Ink-jet recording sheet comprising a molecule containing tertiary amino groups and polysiloxane segments

An ink-jet recording sheet is provided with at least one ink-receiving layer on at least one side of a base material sheet. A resin component which constitutes the ink-receiving layer comprises a hydrophilic resin containing tertiary amino groups in a molecule thereof or a hydrophilic resin containing tertiary amino groups and polysiloxane segments in a molecule thereof. A coating formulation suitable in use for the production of the ink-jet recording sheet is also disclosed.

BACKGROUND OF THE INVENTION 
a) Field of the Invention 
This invention relates to an ink-jet recording sheet (hereinafter simply 
called "a recording sheet"), and more specifically to a recording sheet 
having an ink receiving layer--which imparts excellent waterproofness and 
moisture resistance to printed characters, pictures, patterns or the like 
(hereinafter collectively called "printed marks" for the sake of brevity), 
is excellent in ink absorbency and ink-color-producing ability, provides 
stable printed marks of high quality, and is also outstanding in the 
transportability and blocking resistance inside a printer--and also to a 
coating formulation for producing the sheet. 
b) Description of the Related Art 
Ink-jet recording is to perform recording of an image, characters or the 
like by causing tiny droplets of an ink to fly and stick on a recording 
sheet made of paper or the like. Various operation principles have been 
proposed including, for example, the electrostatic attraction method, the 
method that mechanical vibrations or displacements are applied to an ink 
by means of a piezoelectric element, and the method that an ink is heated 
to bubble and the resulting pressure is used. As a recording method which 
permits high-speed recording, produces less noise and enables high-quality 
printing and multicolor printing, ink-jet recording is finding 
ever-increasing utility for various applications. 
For use in such ink-jet recording, various recording sheets have been 
proposed, including recording sheets provided on paper or like bases with 
ink-receiving layers, which are composed primarily of various pigments and 
resins, or recording sheets containing porous pigments incorporated in 
themselves upon making paper so that prompt absorption of ink and 
formation of well-defined ink dots can be assured without a reduction in 
print quality due to blotting and/or bleeding of the ink adhered on the 
recording sheets. 
For example, JP Kokai No. 57-82085 discloses a recording sheet which has an 
ink-receiving layer composed of a water-soluble resin and containing an 
inorganic pigment and an organic pigment, and JP Kokai No. 62-268682 
discloses a recording layer which carries an ink-receiving layer composed 
of a silanol-containing polyvinyl alcohol copolymer and containing fine 
powdery silica. 
However, keeping the step with improvements in the performance of ink-jet 
recording machines, such as high-speed recording, high-density recording 
and full-color recording, and the resulting expansion of their application 
fields, it has also become necessary for recording sheets to have 
high-level characteristics such as: 
(1) Prompt ink absorption and large ink absorption capacity. 
(2) High color-producing ability for inks. 
(3) High surface strength on the ink-receiving layer. 
(4) High waterproofness of the base material so that the base material will 
not develop roughness or curling by adhered ink. 
(5) Good mark storability, such as waterproofness and ozone resistance, 
after printing of marks on the ink-receiving layer. 
(6) No quality changes of the ink-receiving layer along the passage of 
time. 
To meet these requirements, it has been proposed or studied to use a porous 
pigment or water-soluble polymer having excellent ink absorbency as a 
component of an ink-receiving layer to be placed on a recording sheet, to 
use a latex for an improvement in the waterproofness of an ink-receiving 
layer, and to use as a base material itself a synthetic paper sheet, 
plastic sheet or the like equipped with waterproofness. 
However, those making use of paper as a base material or a water-soluble 
resin alone as an ink-receiving layer have poor waterproofness at their 
ink-receiving layers, leading to a drawback in that blotting takes place 
at parts printed with ink and marks so formed are hence inferior in 
definition. On the other hand, recording sheets making use of a synthetic 
paper sheet or plastic film as a base material and those making use of a 
latex as a resin for the formation of an ink-receiving layer involve 
problems in the adhesion between the ink-receiving layer and the base 
material, the ink absorbency of the ink-receiving layer and the drying 
property of applied ink. 
To improve the waterproofness and moisture resistance of printed images of 
a recording sheet, it has been the general practice to arrange a 
protective layer over an ink-receiving layer or to add a mordant or the 
like in an ink-receiving layer. As a method for the arrangement of a 
protective layer, a hydrophobic resin may be coated or a film may be 
laminated over an ink-receiving layer after printing images thereon. 
Although such a method can bring about improvements in waterproofness and 
moisture resistance, it requires many steps and therefore is not preferred 
for the formation of images from the standpoint of price. Concerning the 
method which features the addition of a mordant or the like in an 
ink-receiving layer, dyes employed in ink-jet color inks are direct dyes 
or acid dyes, the molecule of each of which contains an anionic carboxyl 
or sulfonic group. To improve the waterproofness and fixability of images 
formed with these dyes, a cationic mordant or the like is added to an 
ink-receiving layer. The bonding between the mordant and its associated 
dye is however ionic bonding, which is prone to dissociation in the 
present of water. A limitation is therefore imposed on the waterproofness 
and moisture resistance of images so formed. 
SUMMARY OF THE INVENTION 
With a view to solving such problems of the conventional recording sheets 
as described above and developing a recording sheet which is excellent in 
the waterproofness and moisture resistance of printed marks to be formed, 
is superb in ink absorbency and ink-color-producing ability, provides 
stable printed marks of high quality, and is also outstanding in the 
transportability and blocking resistance inside a printer, the present 
inventors have proceeded with a variety of investigations. As a result, it 
has been found the above object can be achieved by forming an 
ink-receiving layer of a recording sheet with a particular hydrophilic 
resin, leading to the completion of the present invention. 
Accordingly, there is provided, in one aspect of the present invention, an 
ink-jet recording sheet provided with at least one ink-receiving layer on 
at least one side of a base material sheet, wherein a resin component 
which constitutes the ink-receiving layer comprises a hydrophilic resin 
containing tertiary amino groups in a molecule thereof. In another aspect 
of the present invention, there is also provided an ink-jet recording 
sheet provided with at least one ink-receiving layer on at least one side 
of a base material sheet, wherein a resin component which constitutes the 
ink-receiving layer comprises a hydrophilic resin containing tertiary 
amino groups and polysiloxane segments in a molecule thereof. 
DETAILED DESCRIPTION OF THE INVENTION AND PREFERRED EMBODIMENTS 
This invention will next be described in further detail by describing 
certain preferred embodiments. 
The ink-jet recording sheet according to the first aspect of the present 
invention is characterized in that the at least one ink-receiving layer 
arranged on the at least one side of the base material sheet has been 
formed by using the hydrophilic resin which contains the tertiary amino 
groups in the molecule thereof. 
The ink-jet recording sheet according to the second aspect of the present 
invention is characterized in that the at least one ink-receiving layer 
arranged on the at least one side of the base material sheet is formed of 
the hydrophilic resin which contains the tertiary amino groups and the 
polysiloxane segments in the molecule thereof. 
