Abstract:
A liquid ejection head includes ejection ports ejecting as droplets a solution containing colorant particles dispersed therein and a device that makes uniform ejection of the solution from respective ejection channels in an ejection channel region where the ejection ports are arranged. A liquid ejection head of electrostatic type makes an electrostatic force to act on the solution containing charged particles dispersed therein as the colorant particles to eject the droplets.

Description:
The entire contents of documents cited in this specification are incorporated herein by reference. 
     BACKGROUND OF THE INVENTION 
     The present invention relates to a liquid ejection head for ejecting a solution containing charged particles dispersed therein. More specifically, the invention relates to a liquid ejection head that ejects droplets by making an electrostatic force act on a solution containing charged particles dispersed therein. 
     Liquid ejection heads for ejecting liquid have been heretofore proposed as exemplified by a thermal type inkjet head which ejects ink droplets by the expansion force of bubbles generated in heated ink, and a piezoelectric type inkjet head which ejects ink droplets by applying a pressure to ink by means of a piezoelectric element. 
     Recently, another type of inkjet head has been also proposed in which ink containing a charged fine particle component is used and a predetermined voltage is applied to control electrodes of the inkjet head in accordance with image data to control ink ejection based on the electrostatic force to thereby record an image corresponding to the image data on a recording medium. 
     Various inkjet recording apparatuses are known to be of the electrostatic inkjet recording system (see, for example, JP 10-230608 A, JP 9-277558 A, JP 10-67111 A, JP 11-10911 A and JP 2001-121716 A). 
     The inkjet head adopting the electrostatic inkjet recording system is advantageous in that the problems having been heretofore pointed out: ink material restricted in the thermal type inkjet head because of partial heating of ink to 300° C. or higher, and complicated and high-cost structure of the piezoelectric type inkjet head can be solved. 
     The object to be achieved in the inkjet head of the inkjet recording apparatus disclosed in JP 10-230608 A was to consistently eject ink droplets without causing clogging. Each of the ink guides has an ink guide groove (slit) with a predetermined width formed by cutting and its tip portion is pointed, and it is said that the slit contributes to the meniscus stability. However, this apparatus suffers from its insufficient capability to supply ink particles and has a problem associated with continuous ejection in the high-frequency range. 
     The object to be achieved in the inkjet head recording apparatus disclosed in JP 9-277558 A was to prevent printing unevenness due to pressure head differences among the nozzles not by relying on the formation of ink guides but by forming an approximately hemispherical meniscus in each ink outlet port by means of the pressure of ink coming from the ink supply path and the surface tension of the ink. However, this apparatus has a limitation on the orientation of the nozzle heads and shaking of the nozzle heads may have a detrimental effect on the apparatus. 
     The object to be achieved in the inkjet head recording apparatus disclosed in JP 10-67111 A was to stabilize the ink concentration by circulating ink in a consistent manner and the apparatus is designed to absorb variations in the pressure difference between the ink chamber and the ink tank. However, this apparatus is not capable of correcting the non-uniformity of pressure among the channels in the head. 
     As in JP 10-67111 A, the inkjet recording apparatus disclosed in JP 11-10911 A is also capable of correcting the pressure difference between the inlet and outlet of the head by providing the pressure adjusting tube between the ink supply path and the ink recovery path, but the non-uniformity of pressure among the channels cannot be corrected. 
     The inkjet recording apparatus disclosed in JP 2001-121716 A has the ink pressure sensor disposed in the ink supply path to control the ink supplying pump so that a decrease in ink pressure can be detected before the apparatus is turned to an unprintable state. However, a method of compensating for the pressure variations among the channels in the head is not considered in this apparatus. 
     SUMMARY OF THE INVENTION 
     It is required that a uniform and high-quality image be recorded at high speed in a consistent manner with the inkjet head (liquid ejection head) of an inkjet recording apparatus. Recently, a so-called multihead inkjet head is used to meet the demand for further enhanced speed, and hence it is required that droplets be uniformly ejected from a large number of ejection ports. 
