KR20140131739A - Reservoir of fluid discharging apparatus - Google Patents

Abstract

A reservoir of a fluid discharging apparatus includes: a fluid tank including a storage area that stores fluid, which has already been stored; a heater that maintains the temperature of the fluid, which has already been stored; and a preheating part which preheats fluid, which is newly injected. The newly injected fluid is transferred to the storage area after being heated. Therefore, the temperature and the viscosity of the fluid, which has already been stored, are not changed; and the fluid, which has already been stored, can be uniformly discharged.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a reservoir of a fluid discharging apparatus,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a reservoir of a fluid discharge apparatus, and more particularly, to a reservoir of a fluid discharge apparatus that uniformly discharges a fluid.

The fluid ejection apparatus includes a reservoir for storing a fluid to be ejected before the ejection of the fluid and maintaining the temperature of the fluid, and a reservoir for storing the ink is also included in the inkjet printer, which is one of the fluid ejection apparatuses.

A liquid crystal is injected through inkjet printing in the production of a liquid crystal display device. In the inkjet printing, the liquid crystal is ejected through the fine nozzles. When the viscosity of the liquid crystal is increased, the nozzles are clogged or the liquid crystal is not uniformly ejected. Therefore, the reservoir maintains the temperature of the liquid crystal to keep the viscosity of the liquid crystal constant, .

On the other hand, when the liquid crystal is injected into the reservoir, the injected liquid crystal is already heated in the reservoir and combined with the stored liquid crystal, and is discharged through the discharge port. However, since the initial temperature of the injected liquid crystal is lower than the temperature of the liquid crystal stored in the reservoir, the temperature of the liquid crystal stored in the reservoir is not uniformly maintained when the liquid crystal is newly injected. Accordingly, the viscosity of the liquid crystal stored in the reservoir is changed, and the amount of discharged liquid crystal becomes uneven.

An object of the present invention is to provide a reservoir of a fluid discharge device which uniformly discharges a fluid.

The reservoir of the fluid ejection apparatus according to the present invention includes a reservoir for storing the reservoir fluid, an injection port for injecting the fresh injection fluid from the outside, and a discharge port for discharging the reservoir fluid from the reservoir to the outside; A heater disposed outside the fluid tank to generate heat and to transfer the heat to the fluid tank to maintain the temperature of the fluid; And a preheating unit for supplying the new injection fluid from the injection port, preheating the new injection fluid, and delivering the fresh injection fluid to the storage region.

The injection port is formed on the upper side of the preheating part, and the ejection port is formed on the lower side of the preheating part.

The preheater includes a base plate having a flat plate shape, and the base plate moves the fresh injection fluid injected from the injection port along the upper surface of the base plate to transfer the fluid to the storage area.

The preheating unit includes a preheating wall formed along an edge of the base plate to preheat the freshly injected fluid in the preheated portion and transfer it to the storage region.

The base plate is formed by inclining the upper surface of the base plate and the inner side surface of the fluid tank so as to form an acute angle.

The preheater may include: a first hole for injecting the fresh injection fluid from the injection port; And a pipe having a second hole for discharging the new injection fluid from the preheater to the storage region.

The preheating portion is formed of an aluminum alloy.

Wherein the storage region further includes a discharge region and a non-discharge region in contact with the discharge port, wherein the fluid tank has a height of the base storage fluid filled in the discharge region, the height of the base storage fluid filled in the non- And a step on the lower surface of the fluid tank.

The fluid tank may further include a plurality of heat transfer plates formed on one side of the fluid tank so as to be removable from the one side and extending inward of the fluid tank.

The reservoir of the fluid ejecting apparatus is used in an inkjet printing apparatus.

The fresh injection fluid and the base storage fluid include liquid crystal inks.