The term "hydrophilic resin" as used herein means a polymer which is 
insoluble in water, warm water or the like although it contains 
hydrophilic groups in its molecule. The hydrophilic resin should therefore 
be distinguished from water-soluble resins such as polyvinyl alcohol, 
polyvinyl pyrrolidone and cellulose derivatives. 
In the hydrophilic resins useful in the first and second aspects of the 
present invention, it is believed that ionic bonds are formed between 
molecules of a dye and the resins owing to the tertiary amino groups 
introduced in the resin molecules, resulting in improvements in the 
fixability of the dye and the waterproofness of marks to be formed. 
Taking into consideration that the bonding between the dye and the tertiary 
amino groups is ionic bonding as in the conventional cases which use a 
mordant in ink-receiving layers, it is not certain why the marks so formed 
are equipped with such improved waterproofness over those available by the 
conventional art. It is however presumed that the resins useful in the 
present invention are hydrophilic but are water-insoluble and accordingly, 
that their molecules also contain hydrophobic segments in abundance. 
Subsequent to the formation of ionic bonds between the tertiary amino 
groups in the resins and the dye, the hydrophobic segments appear to 
surround these ionic bonds so that the thus-formed marks are provided with 
the improved waterproofness over the prior art. 
Different from the conventional art making use of a mordant, it is believed 
that, while the tertiary amino groups in resin molecules in the present 
invention are progressively forming ionic bonds with the dye, the 
hydrophobic segments in the resin molecules act to surround these ionic 
bonds and that this action is attributable to the improved waterproofness 
of the thus-formed marks. 
In the second aspect of the present invention, on the other hand, the 
polysiloxane segments introduced in the resin molecule is basically 
hydrophobic (water-repellant) so that, basically speaking, the use of the 
resin, which contains the segments, in the formation of the ink-receiving 
layer should not make it possible to expect good results in connection 
with the absorption of a water-based ink. 
It is however known that the surface of an ink-receiving layer made of a 
hydrophilic resin, which contains polysiloxane segments in a specific 
proportion range, is fully covered with polysiloxane segments in a dry 
state but, when the ink-receiving layer is dipped in water or the like, 
the resin shows a phenomenon that the polysiloxane segments are buried 
within the resin, in other words, the resin has environmental 
responsibility [Kobunshi Ronbunshu (see Collected Papers on Polymers), 
48[4], 227 (1991); etc.]. 
In the second aspect of the present invention, this phenomenon is used. The 
formation of an ink-receiving layer with the above-described hydrophilic 
resin, which contains polysiloxane segments, makes it possible to provide 
a recording sheet having good ink absorbency in contrast to an 
expectation, capable of imparting good waterproofness to marks to be 
formed, and also capable of exhibiting good transportability inside a 
printer. Namely, the adequate control of the content of polysiloxane 
segments in resin molecules has made it possible to provide a recording 
sheet excellent in surface lubricity, waterproofness, the transportability 
and blocking resistance in printers, and the like owing to the 
environmental responsibility, because upon being printed with a 
water-based ink, the surface of its ink-receiving layer shows 
hydrophilicity and the polysiloxane segments in the hydrophilic resin act 
to embrace a dye bonded with the resin molecules through ionic bonding 
between tertiary amino groups introduced in the molecules of the 
hydrophilic resin and the ink but, during and after drying subsequent to 
the recording with the water-based ink, the surface of the ink-receiving 
layer is covered with the polysiloxane segments. 
As the hydrophilic resin for use in the present invention, a hydrophilic 
resin containing tertiary amino groups in a molecule thereof and a 
hydrophilic resin containing tertiary amino groups and polysiloxane 
segments in a molecule thereof are both usable. Illustrative examples of 
usable resins can include hydrophilic polyurethane resins, hydrophilic 
polyurea resins, hydrophilic polyurethane-polyurea resins, hydrophilic 
polyamide resin, hydrophilic polyester resins, hydrophilic acrylic resins 
and hydrophilic epoxy resins, all of which contain such groups as 
mentioned above. Among these, preferred hydrophilic resins are hydrophilic 
polyurethane resins, hydrophilic polyurea resins, hydrophilic 
polyurethane-polyurea resins and hydrophilic polyamide resins. 
In the first aspect of the present invention, no particular limitation is 
imposed on the method for introducing tertiary amino groups into molecules 
of the hydrophilic resin to be used. Illustrative can however be to use a 
compound, which contains one or more tertiary amino groups therein, as a 
part of raw materials or to react functional groups in the above-described 
hydrophilic resin free of tertiary amino groups with a tertiary amino 
compound having reactivity upon synthesis (polymerization) of various 
hydrophilic resins such as those described above. 
In the second aspect of the present invention, no particular limitation is 
imposed on the production process of the hydrophilic resin containing 
tertiary amino groups and polysiloxane segments in its molecule. Examples 
of the process can however include to react a hydrophilic resin free of 
such tertiary amino groups and polysiloxane segments with a 
tertiary-amino-group containing reactive compound and a reactive 
polysiloxane compound to introduce tertiary amino groups and polysiloxane 
segments into the resin; to synthesize a reactive resin by using a 
tertiary-amino-group-containing compound as a part of raw material 
components for a hydrophilic resin, followed by a reaction between the 
resin and a reactive polysiloxane compound so that polysiloxane segments 
are introduced into the resin; and to use a 
tertiary-amino-group-containing compound and a 
polysiloxane-segment-containing compound as parts of raw material 
components for a hydrophilic resin and to copolymerize these compounds 
with the remaining raw material component or components to synthesize the 
target resin. Taking into consideration the number of steps required for 
the synthesis of the resin, it is preferred to synthesize the hydrophilic 
resin by polymerization while using a tertiary-amino-group-containing 
compound and a polysiloxane-segment-containing compound as parts of the 
raw materials. 
A description will hereinafter be made about raw material components upon 
production of a hydrophilic resin, which is to be used in the present 
invention, by a polymerization reaction, a post-polymerization reaction or 
the like. 
Firstly, the compound, which is employed for the introduction of tertiary 
amino groups into resin molecules in the first and second aspects of the 
present invention, is a compound containing one or more reactive groups, 
for example, amino, epoxy, hydroxyl, mercapto, carboxyl, alkoxy, acid 
halide, carboxyl ester, acid anhydride or like groups in its molecule and 
also one or more tertiary amino groups in the molecule. 
Preferred examples of tertiary amino compounds having such reactive groups 
therein can include compounds represented by the following formulas 
(1)-(3), respectively. 