     That is, it is required that a uniform and high-quality image be recorded at high speed in a more consistent manner than before with the inkjet recording apparatus. In order to fulfill this requirement, it is necessary to consistently eject droplets of the same size under uniform pressure from droplet-ejecting positions (that is, from multichannel droplet-ejecting ports). 
     However, as described above, it has been generally impossible to respond to such requirement in inkjet heads used in conventional inkjet recording apparatuses. 
     The present invention has been made to solve the problems described above and an object of the present invention is to provide a liquid (ink) ejection head capable of consistently ejecting droplets of the same size under uniform pressure from multichannel ink ejection ports. 
     A more specific object of the present invention is to provide a liquid ejection head of electrostatic type which has multichannel ink ejection guides and are capable of consistently ejecting droplets of the same size under uniform pressure by making uniform the ejection of a solution from respective ejection channels in the region in which the ink ejection guides are arranged (hereinafter referred to as the ejection channel region). 
     In order to achieve the above objects, the present invention provides a liquid ejection head comprising: 
     ejection ports which eject as droplets a solution containing colorant particles dispersed therein; and 
     means for making uniform ejection of the solution from respective ejection channels in an ejection channel region where the ejection ports are arranged. 
     The means for making uniform the ejection of the solution from the respective ejection channels preferably comprises means for locally increasing a pressure loss between a solution supply path for supplying the solution and the ejection channel region. 
     The means for making uniform the ejection of the solution from the respective ejection channels preferably comprises means for making solution surfaces formed in the respective ejection channels of the ejection channel region uniform in height. 
     The means for making uniform the ejection of the solution from the respective ejection channels preferably comprises means for making uniform one or both of a flow rate and a pressure at which the solution is supplied to the respective ejection channels of the ejection channel region. 
     In order to achieve the above objects, the present invention also provides a liquid ejection head of electrostatic type that makes an electrostatic force to act on a solution containing charged particles dispersed therein to eject droplets, comprising: 
     an insulating through-hole substrate through which through-holes for ejecting the droplets extend; 
     an insulating head substrate which is spaced apart from the insulting through-hole substrate by a predetermined distance, with a solution flow path being formed between the insulating through-hole substrate and the insulting head substrate; 
     solution guides which are formed on a surface of the insulating head substrate facing the insulating through-hole substrate, with their tips extending through and protruding from the insulating through-hole substrate; 
     control electrodes which ate provided at positions corresponding to the through-holes and causes the electrostatic force to act on the solution; 
     a counter electrode which is provided at a position facing the solution guides; and 
     means for making uniform ejection of the solution from respective ejection channels in an ejection channel region where the solution guides are arranged. 
     The means for making uniform the ejection of the solution from the respective ejection channels preferably comprises means for locally increasing a pressure loss between a solution supply path for supplying the solution and the ejection channel region. 
     The means for making uniform the ejection of the solution from the respective ejection channels preferably comprises means for making meniscuses formed in the respective ejection channels of the ejection channel region uniform in height. 
     The means for making uniform the ejection of the solution from the respective ejection channels preferably comprises means for making uniform one or both of a flow rate and a pressure at which the solution is supplied to the respective ejection channels of the ejection channel region. 
     The means for making uniform the ejection of the solution from the respective ejection channels preferably comprises means for making uniform flow rates and pressures in a solution-flowing direction and in a width direction by locally increasing the pressure loss per unit length between the solution supply path and the ejection channel region. 
     The means for making uniform the flow rates and the pressures in the solution-flowing direction and in the width direction preferably comprises a baffle plate provided in the solution flow path. 
     The means for making uniform the flow rates and the pressures in the solution-flowing direction and in the width direction preferably comprises a porous member provided in the solution flow path. 
     The means for making uniform the flow rates and the pressures in the solution-flowing direction and in the width direction preferably comprises uneven structures having adjusted roughness and formed in the solution flow path or wall surfaces of the solution flow path having adjusted roughness. 