According to another aspect of the present invention, there is provided a fluid ejection apparatus including a storage region for storing a storage fluid, including a discharge region and a non-discharge region, an injection port for supplying a fresh injection fluid from the outside to the non-discharge region, And a discharge port for discharging the pre-stored fluid to the outside; A heater disposed outside the fluid tank to generate heat and to transfer the heat to the fluid tank to maintain the temperature of the fluid; And a first barrier plate disposed at a boundary between the discharge region and the non-discharge region.

13. The apparatus of claim 12, further comprising a plurality of second barrier plates that divide the non-ejection area into a plurality of sub-ejection areas.

And a preheating unit for supplying the new injection fluid from the injection port and preheating the new injection fluid to transfer the new injection fluid to the storage region.

The first barrier plate is formed of an aluminum alloy.

The fluid tank further includes a plurality of heat transfer plates formed to be detachable from one side of the fluid tank and extending from the one side toward the interior of the fluid tank.

The reservoir of the fluid ejecting apparatus is used in an inkjet printing apparatus.

The fresh injection fluid and the base storage fluid include liquid crystal inks.

According to the above description, the reservoir of the fluid discharge device according to the embodiment of the present invention preheats the injected fluid and moves it to the fluid tank. Therefore, the temperature of the fluid stored in the fluid tank is prevented from being changed, and the fluid is uniformly discharged.

1 is a perspective view of a reservoir of a fluid discharge device according to an embodiment.
2 is a sectional view of the reservoir of the fluid discharge device shown in Fig.
3 is a perspective view of a preheating portion according to another embodiment.
4 is a sectional view of the reservoir of the fluid discharge device including the preheating portion shown in Fig.
5 is a perspective view of a preheating unit according to another embodiment.
6 is a sectional view of the reservoir of the fluid discharge device including the preheating portion shown in Fig.
7 is a cross-sectional view of a reservoir of a fluid discharge device according to another embodiment.
8 is a perspective view of a reservoir of a fluid discharge device according to another embodiment.
9 is a sectional view of the reservoir of the fluid discharge device shown in Fig.
10 is a perspective view of a reservoir of the fluid discharge device according to another embodiment.
11 is a perspective view of a reservoir of the fluid discharge device according to yet another embodiment.
12 is a perspective view of a reservoir of the fluid discharge device according to yet another embodiment.

Hereinafter, a reservoir of a fluid ejection apparatus according to an embodiment of the present invention will be described with reference to the drawings. In the drawings, the scale of some components is exaggerated or reduced in order to clearly represent layers and regions. Like reference numerals refer to like elements throughout the specification. And, a configuration is formed (placed) on another configuration includes not only when the two configurations are in contact with each other but also when there are other configurations between the two configurations. Also, although one surface of a certain configuration is shown as being flat in the drawings, it is not necessarily required to be flat.

1 is a perspective view of a reservoir of a fluid discharge device according to an embodiment. Referring to Fig. 1, a reservoir 1000 of a fluid discharge apparatus includes a fluid tank 100, a heater 200, and a preheating unit 300.

The fluid to be stored and discharged into the fluid ejection apparatus 1000 will be described as a fresh injection fluid La and a storage fluid Lb for detailed explanation. The new infusion fluid La is stored in an external fluid reservoir (not shown) and is newly injected into the fluid tank 100 through the injection port 110. The reservoir fluid Lb is supplied to the fresh infusion fluid La Is stored and heated in the fluid tank 100 before being injected into the fluid tank 100. Therefore, the temperature of the new infusion fluid La is lower than the temperature of the base fluid Lb.

The fluid tank 100 includes a storage region 130 for storing the storage fluid Lb, an inlet 110 for receiving the fresh fluid La from the outside and a storage fluid Lb from the storage region 130 And a discharge port 120 for discharge to the outside. The fluid tank 100 has a certain volume so as to store the holding fluid Lb therein. The fluid tank 100 is made of a material having a high thermal conductivity to conduct heat received from the heater 200 to the fresh injection fluid La and the storage fluid Lb and is preferably made of a metal such as aluminum or an aluminum alloy .