##STR1## 
wherein R.sub.1 represents an alkyl group having 20 or fewer carbon atoms, 
an alicyclic group, or an aromatic group which may contain one or more 
substituents such as halogen atoms or alkyl groups; R.sub.2 and R.sub.3 
may be the same or different and individually represent lower alkylene 
groups or lower alkylene groups each of which contains therein a 
connecting group such as --O--, --CO--, --COO--, --NHCO--, --S--, --SO-- 
or --SO.sub.2 --; and X and Y may be the same or different and 
individually represent --OHs, --COOHs, --NH.sub.2 s, --NHR.sub.1 s, --SHs 
or the like or epoxy, alkoxy, acid halide, acid anhydride or carboxyl 
ester groups which can be converted into --OHs, --COOHs, --NH.sub.2 s, 
--NHR.sub.1 s, --SHs or the like. 
##STR2## 
wherein R.sub.1 s, R.sub.2, R.sub.3, X and Y have the same meanings as 
defined above, and the two R.sub.1 s may together form a cyclic structure; 
R.sub.4 represents --(CH.sub.2).sub.n --, n being an integer of from 0 to 
20, or is the same as R.sub.2 or R.sub.3 ; and Z represents CH or N. 
EQU X--W--Y (3) 
wherein X and Y have the same meanings as defined above; and W represents a 
nitrogen-containing heterocyclic group, a nitrogen- and oxygen-containing 
heterocyclic group, or a nitrogen- and sulfur-containing heterocyclic 
group. 
Specific examples of compounds represented by the above formulas (1) to (3) 
can include: 
N,N-dihydroxyethyl-methylamine, 
N,N-dihydroxyethyl-ethylamine, 
N,N-dihydroxyethyl-isopropylamine, 
N,N-dihydroxyethyl-n-butylamine, 
N,N-dihydroxyethyl-t-butylamine, 
methyliminobispropylamine, 
N,N-dihydroxyethylaniline, 
N,N-dihydroxyethyl-m-toluidine, 
N,N-dihydroxyethyl-p-toluidine, 
N,N-dihydroxyethyl-m-chloroaniline, 
N,N-dihydroxyethylbenzylamine, 
N,N-dimethyl-N',N'-dihydroxyethyl-1,3-diaminopropane, 
N,N-diethyl-N',N'-dihydroxyethyl-1,3-diaminopropane, 
N-hydroxyethyl-piperazine, 
N,N'-dihydroxyethyl-piperazine, 
N-hydroxyethoxyethyl-piperazine, 
1,4-bisaminopropyl-piperazine, 
N-aminopropyl-piperazine, 
dipicolinic acid, 
2,3-diaminopyridine, 
2,5-diaminopyridine, 
2,6-diaminopyridine, 
2,6-diamino-4-methylpyridine, 
2,6-dihydroxypyridine, 
2,6-pyridine-dimethanol, 
2-(4-pyridyl)-4,6-dihydroxypyrimidine, 
2,6-diaminotriazine, 
2,5-diaminotriazole, and 
2,5-diaminooxazole. 
Ethylene oxide adducts, propylene oxide adducts and the like of these 
tertiary amino compounds are also usable in the present invention. 
Illustrative of such adducts can be the following compounds: 
##STR3## 
wherein m stands for an integer of from 1 to 60, and n stands for an 
integer of from 1 to 6. 
A polysiloxane compound, which is usable for the introduction of 
polysiloxane segments into molecules of the hydrophilic resin in the 
second aspect of the present invention, contains one or more reactive 
groups, for example, amino, epoxy, hydroxyl, mercapto, carboxyl or like 
groups in its molecule. Preferred examples of the polysiloxane compound 
containing such reactive groups can include the following compounds: 
(1) Amino-modified Polysiloxane Compounds 
##STR4## 
(2) Epoxy-modified Polysiloxane Compounds 
##STR5## 
(3) Alcohol-modified Polysiloxane Compounds 
##STR6## 
(4) Mercapto-modified Polysiloxane Compounds 
##STR7## 
(5) Carboxyl-modified Polysiloxane Compounds 
##STR8## 
Among the above-described polysiloxane compounds, the polysiloxanepolyols 
and the polysiloxanepolyamines are particularly useful. 
The hydrophilic resin useful in the present invention, especially the 
preferred hydrophilic polyurethane resin, hydrophilic polyurea resin, 
hydrophilic polyurethane-polyurea resin or hydrophilic polyamide resin can 
be synthesized in accordance with a conventionally-known resin synthesis 
(polymerization) process by using, as a part or parts of synthesis raw 
materials, the above-described tertiary amino compound in the first aspect 
of the present invention or the above-described tertiary amino compound 
and the above-described reactive-group-containing polysiloxane compound, 
but no particular limitation is imposed on the polymerization process. A 
description will hereinafter be made specifically about preferred 
synthesis processes. 
Other raw material components, which are preferred for the provision of 
hydrophilic resins useful in the present invention by copolymerization 
with the one raw material component (the tertiary amine compound) or the 
two raw material components (the tertiary amine and the 
reactive-group-containing polysiloxane compound), are raw material 
components employed as raw materials for conventional polyurethane resins, 
polyurea resins, polyurethane-polyurea resins or polyamide resins. For 
example, compounds each of which contains a hydroxyl group, amino group, 
carboxyl group or the like as an end group and has a molecular weight in a 
range of from 100 to 8,000 are usually employed. 
Illustrative of compounds containing hydroxyl groups as end groups and 
having hydrophilicity are: 
polyethylene glycol, 
copolymerized polyol of polyethylene glycol and polytetramethylene glycol, 
copolymerized polyol of polyethylene glycol and polypropylene glycol, 
polyethylene glycol adipate, 
polyethylene glycol succinate, 
copolymerized polyol of polyethylene glycol and 
poly-.epsilon.-caprolactone, and 
copolymerized polyol of polyethylene glycol and poly-.gamma.-valerolactone. 
Illustrative of compounds containing amino groups as end groups and having 
hydrophilicity are: 
polyethylene oxide diamine, 
polyethylene oxide propylene oxide diamine, 
polyethylene oxide triamine, and 
polyethylene oxide propylene oxide triamine. 
Besides the above-described compounds, ethylene oxide adducts containing 
carboxyl groups or vinyl groups and like compounds can also be used. One 
or more of other polyols, polyamines and polycarboxylic acid compound 
having no hydrophilicity can also be used in combination with the 
above-described raw material components in order to impart other property 
or properties. 
The preferable weight average molecular weight of the hydrophilic resin 
containing tertiary amino groups in its molecule and employed in the first 
aspect of the present invention and that of the hydrophilic resin 
containing tertiary amino groups and polysiloxane segments in its molecule 
and employed in the second aspect of the present invention, both of said 
resins being available from materials such as those described above, may 
range from about 5,000 to 500,000 or so, with a weight average molecular 
weight of from 100,000 to 200,000 being more preferred. 
When these resins are each synthesized by a polymerization reaction of the 
above-described raw material components, they can be either those 
synthesized in a solventless manner or those synthesized in water or an 
organic solvent. From the standpoint of production steps, production of 
the resin in an organic solvent, which is usable upon formation of an 
ink-receiving layer, or in water is advantageous because the resulting 
resin solution can be used as is for the formation of the ink-receiving 
layer. 
