by driving the pressure feeding mechanism 38 at all times without supplying the liquid by the head of water.
-As in the modification shown in Fig. 14, the container holding unit 16 may not move. Further, the container holding portion 16 may be arranged on the carriage 32.

The liquid ejecting apparatus 11 does not have to include the support leg portion 13 as in the modification shown in FIG. Further, in the liquid ejecting apparatus 11, instead of the feeding mechanism 25, the winding mechanism 26, and the tension bar 27, a cassette 28 containing a medium S which is a cut sheet cut into a predetermined size is detachably mounted. You may do it.

The degassing chamber 46 of the degassing mechanism 45 may be provided in the supply flow path 37 that connects the pressure chamber 73 of the pressure adjusting mechanism 70 and the filter 96 of the liquid ejecting unit 33. Alternatively, the deaeration chamber 46 of the deaeration mechanism 45 may be provided in a region of the supply passage 37 that is not located on the carriage 32.

The liquid ejected by the liquid ejecting unit 33 is not limited to ink, and may be, for example, a liquid material in which particles of a functional material are dispersed or mixed in the liquid. For example, a liquid material containing materials such as electrode materials and coloring materials (pixel materials) used in the manufacture of liquid crystal displays, EL (electroluminescence) displays and surface-emitting displays in a dispersed or dissolved state is jetted for recording. It may be configured.

The medium S is not limited to paper, and may be a plastic film, a thin plate material, or the like, or may be a cloth used in a textile printing device or the like. In addition, the medium S may be clothing of any shape such as a T-shirt, or may be a three-dimensional object of any shape such as tableware or stationery.

Below, the technical idea and its effects obtained from the above-described embodiments and modifications will be described.
[Thought 1]
A tube pump in which a hollow part is provided in the middle of a tube forming a flow path,
A frame for accommodating the tube in an annularly curved state,
A rotating body that is rotated by a power of a driving source in a first rotation direction and a second rotation direction that is a direction opposite to the first rotation direction around a rotation shaft located on the inner peripheral side of the ring of the tube;
A pressing roller that revolves while pressing the tube by being locked to the rotating body that rotates,
Equipped with
The rotating body includes a first locking portion that locks the pressing roller when rotating in the first rotation direction, and a second locking portion that locks the pressing roller when rotating in the second rotation direction. A first guide curved portion curved in a spiral shape so as to approach the rotation axis from the first locking portion, and a second guide curved portion curved in a spiral shape so as to approach the rotation axis from the second locking portion And a section,
A tube pump, wherein the pressing roller engages the first guide curved portion and the second guide curved portion to release the pressing of the tube when the rotating direction of the rotating body is reversed. ..

According to the above [Concept 1], while the rotating body is rotating in the first rotating direction or the second rotating direction, the pressing roller is locked by the rotating body and revolves while pressing the tube. The fluid can be continuously pumped with the rotation. Further, since the pressing roller engages with the first guide curved portion and the second guide curved portion when the rotating direction of the rotating body is reversed, the pressing of the tube can be released at the timing of reversing the pressure feeding direction.

[Thought 2]
The rotating body has the first locking portion and the second locking portion at both ends, and the first guide curved portion and the second locking portion are provided between the first locking portion and the second locking portion. The guide curved portion has a guide portion arranged continuously,
When the rotation direction of the rotating body is reversed, the pressing roller passes through the first guide curved portion and the second guide curved portion, and is between the first locking portion and the second locking portion. The tube pump according to [Concept 1], wherein the tube pump is moved.

According to the above [Idea 2], in the guide portion, the first guide curved portion and the second guide curved portion are continuously arranged between the first locking portion and the second locking portion at both ends. Therefore, the pressing of the tube by the pressing roller can be released when the rotating body is reversed in any rotation direction.

[Thought 3]
The rotating body includes a first guide portion having the first locking portion and the first guide curved portion, and a second guide portion having the second locking portion and the second guide curved portion. Have
As the pressing roller, a first pressing roller that engages with the first guide portion and a second pressing roller that engages with the second guide portion are provided,
The tube pump according to [Idea 1], wherein the second pressing roller engages with the second guide curved portion at a timing when the first pressing roller engages with the first guide curved portion.

According to the above [Concept 3], different pressure rollers are locked to the two guide portions, but since the pressure rollers engage with the guide curved portions at the same timing, the rotating body is reversed from any rotation direction. Even when this is done, the pressing of the tube by the pressing roller can be released.

[Thought 4]
The tube pump according to [Idea 3], wherein the first pressing roller and the second pressing roller press different areas of the tube.

According to the above [Concept 4], the first pressing roller and the second pressing roller that press different regions of the tube engage with the first guide curved portion and the second guide curved portion at the same timing, thereby Can be returned to atmospheric pressure.

[Thought 5]
As the rotating body, a first rotating body having the first guide portion and a second rotating body having the second guide portion are provided,
The tube according to [Idea 4], wherein the first rotating body and the second rotating body are arranged so as to be aligned in the axial direction of the rotating shaft that is rotated by the power of the one drive source. pump.