The injection port 110 is formed on the upper side of the preheating part 300. Specifically, it is formed on the upper surface of the edge of the fluid tank 100, and is connected to an external fluid reservoir to inject the fresh fluid injecting fluid La from the fluid reservoir.

Storage fluid Lb is temporarily stored in the storage area 130 of the fluid tank 100 in the storage area 130. [ A level sensor (not shown) is provided inside the reservoir 1000 of the fluid discharging device to recognize the height of the holding fluid Lb that has been lowered due to the discharge and to inject a new infusion fluid La, And the base fluid Lb are stored in the storage area 130. [ The storage area 130 is defined below the preheating part 300. Therefore, the pre-storage fluid Lb is kept stored only under the preheating section 300.

The discharge port 120 is formed on the lower side of the preheating part 300. Specifically, it is formed on the lower side surface of the fluid tank. However, the present invention is not limited to this, and the discharge port 120 may be formed on the lower surface of the fluid tank 100. The storage fluid Lb in the storage area 130 passes through the discharge port 120 to reach an external ink jet head unit (not shown), and the original storage fluid Lb arriving at the ink jet head unit is discharged.

 One surface (150) of the fluid tank (100) is formed so as to be capable of being slidable. When the reservoir 1000 of the fluid ejection apparatus is used for a long period of time and the inside of the reservoir 1000 of the fluid ejection apparatus is dirty or foreign matter is generated, a checkable one surface 150 is separated and the inside of the reservoir 1000 of the fluid ejection apparatus is separated Can be cleaned. However, the present invention is not limited thereto, and the fluid tank 100 may not include the checkable surface 150.

 A heater (200) is disposed below the fluid tank (100). The heater 200 includes a coil 210 that generates heat when an electric current flows. The fluid tank 100 is provided with a temperature sensor (not shown) and a temperature controller (not shown) that sense the temperature of the storage fluid Lb and controls the temperature of the storage fluid Lb of the fluid tank 100 Is maintained constant. The heater 200 is in physical contact with the fluid tank 100 so that the heat generated by the heater 200 is transferred to the fluid tank 100 by thermal conduction, Storage fluid Lb through the surface of the fluid tank 100 in contact with the fluid Lb.

The preheating portion 300 is disposed between the injection port 100 and the discharge port 120. The fresh injection fluid La injected from the injection port 110 into the fluid tank 100 reaches the preheating section 300. One side of the preheating part 300 comes into contact with the inner side surface of the fluid tank 300 and receives heat from the inner side surface thereof.

The preheating unit 300 is formed of a material having a high thermal conductivity, and is preferably formed of aluminum or an aluminum alloy.

The preheating unit 300 includes a base plate 210 having a flat plate shape. The base plate 210 moves the fresh injection fluid La injected from the injection port 110 along the upper surface of the base plate and transfers the same to the storage area 130. The preheating unit 300 is provided with a preheating wall 320 formed along the edge of the base plate 210 so as to be preheated in the preheating unit 300 while being transferred to the storage area 130 . However, the shape of the preheating unit 300 may be modified and implemented. Specifically, the preheating unit 300 may not include the preheating wall 320 but may include only the base plate 210.

The fresh injection fluid La and the base fluid Lb may include liquid crystal inks used as ink in inkjet printing.

 The reservoir 1000 of the fluid ejecting apparatus may be a reservoir used in an ink-jet printing apparatus that forms a pattern by ejecting liquid crystal ink to produce a liquid crystal display.

2 is a sectional view of the reservoir of the fluid discharge device shown in Fig. Referring to FIG. 2, the fresh injection fluid La moves along the upper surface of the base plate 210 to one end 315 of the base plate 210. The fresh injection fluid La injected through the injection port 110 reaches the preheating part 300. Since the preheating unit 300 is in contact with the inner side surface of the fluid tank 100, the preheating unit 300 receives the heat transferred from the heater 200 to the inner side surface of the fluid tank 100, La).