     The means for making uniform the flow rates and the pressures in the solution-flowing direction and in the width direction preferably comprises means for changing typical sizes of the solution flow path between the solution supply path and the ejection channel region. 
     The means for locally increasing the pressure loss preferably comprises means for changing between the solution supply path and the ejection channel region, a direction in which the solution mainly flows. 
     The means for making meniscuses formed in the respective ejection channels of the ejection channel region uniform in height preferably comprises means for reducing a pressure loss per unit length in the ejection channel region. 
     The means for reducing the pressure loss per unit length in the ejection channel region preferably comprises means for decreasing a contact area of wall surfaces of the solution flow path which make contact with the solution in the ejection channel region. 
     The wall surfaces of the solution flow path in the ejection channel region which make contact with the solution are preferably subjected to a coating treatment. 
     The wall surfaces of the solution flow path in the ejection channel region which make contact with the solution are preferably provided with microstructured projections or recesses. 
     The means for making uniform the one or both of the flow rate and the pressure at which the solution is supplied to the respective ejection channels of the ejection channel region preferably comprises means for supplying the solution to blocks each composed of more than one channel in the ejection channel region. 
     The means for supplying the solution to blocks each composed of the more than one channel in the ejection channel region preferably supplies the solution in parallel to blocks each composed of more than one channel in the ejection channel region. 
     The blocks each composed of the more than one channel are preferably separated from each other by partitions. 
     According to the present invention, a liquid ejection head capable of consistently ejecting droplets of the same size under uniform pressure from multichannel ink election ports can be realized. 
     More specifically, according to the present invention, the flow rates and the pressures in the ink flow direction and the width direction in the ejection channel region are made uniform, whereby the meniscuses formed in the ejection ports of the ejection channel region are made uniform in height and also have substantially the same shapes. 
     According to the present invention, the pressure loss per unit length in the ejection channel region is also reduced to decrease the pressure difference between the upstream and the downstream in the ink flow direction, which enables the ink flow rate to be made uniform. Thus, the meniscuses formed in the ejection ports of the ejection channel region are made uniform in height and also have substantially the same shapes. 
     Furthermore, the present invention that is configured so as to supply ink to each block composed of more than one channel is capable of making the ink-supplying pressure and flow rate uniform even when it is difficult to reduce the pressure loss in the ejection channel region. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       In the accompanying drawings: 
         FIG. 1  is a schematic view of an inkjet recording apparatus that has an inkjet head which is an example of an electrostatic ejection head according to an embodiment of the present invention; 
         FIG. 2  is a perspective view showing the vicinity of an ejection channel region which is the essential part of the inkjet head shown in  FIG. 1 ; 
         FIG. 3  is a plan view schematically showing the ejection channel region according to another embodiment; 
         FIG. 4  is a plan view of a simulated inkjet head for use in simulating the electrostatic ejection head according to an embodiment; 
         FIGS. 5A and 5B  are graphs showing the simulation results obtained with the simulated inkjet head in Comparative Example; and 
         FIGS. 6A and 6B  are graphs showing the simulation results obtained with the simulated inkjet head in Example; 
         FIG. 7  is a schematic view of an inkjet recording apparatus indicating the baffle plate according to an embodiment; 
         FIG. 8  is a schematic view of an inkjet recording apparatus indicating porous material and microstructured projection/recess according to an embodiment. 
     
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     The liquid ejection head of the present invention will be described below in detail with reference to preferred embodiments shown in the accompanying drawings. 
       FIG. 1  is a schematic view of an inkjet recording apparatus  10  that has an inkjet head  12  which is an example of an electrostatic ejection head according to an embodiment of the present invention.  FIG. 2  is a perspective view showing the vicinity of an ejection channel region which is the essential part of the inkjet head  12  shown in  FIG. 1 . 
     As shown in  FIG. 1 , the inkjet recording apparatus  10  includes the inkjet head  12 , ink circulation means  14 , voltage application means  16 , and recording medium support means  18  disposed in a position facing the inkjet head  12 . 