According to the above [Concept 5], since the two rotating bodies each have the first guide portion and the second guide portion, the diameter of the rotating body can be made smaller than that in the case where the two rotating bodies are provided in one rotating body. You can

[Thought 6]
A power transmission mechanism for transmitting the power of the drive source to the rotating body,
The tube pump according to [Concept 5], wherein the power transmission mechanism includes a rotation delay unit that delays rotation of the first rotating body and transmits the delayed rotation to the second rotating body.

According to the above [Concept 6], the rotation of the first rotating body is delayed and transmitted to the second rotating body, so that after the first pressing roller engages with the first guide curved portion, the second pressing roller moves to the first guiding roller. The first pressing roller can be engaged with the first guide curved portion until it is engaged with the second guide curved portion. As a result, it becomes easy to engage the two pressing rollers with different guide curved portions at the same timing.

[Thought 7]
A liquid ejecting section which has a nozzle and ejects a liquid from the nozzle;
A tube whose hollow portion forms a flow path,
A tube pump provided in the middle of the tube,
Equipped with
The tube pump is
A frame for accommodating the tube in an annularly curved state,
A rotating body that is rotated by a power of a driving source in a first rotation direction and a second rotation direction that is a direction opposite to the first rotation direction around a rotation shaft located on the inner peripheral side of the ring of the tube;
A pressing roller that revolves while pressing the tube by being locked to the rotating body that rotates,
Equipped with
The rotating body includes a first locking portion that locks the pressing roller when rotating in the first rotation direction, and a second locking portion that locks the pressing roller when rotating in the second rotation direction. A first guide curved portion curved in a spiral shape so as to approach the rotation axis from the first locking portion, and a second guide curved portion curved in a spiral shape so as to approach the rotation axis from the second locking portion And a section,
The pressure roller engages with the first guide curved portion and the second guide curved portion to release the pressure on the tube when the rotating direction of the rotating body is reversed. apparatus.

According to [Concept 7], the same effect as that of [Concept 1] can be obtained.

11... Liquid ejecting apparatus, 12... Casing, 20... Liquid container, 33... Liquid ejecting section, 34... Support section, 35... Conveying mechanism, 36... Nozzle, 37... Supply channel, 86... Pump, 100... Control Part, 108F... 1st pump, 108S... 2nd pump, 109... drive source, 110... tube pump, 110S... tube pump, 110T... tube pump, 111... tube, 111a... hollow part, 111c... ring, 111e... end Part, 111f... Exposed part, 112... Frame, 112a... Insertion port, 112b... Insertion port, 112c... Inner peripheral surface, 112F... First frame, 112S... Second frame, 113... Pressing roller, 113a... Engaging shaft part , 113F... First pressing roller, 113S... Second pressing roller, 114... Rotating shaft, 114a... Locking recess, 114b... Projection, 114F... First rotating shaft, 114S... Second rotating shaft, 115... Large diameter plate , 116... Small diameter plate, 120... Rotating body, 120a... Locking recess, 120F... First rotating body, 120S... Second rotating body, 121... First locking portion, 122... Second locking portion, 123... 1 guide curve part, 124... 2nd guide curve part, 125... 1st guide part, 126... 2nd guide part, 127... Guide part, 129... Energizing member, 131... Power transmission mechanism, 132... Rotation delay part, 133... 1st rotation member, 133a... Engagement projection, 134... 2nd rotation member, 134a... Cam groove, 134b... Locking projection, S... Medium.

Claims (5)