Since the initial temperature of the new infusion fluid La is low and the density is high, the injected new infusion fluid La sinks and diffuses in the preheating unit 300. The fresh infusion fluid La that has settled is heated by the preheating unit 300, so that the temperature is increased and the density is lowered. The fresh injection fluid La having a temperature and density of a normal state rises and diffuses to the one end portion 315 like the first arrow Da and the fresh injection fluid La diffused to the one end portion 315 passes through the base plate The fluid moves from the one end of the first reservoir 210 to the storage region 130 and is merged with the storage fluid Lb. The preheating wall 320 of the one end 315 is formed to be lower than the other preheating wall 320 so that the fresh fluidizing fluid La passes over the preheating wall 320 of the one end 315 like the second arrow Db To the storage area 130. However, the present invention is not limited thereto. For example, the shape of the preheating wall 320 at one end 315 may be modified.

The initial temperature of the new infusion fluid La injected into the fluid tank 100 is lower than the temperature of the base fluid Lb heated in the heater 200. However, The temperature of the fluid in the storage region 130 is kept uniform even after the freshly injected fluid La is preheated at the same temperature as the temperature of the fluid Lb and then combined with the base fluid Lb. Accordingly, the viscosity of the base fluid Lb stored in the reservoir 1000 of the fluid discharge apparatus is maintained uniform, and a uniform amount of the base fluid Lb is discharged through the discharge port 120. [

3 is a perspective view of a preheating portion according to another embodiment. 4 is a sectional view of the reservoir of the fluid discharge device including the preheating portion shown in Fig. Referring to FIGS. 3 and 4, the base plate 210 is formed to be inclined at an acute angle? With the inner side surface of the fluid tank 100. The opposite preheating walls 320 of the base plate 210 formed at the edge of the base plate 210 are positioned on the inner side of the fluid tank 100 so as to confine the new infusion fluid La to the preheating unit 300 . The surface of the new infusion fluid La becomes closer to the upper surface of the base plate 210 as the fresh infusion fluid La is directed toward the one end 315 of the base plate 210, Gradually approaches, and the base plate 210 efficiently transfers heat to the fresh injection fluid La.

5 is a perspective view of a preheating unit according to another embodiment. 6 is a sectional view of the reservoir of the fluid discharge device including the preheating portion shown in Fig. 5 and 6, the preheater 300 includes a pipe 330 having a first hole 340 and a second hole 350 formed therein.

The pipe 330 extends from the inner side surface of the fluid tank 100 and is disposed between the discharge port 120 and the injection port 110. The pipe 330 may trap the fresh injection fluid La injected into the pipe 330 and preheat it.

The first hole 340 is formed at a position corresponding to the position of the injection port 110 on the upper side of the pipe 330. The injection hole 110 and the first hole 340 are connected to each other and the fresh injection fluid La is injected from the injection hole 110 to the first hole 340.

The second hole 350 is formed at one end 315 of the pipe 330. The fresh injection fluid La is transferred from the preheating section 300 to the storage region 130 through the second hole 350. The second hole 350 is formed on the upper side of the one end so that the fresh injection fluid La fills the interior of the pipe 330 and then moves to the storage region 130.

The fresh injection fluid La injected into the pipe 330 through the first hole 340 fills the interior of the pipe 330. Since the pipe 330 is in contact with the inner side surface of the fluid tank 100, the pipe 330 receives the heat transferred from the heater 200 to the inner side surface of the fluid tank 100, . The fresh injection fluid La, which is in contact with the preheating unit 300 and supplied with heat, is diffused in the pipe 330. The pipe 330 surrounds the fresh injection fluid La filled in the pipe 330 and supplies heat, so that the pipe 330 efficiently transfers heat to the fresh injection fluid La.

7 is a cross-sectional view of a reservoir of a fluid discharge device according to another embodiment. 7, the storage region 130 of the fluid tank 100 includes a discharge region 131 and a non-discharge region 132, and the lower surface of the fluid tank 100 includes a step.