     The inkjet head  12  includes a head substrate  30 , a through-hole substrate  32  having through-holes  38 , ink guides  34 , control electrodes (ejection electrodes)  36 , a guard electrode  42  and a floating conductive plate  46 . Each of ejection portions  40  has one ink guide  34  and one through-hole  38 . An ink flow path indicated by reference numeral  44  is formed between the head substrate  30  and the through-hole substrate  32 . 
     The ink circulation means  14  includes an ink circulation mechanism  50 , an ink supply path  52  and an ink recovery path  54 . The ink circulation means  14  supplies ink to the inkjet head  12  (mainly to the ejection channel region thereof) at a predetermined flow rate and recovers the supplied ink therefrom. Although not shown, the ink circulation means  14  has a means for replenishing the mechanism where ink (particles) decreased by executing printing operations and a means for storing ink when the apparatus is at rest. 
     In the inkjet head  12  of the embodiment under consideration, the ejection electrodes  36  and the guard electrode  42  are provided on the head substrate  30  side and the recording medium support means  18  side of the through-hole substrate  32 , respectively. Each of the through-holes  38  extends through the through-hole substrate  32  and the ejection electrode  36 . The guard electrode  42  is provided in order to achieve the effect of preventing the deviation of the ejected ink droplet from the position at which the ink droplet is to be adhered. 
     The head substrate  30  is spaced apart from the through-hole substrate  32  by a predetermined distance, and the space defined by these components forms the ink flow path  44  as described above. 
     The floating conductive plate  46  is provided on the peripheries of the ink guides  34  on the surface of the head substrate  30  facing the through-hole substrate  32 . The floating conductive plate  46  is provided in order to achieve the effect of concentrating the dispersed ink particles. The floating conductive plate  46  is provided substantially on the whole surface of the head substrate  30  surrounding the ink guides  34 , but the floating conductive plate  46  may be provided only at positions facing the ejection electrodes  36 , or in the shape of a strip, plane or mesh covering the above positions. 
     On the upper surface of the head substrate  30  facing the through-hole substrate  32  are provided the ink guides  34 , each of which has a tip protruding from its corresponding through-hole  38  toward the recording medium support means  18  side. 
     The ejection electrodes  36  are connected to the voltage application means  16  through a wiring portion  48  (partially shown), The wiring portion  48  is also used to connect the guard electrode  42  and the floating conductive plate  46  to grounding means and a specified voltage application means, respectively. 
     The voltage application means  16  includes a signal voltage source  60  which applies to the ejection electrodes  36  a drive voltage (e.g., pulse voltage) of a predetermined potential corresponding to the ejection data (ejection signal) such as image data and character data, and a bias voltage source  62  which continuously applies a predetermined constant voltage to the ejection electrodes  36 . 
     One terminal (positive terminal in this case) of the signal voltage source  60  is connected to the wiring portion  48  and the other terminal (negative terminal in this case) thereof to one terminal (positive terminal in this case) of the bias voltage source  62 . The other terminal (negative terminal in this case) of the bias voltage source  62  is grounded. 
     The recording medium support means  18  for supporting a recording medium P is provided at a position facing the ink jet head  12 , and includes a counter electrode  70  and a bias voltage source  72  for applying a negative high voltage to the counter electrode  70 . 
     The counter electrode  70  is arranged so as to face the ink droplet-ejecting surface of the inkjet head  12 . The negative terminal of the bias voltage source  72  is connected to the counter electrode  70  and the positive terminal thereof is grounded. The recording medium P is supported on the surface of the counter electrode  70  facing the ink droplet-ejecting surface of the inkjet head  12 . 
     In order to perform higher density image recording, the inkjet head  12  is preferably of a mutichannel structure as shown in  FIG. 1  in which the ejection portions  40  each of which is composed of one ink guide  34  and a through-hole  38  are two-dimensionally arranged together with the ejection electrodes  36 . 
     The respective portions of the inkjet head  12  according to the embodiment under consideration will be described below in detail. 