A tube pump in which a hollow part is provided in the middle of a tube forming a flow path,
A frame that has a cylindrical inner peripheral surface, and accommodates the tube in a state in which the tube is curved in an annular shape without a portion interrupted along the inner peripheral surface,
A first rotating body that is rotated by a power of a drive source in a first rotating direction and a second rotating direction that is an opposite direction of the first rotating direction around a rotating shaft located on the inner peripheral side of the ring of the tube. And a second rotating body,
A first pressing roller that revolves while pressing the tube by being locked by the first rotating body that rotates,
A second pressing roller that revolves while pressing the tube by being locked by the second rotating body that rotates;
A power transmission mechanism that transmits the power of the drive source to the first rotating body and the second rotating body;
Equipped with
The first rotating body has a first locking portion that locks the first pressing roller when rotating in the first rotation direction, and a first curved portion that approaches the rotation shaft from the first locking portion. A guide curved portion, and a first guide portion that is formed to engage with the first pressing roller,
The second rotating body has a second locking portion that locks the second pressing roller when rotating in the second rotation direction, and a second curved portion that is curved from the second locking portion toward the rotation shaft. A guide curved portion, and a second guide portion that is formed to engage with the second pressing roller,
The second pressing roller engages with the second guiding curved portion at a timing when the first pressing roller engages with the first guiding curved portion,
The first pressing roller and the second pressing roller press different areas of the tube,
The first pressing roller engages the first guide curved portion when the rotation direction of the first rotating body is reversed to release the pressing of the tube,
When the rotation direction of the second rotating body is reversed, the second pressing roller engages with the second guide curved portion to release the pressing of the tube,
The power transmission mechanism includes a rotation delay unit that delays rotation of the first rotating body and transmits the delayed rotation to the second rotating body when the rotation direction of the first rotating body is reversed. .. The tube pump according to claim 1, wherein the first rotating body and the second rotating body are arranged so as to be aligned in the axial direction of the rotating shaft that is rotated by the power of the one drive source. .. A tube pump in which a hollow part is provided in the middle of a tube forming a flow path,
A frame that has a cylindrical inner peripheral surface, and accommodates the tube in a state in which the tube is curved in an annular shape without a portion interrupted along the inner peripheral surface,
A rotating body that is rotated by a power of a driving source in a first rotation direction and a second rotation direction that is a direction opposite to the first rotation direction around a rotation shaft located on the inner peripheral side of the ring of the tube;
A pressing roller that has an engaging shaft portion and revolves around the axis of the rotating shaft while pressing the tube by being locked to the rotating body that rotates.
Equipped with
The rotating body includes a first locking portion that locks the engaging shaft portion of the pressing roller when rotating in the first rotation direction, and the engaging shaft of the pressing roller when rotating in the second rotation direction. A second locking part for locking the part is provided at both ends, and the first locking part and the second locking part are connected to the rotary shaft between the first locking part and the second locking part. The guide curved portion curved so as to approach has a guide portion arranged continuously,
The pressing roller moves between the first locking portion and the second locking portion when the engagement shaft portion passes through the guide curved portion when the rotation direction of the rotating body is reversed. , Releasing the pressing of the tube by engaging the guide curved portion,
The tube pump, wherein when the engagement shaft portion engages with the guide curved portion, the guide curved portion restricts movement of the engagement shaft portion in a radial direction around the rotation shaft. A liquid ejecting section which has a nozzle and ejects a liquid from the nozzle;
A tube whose hollow portion forms a flow path,
A tube pump provided in the middle of the tube,
Equipped with
The tube pump is
A frame that has a cylindrical inner peripheral surface, and accommodates the tube in a state in which the tube is curved in an annular shape without a portion interrupted along the inner peripheral surface,
A first rotating body that is rotated by a power of a drive source in a first rotating direction and a second rotating direction that is an opposite direction of the first rotating direction around a rotating shaft located on the inner peripheral side of the ring of the tube. And a second rotating body,
A first pressing roller that revolves while pressing the tube by being locked by the first rotating body that rotates,
A second pressing roller that revolves while pressing the tube by being locked by the second rotating body that rotates;
A power transmission mechanism that transmits the power of the drive source to the first rotating body and the second rotating body;
Equipped with
The first rotating body includes a first locking portion that locks the first pressing roller when rotating in the first rotation direction, and a first curved portion that approaches the rotation shaft from the first locking portion. A guide curved portion, and a first guide portion that is formed to engage with the first pressing roller,
The second rotary body has a second locking portion that locks the second pressing roller when rotating in the second rotation direction, and a second curved portion that is curved from the second locking portion toward the rotation axis. A guide curved portion, and a second guide portion that is formed to engage with the second pressing roller,
The second pressing roller engages with the second guiding curved portion at a timing when the first pressing roller engages with the first guiding curved portion,
The first pressing roller and the second pressing roller press different areas of the tube,
The first pressing roller engages the first guide curved portion when the rotation direction of the first rotating body is reversed to release the pressing of the tube,
When the rotation direction of the second rotating body is reversed, the second pressing roller engages with the second guide curved portion to release the pressing of the tube,
The liquid ejection mechanism includes a rotation delay unit that delays rotation of the first rotating body and transmits the delayed rotation to the second rotating body when the rotation direction of the first rotating body is reversed. apparatus. A liquid ejecting section which has a nozzle and ejects a liquid from the nozzle;
A tube whose hollow portion forms a flow path,
A tube pump provided in the middle of the tube,
Equipped with
The tube pump is
A frame that has a cylindrical inner peripheral surface, and accommodates the tube in a state in which the tube is curved in an annular shape without a portion interrupted along the inner peripheral surface,
A rotating body that is rotated by a power of a driving source in a first rotation direction and a second rotation direction that is a direction opposite to the first rotation direction around a rotation shaft located on the inner peripheral side of the ring of the tube;
A pressing roller that has an engaging shaft portion and revolves around the axis of the rotating shaft while pressing the tube by being locked to the rotating body that rotates.
Equipped with
The rotating body includes a first locking portion that locks the engaging shaft portion of the pressing roller when rotating in the first rotation direction, and the engaging shaft of the pressing roller when rotating in the second rotation direction. A second locking part for locking the part is provided at both ends, and the first locking part and the second locking part are connected to the rotary shaft between the first locking part and the second locking part. The guide curved portion curved so as to approach has a guide portion arranged continuously,
The pressing roller moves between the first locking portion and the second locking portion when the engagement shaft portion passes through the guide curved portion when the rotation direction of the rotating body is reversed. , Releasing the pressing of the tube by engaging the guide curved portion,
When the engagement shaft portion engages with the guide curved portion, the guide curved portion restricts movement of the engagement shaft portion in a radial direction around the rotation shaft. ..

Images