The discharge region 131 is defined as an area contacting the discharge port 120 of the storage region 130 and the non-discharge region is defined as an area other than the discharge region 131 of the storage region 130.

 The lower surface of the fluid tank 100 is formed so that the height h2 of the base fluid Lb filled in the discharge region 131 is higher than the height h1 of the base fluid Lb filled in the non- Step difference.

The fresh injection fluid La injected through the injection port 110 is preheated by the preheater 300 and transferred to the non-discharge region 132 to be combined with the pre-storage fluid Lb. The base fluid Lb in the non-discharge region 132 is discharged through the discharge region 120 via the discharge region 131. [

8 is a perspective view of a reservoir of a fluid discharge device according to another embodiment. 9 is a sectional view of the reservoir of the fluid discharge device shown in Fig. Referring to FIG. 8, the fluid tank 100 includes a plurality of heat transfer plates 155.

The plurality of heat transfer plates 155 extend from the detachable one surface 150 of the fluid tank 100 toward the interior of the fluid tank 100 and include the first to sixth heat transfer plates 155a to 155f. The first to sixth heat transfer plates 155a to 155f are formed so that the first to sixth heat transfer plates 155a to 155f are not in contact with the preheating unit 300 when the one surface 150 is coupled with the fluid tank 100, (300). ≪ / RTI > Each heat transfer plate 155 has a thin plate shape in order to maximize a cross-sectional area of the heat transfer plate 155 and the base fluid Lb. The first to sixth heat transfer plates 155a to 155f are arranged in parallel to each other with a predetermined distance therebetween.

The fresh injection fluid La injected through the injection port 110 is preheated by the preheating part 300 and transferred to the non-discharge area 132 to be combined with the pre-storage fluid Lb. The first to sixth heat transfer plates 155a to 155f are brought into contact with the pre-storage fluid Lb to the pre-storage fluid Lb. Each heat transfer plate 155 contacts one surface 150 of the fluid tank 100 so that each heat transfer plate 155 receives heat transferred to the one surface 150 from the heater 200, (Lb) to maintain the temperature of the storage fluid (Lb). Since the heat transfer plate 155 increases the cross-sectional area with the base fluid Lb, the reservoir 1000 of the fluid discharge device efficiently transfers heat to the base fluid Lb.

10 is a perspective view of a reservoir of the fluid discharge device according to another embodiment. 11 is a perspective view of a reservoir of the fluid discharge device according to yet another embodiment. Referring to FIG. 10, the reservoir 1000 of the fluid discharge device includes a heater 200 and a first barrier plate 400. Since the fluid tank 100 and the heater 200 are similar to those in FIG. 1, a duplicate description will be omitted.

The storage region 130 includes a discharge region 131 contacting the discharge port 120 and a non-discharge region 132 defined as a region other than the discharge region 131 among the storage regions 130.

The injection port 110 is formed on the upper surface of the edge of the fluid tank 100 and connected to an external fluid reservoir (not shown) to receive a fresh injection fluid La newly injected from the fluid reservoir, Thereby providing fresh infusion fluid La.

The discharge port 120 is formed on the side surface of the fluid tank 100 in the discharge region 131. However, the present invention is not limited to this, and the discharge port 120 may be formed on the lower surface of the fluid tank 100. The storage fluid Lb stored in the discharge area 131 passes through the discharge port 120 to reach an external inkjet head unit (not shown), and the original storage fluid Lb, which reaches the inkjet head unit, do.

The first barrier plate 400 is disposed at the boundary between the discharge region 131 and the non-discharge region 132 and extends from the lower surface of the fluid tank 100 to the interior of the fluid tank 100, And separates the base fluid (Lb) in the non-discharge region (132) from the base fluid (Lb) in the non-discharge region (132). Therefore, the base fluid Lb in the discharge region 131 and the base fluid Lb in the non-discharge region 132 are not mixed by the first barrier plate 400.

 The first barrier plate 400 is made of a material having high thermal conductivity to conduct heat received from the heater 200, and is preferably formed of a metal such as aluminum or an aluminum alloy.