     As shown in  FIG. 2 , an ejection channel region  12   a  is formed on the upper surface of the inkjet head  12  and has the ejection portions  40  formed in, for example, 5 rows along its short side direction, that is, the ink flow direction indicated by an arrow “a” in  FIG. 2  and in, for example, 17 columns in the width direction (long side direction) perpendicular to the ink flow direction. In the illustrated example, ink is supplied to the ink flow path  44  in the direction perpendicular to the ink supply path  52  through the ink supply path  52  that has a flow path which enlarges in the longitudinal direction from a tube  52   a  communicating with an ink inlet from the ink circulation mechanism  50  toward the width of the ejection channel region  12   a . The ink is then supplied from the ink flow path  44  to the respective ejection portions  40  of the ejection channel region  12   a . The ink is recovered from the ink flow path  44  of the ejection channel region  12   a  in the direction perpendicular to the ink flow path  44  through the ink recovery path  54  that has a flow path narrowing in the longitudinal direction from the width of the ejection channel region  12   a  toward a tube  54   a  communicating with an ink outlet to the ink circulation mechanism  50 . 
     As described above, the object of the present invention is to make uniform the ink ejection from the respective ejection channels in the ejection channel region  12   a  to enable ink droplets of the same size to be consistently ejected under uniform pressure. 
     Specific examples of the structure for achieving this object will be described below. 
     The basic feature of the inkjet head  12  according to the embodiment under consideration is that it has a means for making uniform the ink ejection from the respective ejection channels in the ejection channel region  12   a . Various means can be used to make uniform the ink ejection from the respective ejection channels. 
     A first means is to locally increase the pressure loss between the ink supply path  52  for supplying ink to the inkjet head  12  and the ejection channel region  12   a . More specifically, a structure is used in which the ink flow path is bent at right angles from the vertically upward direction to the horizontal direction at the portion where the ink is supplied from the ink supply path  52  to the ejection channel region  12   a , in other words, at the inlet portion of the inkjet head  12 . 
     By bending the ink flow path at right angles in this way, the flow rate and the pressure of the ink flow are made uniform in the inlet portion of the inkjet head  12  particularly in the width direction of the ejection channel region  12   a , which enables the ink ejection from the respective ejection channels in the ejection channel region  12   a  to be made uniform. This structure also enables the meniscuses formed in the respective ejection channels of the ejection channel region  12   a  to be made uniform in height. 
     Another means for making uniform the ink ejection from the respective ejection channels is a structure as shown in  FIG. 2  in which the height or the cross-sectional area of the ink flow path in the portion through which the ink flows into the inkjet head  12  is decreased. Specific examples include a structure in which the height of the ink flow path in the portion through which the ink flows into the inkjet head  12  is decreased from d 1  to d 2 , and a structure in which the cross-sectional area of the ink flow path is decreased from S 1  to S 2 . 
     Reference symbol R shown in  FIG. 1  indicates the portion in the ink flow path  44  corresponding to the ejection channel region  12   a . The structures described above are applied to make uniform the flow rate and the pressure of the ink flow in the portion R. 
     It is preferred for the portion R not to have a structure that may interfere with the uniform flow rate and pressure of the ink flow, for example, a structure in which a barrier (partition) is provided in a direction perpendicular to the ink flow direction or a structure in which wall surfaces contacting the ink have a large surface roughness. 
     The distance L (see  FIG. 1 ) between the portion through which the ink flows into the inkjet head  12  and the inlet of the portion R corresponding to the ejection channel region  12   a  should be also called the entrance length (entrance region) for developing the ink flow. The distance L has preferably a value exceeding a certain value. For example, the distance L has desirably a value satisfying the relation:
 
 L= 0.0065× Vd   2   2 /ν
 
where V is the flow rate of the ink, d 2  is the height of the ink flow path in the ejection channel region  12   a , and ν is the kinematic viscosity of the ink.