The tertiary amino groups in each hydrophilic resin for use in the present 
invention may be contained in either one or both of its side chains 
(pendants) and its back bone. The content of the tertiary amino groups in 
the resin may preferably be in a range of from 1 to 60 wt. %, in terms of 
the tertiary amino compound as the raw material, of the whole resin. If 
the content of the tertiary amino compound is smaller than the above 
range, an ink-receiving layer cannot fully exhibit waterproofness, 
moisture resistance and the like, the attainment of which is an objective 
of the present invention. On the other hand, a content of the tertiary 
amino compound higher than the above range leads to an ink-receiving layer 
having stronger water repellency due to a reduction in the proportion of 
hydrophilic segments, and hence to deteriorations in the absorbency of a 
water-based ink and the quality of printed marks. Contents of the tertiary 
amino compound outside the above range are therefore not preferred. 
Further, the number of tertiary amino groups may be from 0.1 to 50 
equivalents per gram, preferably from 0.2 to 10.0 equivalents per gram, in 
other words, may be from 1 to 50 groups, preferably from 2 to 5 groups per 
1,000 weight average molecular weight of the hydrophilic resin. If the 
number of tertiary amino groups is smaller than the above range, the 
fixability of a dye, the waterproofness of formed marks, and the like 
properties are insufficient. If the number of tertiary amino groups is 
greater than the above range, on the other hand, the resulting resin is 
provided with stronger water repellency due to a reduction in the 
proportion of hydrophilic segments in the resin, raising a problem in the 
ink absorbency or the like of an ink-receiving layer to be formed. 
In the second aspect of the present invention, the polysiloxane segments in 
the resin may also be contained in either one or both of its side chain 
(pendants) and its backbone. The content of the segments in the resin may 
be in a range of from 0.1 to 10 wt. %, notably of from 0.5 to 10 wt. % of 
the whole resin. If the content of the polysiloxane segments in the resin 
is smaller than 0.1 part by weight, the good surface properties--such as 
waterproofness, high running property, transportability and blocking 
resistance--of a recording sheet, the attainment of which is an objective 
of the present invention, cannot be fully brought about. On the other 
hand, a content of polysiloxane segments higher than 10 wt. % leads to 
stronger water repellency for the polysiloxane segments and hence to 
deteriorations in the absorbency of a water-based ink in an ink-receiving 
layer to be formed and the quality of printed marks to be formed on the 
ink-receiving layer. Contents of polysiloxane segments outside the above 
range are therefore not preferred. 
Usable examples of the base material sheets in the recording sheets 
according to the present invention can include paper sheets, plastic 
films, glass sheets and the like, although no particular limitation is 
imposed on the base material sheets. Exemplary paper sheets can include 
high-quality paper sheets (i.e., wood-free paper sheets), medium-quality 
paper sheets (i.e., paper sheets made of at least 70% of chemical pulp and 
the remainder of groundwood pulp), coated paper sheets, and cast-coated 
paper sheets. Illustrative of plastic films can be polyester, cellulose 
triacetate, polycarbonate, poly(vinyl chloride), polypropylene, polyamide, 
polystyrene, polyethylene and poly(methyl methacrylate) sheets of 50-250 
.mu.m in thickness. If necessary, these base material sheets can each be 
provided with a primer layer to improve the adhesion of its ink-receiving 
layer to the base material sheet and/or can each be provided, on its back 
side opposite to its ink-receiving layer, with an anti-curling layer or 
with a lubricant layer which improves the coefficient of friction. 
As the resin component constituting the ink-receiving layer, the 
above-described resins can be used singly. Depending on the composition of 
an ink to be used in ink-jet recording, each of the above-described resins 
may also be used in combination with another water-soluble resin with a 
view to adjusting the hydrophilicity and/or water absorbency of the 
ink-receiving layer or additionally imparting such property and/or 
properties to the ink-receiving layer. Usable examples of the 
water-soluble resin can include polyvinyl alcohol, modified polyvinyl 
alcohol, hydroxy-ethylcellulose, CMC, cellulose derivatives, 
polyvinyl-pyrrolidone, starch, cationized starch, gelatin, casein, and 
acrylic acid polymers. 
Further, a hydrophobic resin may also be used in combination with the each 
of the above-described resins with a view to imparting additional 
waterproofness and durability to the ink-receiving layer and also to 
printed marks to be formed thereon. Usable examples of the hydrophobic 
resin can include polyester resins, poly(vinyl chloride) resin, 
polystyrene resin, poly(methyl methacrylate) resin, polycarbonate resins, 
polyurethane resins, vinyl chloride-vinyl acetate copolymer resins, 
acrylonitrile-styrene copolymer resins, polyvinyl butyral resin, polyamide 
resins, epoxy resins, urea resins, and melamine resins. 
Moreover, one or more inorganic or organic pigments and/or resin particles 
can also be incorporated in the ink-receiving layer in order to provide 
the ink-receiving layer with improved ink absorbency, dye fixability, 
dye-color-producing ability, blocking resistance and waterproofness. As 
such pigments and resin particles, one or more pigments and resin 
particles can be suitably chosen in accordance with the quality design of 
the recording sheet from known pigments and resin particles, for example, 
mineral or porous pigments--such as kaolin, delaminated kaolin, aluminum 
hydroxide, silica, diatomaceous earth, calcium carbonate, talc, titanium 
oxide, calcium sulfate, barium sulfate, zinc oxide, alumina, calcium 
silicate, magnesium silicate, colloidal silica, zeolite, bentonite, 
sericite and lithopone; fine particles and fine porous particles of 
plastic pigments composed of polystyrene resin, urea resins, acrylic 
resins, melamine resins, benzoguanamine resin or polyurethane resins; and 
hollow particles composed of these materials. 
In addition to such resins and pigments, one or more of various other 
additives can also be incorporated in the ink-receiving layer as needed. 
These additives can include thickening agents, parting agents, penetrating 
agents, wetting agents, thermal gelling agents, sizing agents, defoaming 
agents, foam suppressors, blowing agents, coloring matters, fluorescent 
whiteners, ultraviolet absorbers, oxidation inhibitors, quenchers, 
antiseptic agents, antistatic agents, crosslinking agents, dispersants, 
lubricants, plasticizers, pH regulators, flow improvers, setting 
promoters, and waterproofing agents. 
A description will next be made about the formation of an ink-receiving 
layer. First, a hydrophilic resin containing tertiary amino groups in its 
molecule or a hydrophilic resin containing tertiary amino groups and 
polysiloxane segments in its molecule is dissolved or dispersed either by 
itself or, if necessary, together with one or more other resins in one of 
various organic solvents or in water and, if necessary, one or more of the 
above-described pigments, resin particles and various additives may then 
added and mixed, whereby a coating formulation is prepared. Examples of 
the solvent usable for the preparation of the coating formulation can 
include water (in this case, the coating formulation is obtained in the 
form of a dispersion or an emulsion), methanol, ethanol, propanol, 
acetone, methyl ethyl ketone, toluene, xylene, ethyl acetate, ethyl 
butyrate, dioxane, pyrrolidone, dimethylformamide, formamide and 
dimethylsulfoxide; and mixtures thereof. The concentration of the 
above-described hydrophilic resin in the coating formulation may range 
generally from about 5 to 50 wt. %, preferably from about 10 to 30 wt. %. 