The fresh injection fluid La supplied through the injection port 110 reaches the discharge region 131 and is merged with the base storage fluid Lb filling the discharge region 131. [ The temperature of the fresh injection fluid La is lower than the temperature of the base storage fluid Lb and the density of the fresh injection fluid La is larger than the density of the base storage fluid Lb so that the fresh injection fluid La is diffused and sinks. However, since the first barrier plate 400 separates the non-discharge region 132 and the discharge region 131, the freshly-injected fluid La is not diffused to the discharge region 131. [ When the temperature and density of the new infusion fluid La reach a steady state and the temperature of the new infusion fluid La becomes close to the temperature and density of the surrounding base fluid Lb, A part of the freshly injected fluid La is mixed with the base fluid Lb and flows along the surface to the surface of the discharge region 131 beyond the first barrier plate 400 like the third arrow Dc ). The temperature of the fresh storage fluid Lb in the discharge area 131 does not change since the temperature of the freshly implanted fluid La moved to the discharge area 131 is the same as the storage fluid Lb of the discharge area 131 The viscosity of the holding fluid Lb is maintained uniformly. Therefore, the base fluid Lb is uniformly discharged through the discharge portion 120.

 The fluid tank 100 may further include a plurality of heat transfer plates 155 extending from one side of the fluid tank 100 toward the interior of the fluid tank 100 so as to increase the cross- have. The plurality of heat transfer plates 155 are similar to those of the heat transfer plate 155 of the other embodiment shown in FIG. 8, so duplicate descriptions are omitted.

The fresh injection fluid La and the base fluid Lb may include a liquid crystal ink composed of a liquid crystal of a liquid crystal display device and the reservoir 1000 of the fluid discharge device may spray liquid crystal ink to produce a liquid crystal display And may be a reservoir included in an ink-jet printing apparatus forming a pattern.

Referring to FIG. 11, as another embodiment, the reservoir 1000 of the fluid discharge device may include a preheating portion 300. The preheating unit 300 is similar to the preheating unit 300 of FIG. 1 and FIG. 2, and thus a duplicate description will be omitted. The preheating unit 300 is disposed between the discharge port 120 and the injection port 110 and preheats the fresh injection fluid La injected from the injection port 110. The fresh injection fluid La moves to one end of the preheating section 300 and is transferred to the non-discharge area 132 and merged with the base discharge fluid Lb of the non-discharge area 132. [

12 is a perspective view of a reservoir of the fluid discharge device according to yet another embodiment.

Referring to Fig. 12, the reservoir 1000 of the fluid discharge apparatus further includes a plurality of second barrier plates 400a to 400d. The plurality of second barrier plates 400a to 400d are disposed in the non-discharge region 132 to divide the non-discharge region 132 into a plurality of sub-discharge regions 132a to 132d. The second barrier plates 400a to 400d extend parallel to the first barrier plate 400 from the lower surface of the fluid tank 100 and are spaced apart from each other by a predetermined distance. A first sub non-discharge region 132a is formed between the side surface of the organic tank 100 and the first second barrier plate 400a and a second sub non-discharge region 132b is formed between the first barrier plate 400a and the second barrier plate 400b. The third sub-discharge region 132b is formed between the second second barrier plate 400b and the third barrier plate 400c and the third sub-discharge region 132c is formed between the third barrier plate 400c and the fourth barrier plate 400c. And a fourth sub-discharge region 132d is defined between the two barrier plates 400d.

The fresh injection fluid La supplied through the injection port 110 reaches the first sub-non-discharge region 132a and the new injection fluid La that has reached the first sub- Is moved from the second sub-non-ejection region 132b to the fourth sub-non-ejection region 132d through heating and diffusion as described in the embodiment. In the course of moving from the first sub-non-ejection region 132a to the fourth sub-ejection region 132d, the temperature and density of the freshly-injected fluid La reach a steady state, and the temperature and density of the priming fluid Lb . As a result, even when the stock keeping fluid Lb moves from the fourth sub-no-discharge region 132d to the discharge region 131, the temperature and viscosity of the stock keeping fluid Lb in the discharge region 131 are kept uniform So that the priming fluid Lb can be uniformly discharged through the discharge portion 120.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be understood that various modifications and changes may be made thereto without departing from the scope of the present invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification, but should be defined by the claims.