 
     It is preferable to increase the height of the ink flow path from d 2  to d 3 , or the cross-sectional area from S 2  to S 3  on the outlet side of the ejection channel region  12   a . In this case, the height d 1  and the cross-sectional area S 1  of the ink flow path may be the same as or different from the height d 3  and the cross-sectional area S 3 , respectively. 
     The above-mentioned structure in which the ink flow path is bent at right angles from the vertically upward direction to the horizontal direction in the inlet portion of the inkjet head  12  may be replaced by the structure in which a baffle plate is provided in the inlet portion of the inkjet head  12  (preferably in the vicinity of the starting point of the entrance length L) in a direction orthogonal to the ink flow or at an angle exceeding a certain value. 
     In this case, the shape and material of the baffle plate are preferably selected so that the uniformity of the ink flow is not degraded. In a particularly preferred structure, a porous material can be used to further enhance the uniformity of the ink flow. There are no particular limitations on the material, pore size and porosity of the porous material used. 
     It is needless to say that, in the portion contacting the ink flow within the region R of the flow path corresponding to the ejection channel region  12   a , in short, in the ink-contacting portion, the wall surfaces have preferably a small surface roughness. However, it is preferable for the wall surfaces to be further subjected to a treatment (coating treatment) to make them liquid repellent or receptive to thereby reduce the resistance in the flow path. 
     There is no particular limitation on the material used in the coating treatment, and any material can be used as long as the material used does not adversely affect the ink material. 
     Instead of performing the coating treatment as described above, it is of course effective for the whole (or only the portions near the surfaces) of the components located in the ink-contacting portion within the portion R corresponding to the ejection channel region  12   a  to be made of a material which is highly repellent or receptive to liquid and has a small surface roughness as described above. 
     It is also effective to use a nanostructured or microstructured pillar or slit in the liquid repellent or receptive portion as described above. For example, such structure enables the pressure loss to be reduced to about 20% or less. 
     In addition to the various structures described above, a structure in which the area of the wall surfaces in the ink flow path contacting the ink is decreased is also effectively used in order to reduce the resistance during the passage of the ink through the ink-contacting portion within the portion R corresponding to the ejection channel region  12   a . Assuming here that a flow path with a square cross section and a flow path with a circular cross section are identical in cross-sectional area, the ink-contacting area of the latter is √π/2 times (about 0.89 times) as large as the former. 
     A structure whose concept is different from that of the structure illustrated above will be described below. 
       FIG. 3  is a plan view schematically showing the ejection channel region  12   b  according to another embodiment.  FIG. 3  shows discrete ejection channel regions  12   c  each corresponding to the ejection portions in one row of the ejection channel region  12   a  described above. Partitions  20  for dividing the ink supply path  52  into several segments are also shown. 
     In the structure shown in  FIG. 3 , each of the ejection channel regions  12   c  is arranged so as to have an ink supply path exclusively used therefor, and the structure is advantageous in that an adjustment for making uniform the amount of ink to be supplied to each of the ejection channel regions  12   c  can be readily made. 
     In this embodiment, each of the ejection channel regions  12   c  has a row of ejection portions but a structure in which each ejection channel region is composed of two or more rows may of course be applied. 
     Various structures including the one relying on the coating treatment as described above can also be used in the inkjet head of this embodiment in order to reduce the resistance of the partitions  20  against the contact with the ink flow. 
     The liquid ejection head of the present invention has been described above with reference to the various embodiments. Then, in Example, a simulation was performed for the structure of a typical embodiment as shown in  FIG. 2  in which the height of the ink flow path was reduced in the portion through which the ink flowed into the inkjet head  12 , and this Example and Comparative Example corresponding thereto are shown below. 
     EXAMPLE AND COMPARATIVE EXAMPLE 
     The following Example and Comparative Example are experimental examples in which simulated inkjet heads intended for simulation purposes was used. The simulated inkjet heads had the same geometry as that used in the actual apparatus but did not include members (e.g., ink guides and through-holes) forming the actual ejection portions. 