Further, the viscosity of the coating formulation may range from about 1 
to 500 dPa.s, preferably from about 10 to 200 dPa.s in view of coating 
applicability. One or more of the various pigments may be added generally 
in a total amount of from 0 to 5 parts by weight, preferably in a total 
amount of from about 0.5 to 20 parts by weight per 100 parts by weight of 
the hydrophilic resin. 
Illustrative of a coating method of the coating formulation on the base 
material sheet can be gravure coating, direct or reverse roll coating, 
wire bar coating, air knife coating, curtain coating, blade coating, rod 
coating, and die coating. The recording sheet according to the present 
invention can be obtained by applying the coating formulation on at least 
one side of the base material sheet to give a predetermined dry thickness 
and then drying the thus-applied coating formulation. After the 
application of the coating formulation, surface finishing may be applied 
by using a calender such as a machine calender, supercalender or soft 
calender. 
The coating weight of the above coating formulation may be generally from 
0.5 to 50 g/m.sup.2 or so, preferably from 3 to 30 g/cm.sup.2 or so in 
terms of dry weight. If the coating weight is smaller than 0.5 g/m.sup.2, 
the resulting ink-receiving layer cannot exhibit sufficient ink 
absorbency. Even if the coating weight exceeds 50 g/m.sup.2, the effects 
of the present invention are not exhibited to greater extents. 
Accordingly, such an excessively large coating weight is not economical 
and, moreover, tends to induce folding, cracking, curling and the like on 
the resulting recording sheet.

The present invention will next be described more specifically by the 
following Referential Examples, Examples and Comparative Examples, in 
which all the designations of "part" or "parts" and "%" are by weight 
unless otherwise specifically indicated. 
(1) First Aspect of the Invention 
Referential Example 1 
(Synthesis Example of Polyurethane Resin) 
In a reactor, 150 parts of polyethylene glycol (molecular weight: 2,040), 
20 parts of N-methyldiethanolamine and 5 parts of ethylene glycol were 
dissolved in a mixed solvent consisting of 150 parts of methyl ethyl 
ketone and 210 parts of dimethylformamide. While thoroughly stirring the 
solution at 60.degree. C., a solution of 74 parts of hydrogenated MDI in 
100 parts of methyl ethyl ketone was gradually added dropwise. After 
completion of the dropwise addition, they were reacted at 80.degree. C. 
for 6 hours so that a polyurethane resin solution useful in the present 
invention was obtained. This resin solution had a viscosity of 530 dPa.s 
(25.degree. C.) at a solid content of 35%. The breaking strength, breaking 
extension and softening point of a film formed from the resin solution 
were 24.5 MPa, 450% and 115.degree. C., respectively. 
Referential Example 2 
(Synthesis Example of Polyurea Resin) 
In a reactor, 150 parts of polyethylene oxide diamine ("Jeffermin ED", 
trade name; product of Texaco Chemical Inc.; molecular weight: 2,000), 30 
parts of methyliminobispropylamine and 4 parts of 1,4-diaminobutane were 
dissolved in 200 parts of dimethylformamide. While thoroughly stirring the 
solution with its internal temperature controlled within a range of from 
20 to 30.degree. C., a solution of 83 parts of hydrogenated MDI in 100 
parts of dimethylformamide was gradually added dropwise to react them. 
After completion of the dropwise addition, the internal temperature was 
gradually raised. When 50.degree. C. was reached, they were reacted 
further for 6 hours. Then, 195 parts of dimethylformamide were added, 
whereby a polyurea resin solution useful in the present invention was 
obtained. This resin solution had a viscosity of 230 dPa.s (25.degree. C.) 
at a solid content of 35%. The breaking strength, breaking extension and 
softening point of a film formed from the resin solution were 27.6 MPa, 
310% and 145.degree. C., respectively. 
Referential Example 3 
(Synthesis Example of Polyurethane-polyurea Resin) 
In a reactor, 150 parts of polyethylene oxide diamine ("Jeffermin ED", 
trade name; product of Texaco Chemical Inc.; molecular weight: 2,000), 30 
parts of N,N-dimethyl-N',N'-dihydroxyethyl-1,3-diaminopropane and 6 parts 
of triethylene glycol were dissolved in 140 parts of dimethylformamide. 
While thoroughly stirring the solution with its internal temperature 
controlled within a range of from 20 to 30.degree. C., a solution of 70 
parts of hydrogenated MDI in 200 parts of methyl ethyl ketone was 
gradually added dropwise. After completion of the dropwise addition, the 
contents were allowed to react at 80.degree. C. for 6 hours. After 
completion of the reaction, 135 parts of methyl ethyl ketone were added so 
that a polyurethane-polyurea resin solution useful in the present 
invention was obtained. The resin solution had a viscosity of 280 dPa.s 
(25.degree. C.) at a solid content of 35%. The breaking strength, breaking 
extension and softening point of a film formed from the resin solution 
were 14.7 MPa, 450% and 107.degree. C., respectively. 
Referential Example 4 
(Synthesis Example of Polyamide Resin) 
To a solution of 14.6 parts of adipic acid in 200 parts of anhydrous 
ethanol in a reactor, a solution of 120 parts of polyethylene oxide 
diamine ("Jeffermin ED", trade name; product of Texaco Chemical Inc.; 
molecular weight: 2,000), 3 parts of methyliminobispropylamine and 2 parts 
of 1,4-diaminobutane in 100 parts of anhydrous ethanol was added dropwise 
at room temperature. After exotherm subsided, the reaction mixture was 
cooled, whereby a nylon salt was allowed to precipitate. 
After the nylon salt was collected by filtration and dried, 160 parts of 
the nylon salt were dissolved in 40 parts of water. The resulting solution 
was placed in an autoclave. The autoclave was purged with nitrogen gas, 
and its valve was closed. When the internal temperature and pressure 
reached 220.degree. C. and 1.5 MPa, respectively, the valve was opened to 
release water vapor. Heating was continued while maintaining the pressure. 
Polycondensation was conducted for 4 hours and, after that, the internal 
pressure was allowed to slowly drop to atmospheric pressure. After 
cooling, the reaction product was taken out and dissolved in 
N-methyl-2-pyrrolidone. This resin solution had a viscosity of 50 dPa.s 
(25.degree. C.) at a solid content of 30%. The breaking strength, breaking 
extension and softening point of a film formed from the resin solution 
were 7.8 MPa, 130% and 140.degree. C., respectively. 