100: Fluid tank 130: Storage area
131: Discharge area 132: Non-discharge area
200: heater 300: preheating part
400: barrier plate La: fresh injection fluid
Lb: Storage fluid

Claims (18)

A fluid tank including a storage region for storing the storage fluid, an injection port for injecting the fresh injection fluid from the outside, and a discharge port for discharging the storage fluid from the storage region to the outside;
A heater disposed outside the fluid tank to generate heat and to transfer the heat to the fluid tank to maintain the temperature of the fluid; And
And a preheating unit for supplying the new injection fluid from the injection port to preheat the new injection fluid, and then delivering the fresh injection fluid to the storage region. The method according to claim 1,
The injection port is formed on the upper side of the preheating part,
And the discharge port is formed below the preheating part. 3. The method of claim 2,
Wherein the preheating portion includes a base plate having a flat plate shape,
Wherein the base plate moves the fresh injection fluid injected from the injection port along the upper surface of the base plate and transfers the injected fluid to the storage area. The method of claim 3,
And a preheating wall formed along an edge of the base plate to preheat the freshly injected fluid in the preheated portion and transfer it to the storage region. 5. The method of claim 4,
Wherein the base plate is formed by inclining the upper surface of the base plate and the inner side surface of the fluid tank so as to form an acute angle. 3. The method of claim 2,
The preheater includes a first hole for injecting a fresh injection fluid from the injection port; And
And a second hole formed to discharge the freshly injected fluid from the preheating section to the storage region. The method according to claim 1,
Wherein the preheating portion is made of an aluminum alloy. The method according to claim 1,
Wherein the storage area further includes a discharge area and a non-discharge area in contact with the discharge port,
Wherein the fluid tank further includes a step on a lower surface of the fluid tank such that a height of the base fluid filled in the discharge area is higher than a height of the base fluid filled in the non-discharge area. The method according to claim 1,
Wherein the fluid tank further comprises a plurality of heat transfer plates formed on one side of the fluid tank so as to be detachable and extending from the one side inward of the fluid tank. The method according to claim 1,
The reservoir of the fluid ejection apparatus is used in an ink-jet printing apparatus. The method according to claim 1,
Wherein the fresh injection fluid and the base storage fluid comprise liquid crystal inks. An injection port including a discharge area and a non-discharge area for storing the storage fluid, an injection port for supplying the fresh injection fluid from the outside to the non-discharge area, and a discharge port for contacting the discharge area, A fluid tank including a discharge port;
A heater disposed outside the fluid tank to generate heat and to transfer the heat to the fluid tank to maintain the temperature of the fluid; And
And a first barrier plate disposed at a boundary between the discharge region and the non-discharge region. 13. The method of claim 12,
Further comprising a plurality of second barrier plates for dividing the non-ejection area into a plurality of sub-ejection areas. 13. The method of claim 12,
Further comprising a preheating unit for supplying the new infusion fluid from the injection port to preheat the new infusion fluid, and then delivering the fresh infusion fluid to the storage area. 13. The method of claim 12,
Wherein the first barrier plate comprises a reservoir of a fluid discharge device formed of an aluminum alloy, 13. The method of claim 12,
Wherein the fluid tank further comprises a plurality of heat transfer plates formed on one side of the fluid tank so as to be detachable and extending from the one side in the inward direction of the fluid tank. 13. The method of claim 12,
The reservoir of the fluid ejection apparatus is used in an ink-jet printing apparatus. 13. The method of claim 12,
Wherein the fresh injection fluid and the base storage fluid comprise liquid crystal inks.

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