One-pack type epoxy sealant with amine-type curing agent, for liquid crystal cell, display apparatus and recording apparatus

A liquid crystal cell is prepared by bonding a pair of oppositely disposed electrode plates with a sealant of a one-pack type epoxy adhesive to define a space to be filled with a liquid crystal. In advance of the use, the one-pack type epoxy adhesive is modified with an amine-type room temperature hardener to selectively reduce a low-molecular weight fraction in the epoxy adhesive so as to avoid a sealant flow at an elevated temperature. This is particularly advantageous when the sealant is used in combination with a particulate adhesive which is disposed in the liquid crystal space and activated at such an elevated temperature to bond the electrode plates while keeping an accurate gap between the electrode plates.

FIELD OF THE INVENTION AND RELATED ART 
The present invention relates to a sealant for bonding substrates, 
particularly a sealant for liquid crystal cells for boding a pair of 
opposite electrode plates of a liquid crystal cell which may be loaded in 
a display apparatus or a recording apparatus. 
A one-pack type or single-liquid type epoxy resin adhesive has been 
conventionally used as an adhesive for constituting a sealant for liquid 
crystal cells, because of its high strength and excellent heat resistance, 
chemical resistance and moisture resistance, etc. 
For example, Japanese Laid-Open Patent Application (JP-A) Sho 59-126511 
(assigned to Mitsui Toatsu Kabushiki Kaisha) discloses a one-pack type 
epoxy resin adhesive which comprises (a) an epoxy resin, (b) a hydrazide 
compound having a hydrazide group as a potential hardener, (c) a filler, 
and optionally (d) a solvent. It is also disclosed that the adhesive may 
be used for production of a liquid crystal cell. 
In a conventional liquid crystal cell production process using such a 
one-pack type epoxy resin adhesive, a sealant comprising the adhesive is 
applied generally by printing onto at least one of a pair of substrates, 
and then the pair of substrates superposed in alignment with each other, 
followed by pressure bonding. The pressure bonding is effected for 
pressing the sealant to provide the entire panel uniformly with a 
prescribed gap and for fixing the alignment of the pair of substrates. 
The sealant used in this instance is required of the following properties 
(1)-(3) in combination: 
(1) a viscosity appropriate for printing; 
(2) an appropriate tackiness to the substrates; and 
(3) a sufficiently high viscosity so that it does not flow at the time of 
the pressure bonding or the substrates are not moved from each other. The 
above properties (1) and (3) are generally contradictory to each other. 
FIG. 3 is an illustration of sealant flow wherein a sealant 106 applied 
between a display area 211 and a scribe line 313 at which the substrates 
have been cut, has caused a sealant flow-out 312. Such a sealant flow is 
especially frequently encountered where such a one-pack type epoxy resin 
is not used, because the above property (3) is lacked, thus resulting in 
failure of increase in production yield and higher resolution. 
In the case of using a one-pack type epoxy adhesive, a latent or potential 
hardener contained therein is activated generally at 120.degree. C. or 
higher to promote the curing, so that the adhesive can be diluted with a 
solvent to allow a relatively wide viscosity adjustment and also the 
solvent can be dried under heating at a temperature below the activation 
temperature. Accordingly, the above required properties (1) and (3) have 
been satisfied simultaneously, so that the problems of sealant flow and 
alignment failure at the time of pressure bonding and curing have been 
solved. 
Such a one-pack type epoxy adhesive is accompanied with a change in 
printing characteristic depending on the selection of a diluting solvent 
and a dilution ratio. For example, it has been possible to use a batch of 
adhesive for a long time of continuous operation if the printing 
characteristic is stabilized by using a solvent having a higher boiling 
point at a higher proportion. 
However, the use of such a one-pack type epoxy adhesive is not always 
satisfactory in view of recent requirements for a larger area, a higher 
resolution and a higher drive speed of a panel (liquid crystal cell). For 
these requirements, an STN (super twisted nematic) liquid crystal device 
and an FLC (ferroelectric liquid crystal) device requiring a smaller gap 
of 5-6 microns and 1-2 microns, respectively, have been developed. In 
these devices, such a small gap is required to be maintained with a 
tolerance of 0.05-0.10 micron over a wide area. Accordingly, it has been 
required to uniformly disperse spacers and maintain the distribution of 
the spacers for a long time and also to fix the pair of substrates to each 
other with a constant gap over the entire extension of the panel by 
bonding the substrates at points and secure the gap between the substrates 
provided under pressure bonding 
For such bonding between a pair of substrates, it is most practical at 
present to use a hot melt type particulate adhesive in view of wide 
applicability to general usages and little influence on display quality. 
For optimization of the production process, it is further desirable to 
soften the particulate adhesive under heating for providing a prescribed 
gap simultaneously with the pressure bonding of the sealant. 
However, if the heating for the particulate adhesive is applied to the 
sealant of a conventional one-pack type epoxy adhesive under application 
of a pressure for providing a small gap of several microns, the 
above-mentioned sealant flow can occur to a practically non-acceptable 
level in some cases. 
SUMMARY OF THE INVENTION 
A principal object of the present invention is to provide a sealant which 
solves the above-mentioned problem of sealant flow even at a softening 
point of a particulate adhesive without impairing various advantages of a 
one-pack type epoxy adhesive. 
According to a principal aspect of the present invention, there is provided 
a sealant for a liquid crystal cell wherein a pair of oppositely disposed 
electrode plates are bonded to each other with the sealant to define space 
to be filed with a liquid crystal, comprising a one-pack type 
thermosetting epoxy adhesive and an amine-type room temperature hardener 
modifying the epoxy adhesive. 
These and other objects, features and advantages of the present invention 
will become more apparent upon a consideration of the following 
description of the preferred embodiments of the present invention taken in 
conjunction with the accompanying drawings.