Referential Example 5 
(Synthesis Example of Polyurethane Resin for Use in a Comparative Example) 
A polyurethane resin solution was obtained using the same materials and 
formula as in Referential Example 1 except that N-methyldiethanolamine was 
not used. This resin solution had a viscosity of 500 dPa.s (25.degree. C.) 
at a solid content of 35%. The breaking strength, breaking extension and 
softening point of a film formed from the resin solution were 21.5 MPa, 
400% and 102.degree. C., respectively. 
Referential Example 6 
(Synthesis Example of Polyurea Resin for Use in a Comparative Example) 
A polyurea resin solution was obtained using the same materials and formula 
as in Referential Example 2 except that methyliminobispropylamine was not 
used. This resin solution had a viscosity of 300 dPa.s (25.degree. C.) at 
a solid content of 35%. The breaking strength, breaking extension and 
softening point of a film formed from the resin solution were 26.0 MPa, 
260% and 140.degree. C., respectively. 
Referential Example 7 
(Synthesis Example of Polyurethane-polyurea Resin for Use in a Comparative 
Example) 
A polyurethane-polyurea resin solution was obtained using the same 
materials and formula as in Referential Example 3 except that 
N,N-dimethyl-N',N'-dihydroxyethyl-1,3-diaminopropane was not used. This 
resin solution had a viscosity of 220 dPa.s (25.degree. C.) at a solid 
content of 35%. The breaking strength, breaking extension and softening 
point of a film formed from the resin solution were 13.0 MPa, 470% and 
88.degree. C., respectively. 
Referential Example 8 
(Synthesis Example of Polyamide Resin for Use in a Comparative Example) 
A polyamide resin solution was obtained using the same materials and 
formula as in Referential Example 4 except that methyliminobispropylamine 
was not used. This resin solution had a viscosity of 55 dPa.s (25.degree. 
C.) at a solid content of 30%. The breaking strength, breaking extension 
and softening point of a film formed from the resin solution were 8.0 MPa, 
130% and 135.degree. C., respectively. 
The weight average molecular weights of the respective resins obtained 
above in Referential Examples 1-8 and the numbers of tertiary amino groups 
per 1,000 weight average molecular weight in the respective resins were as 
shown below in Table 1. 
TABLE 1 
______________________________________ 
Referential Weight average 
Number of tertiary 
Example molecular weight 
amino groups 
______________________________________ 
1 87,000 0.67 eq/g 
2 63,000 0.76 eq/g 
3 69,000 1.23 eq/g 
4 72,000 0.22 eq/g 
5 84,000 0 
6 70,000 0 
7 65,000 0 
8 74,000 0 
______________________________________ 
EXAMPLES 1-4 
In each Example, 40 parts of the resin obtained in the corresponding one of 
Referential Examples 1-4, 100 parts of fine particulate synthetic 
amorphous silica (BET specific surface area: 300 m.sup.2 /g, product of 
Mizusawa Industrial Chemicals, Ltd.) and 0.2 part of a dispersant (sodium 
polypyrophosphate) were dispersed and mixed in a methyl ethyl 
ketone/toluene mixed solvent, and the solid content of the resulting 
dispersion was adjusted to 15%. Four coating formulations according to the 
present invention were therefore obtained for the formation of 
ink-receiving layers. Each coating formulation was applied by an air knife 
coater on a wood-free paper sheet having a basis weight of 35 g/m.sup.2 to 
give a solid coat weight of 10 g/m.sup.2, and was then dried. The 
thus-coated paper sheet was supercalendered under a linear pressure of 200 
Kg/cm to form an ink-receiving layer. Four recording sheets according to 
the present invention were therefore obtained in Examples 1-4, 
respectively. 
Comparative Examples 1-4 
In each Comparative Example, 40 parts of the resin obtained in the 
corresponding one of Referential Examples 5-8, 100 parts of fine 
particulate synthetic amorphous silica (BET specific surface area: 300 
m.sup.2 /g, product of Mizusawa Industrial Chemicals, Ltd.) and 0.2 part 
of a dispersant (sodium polypyrophosphate) were dispersed and mixed in a 
methyl ethyl ketone/toluene mixed solvent, and the solid content of the 
resulting dispersion was adjusted to 15%. Four coating formulations were 
therefore obtained for the formation of ink-receiving layers. Each coating 
formulation was applied by an air knife coater on a wood-free paper sheet 
having a basis weight of 35 g/m.sup.2 to give a solid coat weight of 10 
g/m.sup.2, and was then dried. The thus-coated paper sheet was 
supercalendered under a linear pressure of 200 Kg/cm to form an 
ink-receiving layer. Four recording sheets were therefore obtained in 
Comparative Examples 1-4, respectively. 
Using the eight (8) recording sheets obtained as described above, printing 
or recording was conducted with four colors of yellow, magenta, cyan and 
black on an ink-jet printer which was designed to perform printing or 
recording with inks of water-soluble dyes. The following properties were 
ranked. The ranking results are presented in Table 2. 
Ink Absorbency 
The number of seconds required until printed inks dried was counted, and 
ink absorbency was ranked in accordance with the following ranking 
standard. 
A: 5 seconds or shorter. 
B: 6 to 10 seconds. 
C: 11 seconds or longer. 
Vividness of Produced Colors 
A color mark was printed by the above-described printer and the vividness 
of the thus-obtained color mark was then visually observed. The vividness 
of the produced colors was ranked in accordance with the following ranking 
standard. 
A: Good 
B: Average 
C: Poor 
Blotting Resistance 
The extents of ink blotting and bleeding at an overprinted boundary area of 
magenta and cyan were visually observed. The blotting resistance was 
ranked in accordance with the following ranking standard. 
A: Good 
B: Average 
C: Poor 
Waterproofness of Ink-receiving Layer 
Each ink-receiving layer was wetted with water. The state of separation of 
the ink-receiving layer upon wiping the water off under constant finger 
pressure was visually observed. The waterproofness of the ink-receiving 
layer was ranked in accordance with the following ranking standard. 
A: No change. 
B: Changed in surface conditions. 
C: Separated. 
Waterproofness of Printed Mark 
After printing each recording sheet by the printer, the recording sheet was 
dipped for 10 minutes in water, and the recording sheet was then dried at 
room temperature. The recorded mark was visually observed for changes in 
blotting and color. The waterproofness of the printed mark was ranked in 
accordance with the following ranking standard. 
A: No change. 
B: Some color changes were observed. 
C: Color changes were observed. 
The resin solutions obtained in Referential Examples 1-8 were individually 
coated on 100-.mu.m PET films to give a dry coat thickness of 20 .mu.m, 
whereby transparent sheets were produced. In a similar manner as described 
above, printing or recording was conducted by the ink jet printer. 
Properties were ranked by the following methods, respectively. 
Blocking Resistance 
An untreated PET film was placed over the resin-coated side of each 
transparent sheet and, under a load of 0.29 MPa, the film and the sheet 
were left over at 40.degree. C. for 1 day. The untreated PET film was then 
removed, and the blocking resistance of the transparent sheet was visually 
observed. The blocking resistance was ranked in accordance with the 
following ranking standard. 