       FIG. 4  shows a plan view of a simulated inkjet head. The dimensions of the respective portions are shown in detail in  FIG. 4 . The direction indicated by Y in  FIG. 4  is the ink flow direction. The interval between Y 1  and Y 2  in the Y direction indicates the region R corresponding to the ejection channel region  12   a  and the interval between Y=0 and Y=Y 1  corresponds to the entrance length L over which the ink flows. 
     Prior to referring to the simulations in Example and Comparative Example, it is to be noted that there is a different point between Example and Comparative Example: In Example, the height of the ink flow path is reduced in the portion through which the ink flows into the inkjet head and the height of the ink flow path in the entrance region (having the length L) is 2 mm and that in the ejection channel region is 200 μm (0.2 mm), whereas the height of the ink flow path is 2 mm over the whole length in Comparative Example. 
       FIGS. 5A and 5B  are graphs showing the simulation results obtained with the simulated inkjet head in Comparative Example, and  FIGS. 6A and 6B  are graphs showing the simulation results obtained with the simulated inkjet head in Example.  FIGS. 5A and 6A  show the uniformity in the ink pressure in the portion corresponding to the portion R of the ink flow path  44  corresponding to the ejection channel region  12   a  (hereinafter referred to as the portion corresponding to R), and  FIGS. 5B and 6B  show the uniformity in the ink flow rate in the portion corresponding to R. In the simulations of Example and Comparative Example shown in  FIGS. 5A ,  5 B,  6 A and  6 B, the average flow rate was set to be the same. 
     Now referring to the graphs of  FIGS. 5A and 5B  which show the simulation results in Comparative Example, unsatisfactory results are obtained in both of the uniformity in the ink pressure in  FIG. 5A  and the uniformity in the ink flow rate in  FIG. 5B . More specifically, as for the uniformity in the ink pressure in  FIG. 5A , it is seen that the ink pressure considerably varies in the width direction of the simulated inkjet head (horizontal direction in  FIG. 5A ) and there is a difference of about ±20 Pa between the end (X=163 for example) and the center (X=0). 
     As for the uniformity in the ink flow rate in  FIG. 5B , it is seen that the flow rate markedly varies in the width direction (horizontal direction in  FIG. 5B  as above) over the distance of about 170 mm and the inkjet head is by no means adequate for practical use. As also described in  FIG. 5B , the flow rate differs at a one-digit level or higher between the ink flow before reaching the portion corresponding to R and the ink flow having passed therethrough. In the case where the flow rate differs to such an extent, the ink could concentrate in a considerably non-uniform manner. 
     Referring to the graphs of  FIGS. 6A and 6B  which show the simulation results in Example, highly satisfactory results are obtained in both the uniformity in the ink pressure in  FIG. 6A  and the uniformity in the ink flow rate in  FIG. 6B . More specifically, as for the uniformity in the ink pressure in  FIG. 6A , the ink pressure differs to some extent between the ink before reaching the portion corresponding to R and the ink having passed therethrough, whereas no substantial difference is observed in the width direction (horizontal direction in  FIG. 6A ). The difference in the ink pressure in the direction along the portion corresponding to R causes no problem in the actual inkjet image formation. 
     As for the uniformity in the ink flow rate in  FIG. 6B , no substantial difference is observed not only in the width direction (horizontal direction in  FIG. 6B ) but also in the direction along the portion corresponding to R and it is seen that the uniformity in the ink flow rate is achieved over the whole region in a substantially complete manner. 
     The simulation results in Example show a high degree of effectiveness of the structure in the above-mentioned embodiment in which ejection of the solution from the respective ejection channels in the ejection channel region is made uniform. 
     While the liquid ejection head of the present invention has been described above in detail with reference to the various embodiments and examples, the invention is by no means limited thereto and various improvements and modifications can of course be made without departing from the scope and spirit of the invention. 
     In addition to the above-mentioned structure in which the blocks and the ink supply path are arranged on a horizontal plane, a structure composed of a three-dimensionally combined arrangement is also effective to supply a solution to each block composed of more than one channel in the ejection channel region.