A: No blocking. 
B: Slight blocking. 
C: Severe blocking. 
Printer Transportability 
The printer transportability of each transparent sheet upon printing or 
recording it by the ink-jet printer was observed, and was ranked in 
accordance with the following ranking standard. 
A: Good transportability. 
B: Slight noise was produced. 
C: Poor transportability. 
Waterproofness of Printed Mark 
After each transparent sheet was printed by the printer, the recorded sheet 
was dipped for 24 hours in water and was then dried at room temperature. 
The recorded mark was visually observed for changes in blotting and color. 
The waterproofness of the printed mark was ranked in accordance with the 
following ranking standard. 
A: No change. 
B: Some color changes were observed. 
C: The dyes were completely dissolved, resulting in the disappearance of 
the mark. 
TABLE 2 
______________________________________ 
Comparative 
Example Example 
Ranked properties 
1 2 3 4 1 2 3 4 
______________________________________ 
Ink absorbency 
A A A A A A A A 
Vividness of 
A A A A A A A A 
produced color 
Blotting resistance 
A A A A A A A A 
Waterproofness of 
A A A A B B B B 
ink-receiving layer 
Waterproofness of 
A A A A B B B B 
printed mark (wood- 
free paper sheet) 
Blocking resistance 
A A A A C B C B 
Printer transport- 
A A A A C B C B 
ability 
Waterproofness of 
A A A A C C C C 
printed mark (PET 
film) 
______________________________________ 
As has been described above, the first aspect of the present invention 
provides an ink-jet recording sheet, which gives printed marks of high 
quality, is excellent in the waterproofness and moisture resistance of its 
ink-receiving layer and printed marks, and also is excellent in the 
transportability and blocking resistance in a printer. 
[Second Aspect of the Present Invention] 
Referential Example 1 
(Synthesis Example of Polyurethane Resin) 
##STR9## 
(wherein a stands for an integer to give a molecular weight of 3,200.) 
In a reactor, 8 parts of a polydimethylsiloxanepolyol having the 
above-described structure (molecular weight: 3,200), 142 parts of 
polyethylene glycol (molecular weight: 2,040), 20 parts of 
N-methyldiethanolamine and 5 parts of diethylene glycol were dissolved in 
a mixed solvent consisting of 100 parts of methyl ethyl ketone and 200 
parts of dimethylformamide. While thoroughly stirring the solution at 
60.degree. C., a solution of 73 parts of hydrogenated MDI in 100 parts of 
methyl ethyl ketone was gradually added dropwise. After completion of the 
dropwise addition, they were reacted at 80.degree. C. for 6 hours. Sixty 
parts of methyl ethyl ketone were then added so that a polyurethane resin 
solution was obtained. This solution had a viscosity of 330 dPa.s 
(25.degree. C.) at a solid content of 35%. The breaking strength, breaking 
extension and softening point of a film formed from the resin solution 
were 20.5 MPa, 400% and 103.degree. C., respectively. 
Referential Example 2 
(Synthesis Example of Polyurea Resin) 
##STR10## 
(wherein c stands for an integer to give a molecular weight of 3,880.) 
In a reactor, 5 parts of a polydimethylsiloxanediamine having the 
above-described structure (molecular weight: 3,880), 145 parts of 
polyethylene oxide diamine ("Jeffermin ED", trade name; product of Texaco 
Chemical Inc.; molecular weight: 2,000), 25 parts of 
methyliminobispropylamine and 5 parts of 1,4-diaminobutane were dissolved 
in 250 parts of dimethylformamide. While thoroughly stirring the solution 
with its internal temperature controlled within a range of from 20 to 
30.degree. C., a solution of 75 parts of hydrogenated MDI in 100 parts of 
dimethylformamide was gradually added dropwise to react them. After 
completion of the dropwise addition, the internal temperature was 
gradually raised. When 50.degree. C. was reached, they were reacted 
further for 6 hours. Dimethylforamide (125 parts) was then added so that a 
polyurea resin solution useful in the present invention was obtained. This 
resin solution had a viscosity of 315 dPa.s (25.degree. C.) at a solid 
content of 35%. The breaking strength, breaking extension and softening 
point of a film formed from the resin solution were 31.3 MPa, 370% and 
147.degree. C., respectively. 
Referential Example 3 
(Synthesis Example of Polyurethane-polyurea Resin) 
##STR11## 
(wherein m and n stand for integers to give a molecular weight of 4,500.) 
In a reactor, 5 parts of an ethylene-oxide-added polydimethylsiloxane 
having the above structure (molecular weight: 4,500), 145 parts of 
polyethylene oxide diamine ("Jeffermin ED", trade name; product of Texaco 
Chemical Inc.; molecular weight: 2,000), 30 parts of 
N,N-dimethyl-N',N'-dihydroxyethyl-1,3-diaminopropane and 5 parts of 
dimethylformamide were dissolved in a mixed solvent consisting of 150 
parts of methyl ethyl ketone and 150 parts of dimethylformamide. While 
thoroughly stirring the solution at 60.degree. C., a solution of 72 parts 
of hydrogenated MDI in 100 parts of methyl ethyl ketone was gradually 
added dropwise. After completion of the dropwise addition, the contents 
were allowed to react at 80.degree. C. for 6 hours. After completion of 
the reaction, 75 parts of methyl ethyl ketone were added so that a 
polyurethane-polyurea resin solution useful in the present invention was 
obtained. The resin solution had a viscosity of 390 dPa.s (25.degree. C.) 
at a solid content of 35%. The breaking strength, breaking extension and 
softening point of a film formed from the resin solution were 22.7 MPa, 
450% and 127.degree. C., respectively. 
Referential Example 4 
(Synthesis Example of Polyamide Resin) 
To a solution of 14.6 parts of adipic acid in 200 parts of anhydrous 
ethanol in a reactor, a solution of 11.6 parts of the 
polydimethylsiloxanediamine of Referential Example 2, 114 parts of 
polyethylene oxide diamine ("Jeffermin ED", trade name; product of Texaco 
Chemical Inc.; molecular weight: 2,000) and 6 parts of 
methyliminobispropylamine in 100 parts of anhydrous ethanol was added at 
room temperature. After exotherm subsided, the reaction mixture was 
cooled, whereby a nylon salt was allowed to precipitate. 
After the nylon salt was collected by filtration and dried, 160 parts of 
the nylon salt were dissolved in 40 parts of water. The resulting solution 
was placed in an autoclave. The autoclave was purged with nitrogen gas, 
and its valve was closed. When the internal temperature and pressure 
reached 220.degree. C. and 1.5 MPa, respectively, the valve was opened to 
release water vapor. Heating was continued while maintaining the pressure. 
Polycondensation was conducted for 4 hours and, after that, the internal 
pressure was allowed to slowly drop to atmospheric pressure. After the 
contents were cooled, the reaction product was taken out and dissolved in 
N-methyl-2-pyrrolidone. This resin solution had a viscosity of 42 dPa.s 
(25.degree. C.) at a solid content of 30%. The breaking strength, breaking 
extension and softening point of a film formed from the resin solution 
were 6.8 MPa, 135% and 137.degree. C., respectively. 
Referential Example 5 
(Synthesis Example of Polyurethane Resin for Use in a Comparative Example) 
A polyurethane resin solution was obtained using the same materials and 
formula as in Referential Example 1 except that polydimethylsiloxane 
polyol and N-methyldiethanolamine were not used. This resin solution had a 
viscosity of 500 dPa.s (25.degree. C.) at a solid content of 35%. The 
breaking strength, breaking extension and softening point of a film formed 
from the resin solution were 6.8 MPa, 250% and 106.degree. C., 
respectively. 
Referential Example 6 
(Synthesis Example of Polyurea Resin for Use in a Comparative Example) 
A polyurea resin solution was obtained using the same materials and formula 
as in Referential Example 2 except that polydimethylsiloxanediamine and 
methyliminobispropylamine were not used. This resin solution had a 
viscosity of 300 dPa.s (25.degree. C.) at a solid content of 35%. The 
breaking strength, breaking extension and softening point of a film formed 
from the resin solution were 28.0 MPa, 300% and 144.degree. C., 
respectively. 
Referential Example 7 
(Synthesis Example of Polyurethane-polyurea Resin for Use in a Comparative 
Example) 
A polyurethane-polyurea resin solution was obtained using the same 
materials and formula as in Referential Example 3 except that 
polydimethylsiloxane and 
N,N-dimethyl-N',N'-dihydroxyethyl-1,3-diaminopropane were not used. This 
resin solution had a viscosity of 220 dPa.s (25.degree. C.) at a solid 
content of 35%. The breaking strength, breaking extension and softening 
point of a film formed from the resin solution were 15.0 MPa, 430% and 
88.degree. C., respectively. 
Referential Example 8 
(Synthesis Example of Polyamide Resin for Use in a Comparative Example) 
A polyamide resin solution was obtained using the same materials and 
formula as in Referential Example 4 except that 
polydimethylsiloxanediamine and methyliminobispropylamine were not used. 
This resin solution had a viscosity of 55 dPa.s (25.degree. C.) at a solid 
content of 30%. The breaking strength, breaking extension and softening 
point of a film formed from the resin solution were 8.0 MPa, 130% and 
138.degree. C., respectively. 
The weight average molecular weights of the respective resins obtained 
above in Referential Examples 1-8 and the numbers of tertiary amino groups 
per 1,000 weight average molecular weight in the respective resins were as 
shown below in Table 3. 
TABLE 3 
______________________________________ 
Weight 
average Number of Content of 
Referential 
molecular tertiary polysiloxane 
Example weight amino groups 
segments 
______________________________________ 
1 75,000 0.66 eq/g 3.2% 
2 71,000 0.75 eq/g 2.0% 
3 77,000 1.22 eq/g 1.2% 
4 67,000 0.22 eq/g 7.5% 
5 84,000 0 0 
6 70,000 0 0 
7 65,000 0 0 
8 74,000 0 0 
______________________________________ 
EXAMPLES 1-4 
In each Example, 40 parts of the resin obtained in the corresponding one of 
Referential Examples 1-4, 100 parts of fine particulate synthetic 
amorphous silica (BET specific surface area: 300 m.sup.2 /g, product of 
Mizusawa Industrial Chemicals, Ltd.) and 0.2 part of a dispersant (sodium 
polypyrophosphate) were dispersed and mixed in a methyl ethyl 
ketone/toluene mixed solvent, and the solid content of the resulting 
dispersion was adjusted to 15%. Four coating formulations were therefore 
obtained for the formation of ink-receiving layers. Each coating 
formulation was applied by an air knife coater on a wood-free paper sheet 
having a basis weight of 35 g/m.sup.2 to give a solid coat weight of 10 
g/m.sup.2, and was then dried. The thus-coated paper sheet was 
supercalendered under a linear pressure of 200 Kg/cm to form an 
ink-receiving layer. Four recording sheets according to the present 
invention were therefore obtained in Examples 1-4, respectively. 
Comparative Examples 1-4 
In each Comparative Example, 40 parts of the resin obtained in the 
corresponding one of Referential Examples 5-8, 100 parts of fine 
particulate synthetic amorphous silica (BET specific surface area: 300 
m.sup.2 /g, product of Mizusawa Industrial Chemicals, Ltd.) and 0.2 part 
of a dispersant (sodium polypyrophosphate) were dispersed and mixed in a 
methyl ethyl ketone/toluene mixed solvent, and the solid content of the 
resulting dispersion was adjusted to 15%. Four coating formulations were 
therefore obtained for the formation of ink-receiving layers. Each coating 
formulation was applied by an air knife coater on a wood-free paper sheet 
having a basis weight of 35 g/m.sup.2 to give a solid coat weight of 10 
g/m.sup.2, and was then dried. The thus-coated paper sheet was 
supercalendered under a linear pressure of 200 Kg/cm to form an 
ink-receiving layer. Four recording sheets were therefore obtained in 
Comparative Examples 1-4, respectively. 
Using the eight (8) recording sheets obtained as described above, their 
properties were ranked by the same methods as in the first aspect of the 
present invention. Ranking results are presented in Table 4. 
TABLE 4 
______________________________________ 
Comparative 
Example Example 
Ranked properties 
1 2 3 4 1 2 3 4 
______________________________________ 
Ink absorbency 
A A A A A A A A 
Vividness of 
produced color 
A A A A A A A A 
Blotting resistance 
A A A A A A A A 
Waterproofness of 
ink-receiving layer 
A A A A B B B B 
Waterproofness of 
printed mark (wood- 
A A A A B B B B 
free paper sheet) 
Blocking resistance 
A A A A C B C B 
Printer transport- 
A A A A B B C B 
ability 
Waterproofness of 
printed mark (PET 
A A A A C C C C 
film) 
______________________________________ 
As has been described above, the second aspect of the present invention 
provides an ink-jet recording sheet, which gives printed marks of high 
quality, is excellent in the waterproofness and moisture resistance of its 
ink-receiving layer and printed marks, and also is excellent in the 
transportability and blocking resistance in a printer. 
As has been described above, the formation of an ink-receiving layer of an 
ink-jet recording sheet with a hydrophilic resin containing tertiary amino 
groups in its molecule or a hydrophilic resin containing tertiary amino 
groups and polysiloxane segments in its molecule, most preferably with a 
hydrophilic polyurethane resin, hydrophilic polyurea resin, hydrophilic 
polyurethane-polyurea resin or hydrophilic polyamide resin as a component 
makes it possible to provide a recording sheet which is excellent in ink 
absorbency and color-producing ability, gives stable printed marks of high 
quality, imparts superb waterproofness and moisture resistance to the 
ink-receiving layer and the printed marks, and is also excellent in the 
transportability and blocking resistance in a printer.