DETAILED DESCRIPTION OF THE INVENTION 
FIG. 1 is a schematic partial sectional view of a liquid crystal cell 
according to the present invention. Referring to FIG. 1, the liquid 
crystal cell comprises a pair of substrates 101 each having thereon 
transparent electrodes 102, metal wires (or electrodes) 103, an insulating 
layer 104 and an alignment film 105, a sealant 106 for bonding the pair of 
substrates, a liquid crystal 107, a spacer 108 for holding the thickness 
of the liquid crystal layer, and a particulate adhesive 109. 
The sealant 106 according to the present invention comprises a one-pack 
type thermosetting epoxy adhesive, which in turn comprises an epoxy resin 
and a potential hardener. 
The epoxy resin used in the present invention is a compound having two or 
more epoxy groups in its molecules. Examples thereof may include the 
following classes I-IV of compounds: 
I. Polycondensation resins between active hydrogen-containing compounds 
inclusive of: 
(1) bisphenols, such as bisphenol A and bisphenol F, 
(2) hydroxy compounds, such as novolak resin formed by condensation between 
phenol or cresol and formaldehyde, tetrahydroxyphenylmethane, and 
resorcinol, 
(3) amine compounds, such as diaminodiphenyl methane, aniline and 
xylenediamine, 
(4) polyhydric alcohols, such as glycerin and pentaerythritol, and 
(5) carboxy compounds, such as phthalic acid and hexahydrophthalic acid; 
and epihalohydrins, such as epichlorohydrin and epibromohydrin, or 
methylepihalohydrins, such as methylepichlorohydrin; and halogenated 
products of the polycondensation resins; 
II. epoxidized aliphatic acids and derivatives thereof, such as epoxidized 
soybean oil; 
III. epoxidized diene polymers, such as epoxidized polybutadiene, and 
epoxidized polyisoprene; and 
IV. aliphatic epoxy resins, such as 3,4-epoxy-6-methylcyclohexylmethyl 
3,4-epoxy-6-methylcyclohexanecarbonate, vinylcyclohexene diepoxide, and 
bis(2,3-epoxycyclopentyl) ether. These epoxy resins may be used singly or 
in mixture of two or more species and may have a number-average molecular 
weight of 300-1500 (corresponding to that of polystyrene based on GPC (gel 
permeation chromatography)). Particularly suitable epoxy resins may be 
those belonging to the Class I, particularly those derived from the 
compounds of (1)-(3). 
In case where two or more species of epoxy resins are used, it is 
sufficient that they have averagely a number-average molecular weight of 
300-500. The reason for the definition of a number-average molecular 
weight of 300-1500 (before the addition of the room temperature hardener) 
is as follows. Thus, an average molecular weight of below 300 results in a 
poor adhesiveness with cell-constituting materials, thus failing to 
provide sufficient physical and chemical stabilities, and also results in 
an insufficient heat resistance. On the other hand, an average molecular 
weight of over 1500 results in a poor adhesiveness or tackiness after 
pre-drying, thus leading to a difficulty that the cell substrate and 
member to be bonded thereto superposed on each other after pre-drying are 
liable to change their relative positions due to external impact, 
vibration, etc. A particularly preferred range of the average molecular 
weight of the epoxy resin is 400-800. 
The potential hardener to be used in the present invention may be a 
hardener for an epoxy resin which may be activated at 
100.degree.-140.degree. C., desirably 110.degree.-130.degree. C., most 
suitably at 120.degree.-125.degree. C. The potential hardener may 
preferably be a hydrazide compound, examples of which may include: 
mono-basic acid hydrazides, such as salicylohydrazide, p-oxybenzohydrazide 
and phenylaminopropionohydrazide; and dibasic acid dihydrazides, such as 
succinohydrazide, adipinodihydrazide isophthalodihydrazide, 
dodecanodihydrazide, sebacodihydrazide, thiodipropionohydrazide, 
furandicarbodihydrazide, and cyclohexanecarbodihydrazide. Among these, 
dibasic acid dihydrazides are particularly preferred. These hydrazide 
compounds may be used singly or in mixture of two or more species. 
The hydrazide compound functions as a hardener for an epoxy resin and, when 
mixed with an epoxy resin, provides a mixture having a long shelf life at 
room temperature, which can be used as a one-pack type epoxy resin 
adhesive. Further, compared with other hardeners usable in one-pack type 
epoxy resin adhesives, such as dicyanodiamide and BF.sub.3 compounds, 
initiates the hardening reaction at a relatively low temperature and also 
has an effect of imparting extremely high heat resistance, low-temperature 
characteristic and water resistance. It is also advantageous that no 
electrically harmful substance is generated therefrom. 
The potential hardener, particularly a hydrazide compound, may be used in 
an amount of providing 0.15-0.35 mol of hydrazide group for 1 mol of epoxy 
group in the epoxy resin. If the amount is below 0.15 mol, an operational 
difficulty is encountered such that a long time is required for, and the 
electrical insulating characteristic of the resultant cell is liable to be 
insufficient. An amount of above 0.35 mol provides difficulties, in 
particular a lowering in moisture resistance. It is particularly preferred 
that the hydrazide is used in such an amount as to provide 0.2-0.25 mol of 
hydrazide group for 1 mol of epoxy group in the epoxy resin. The mixing of 
both compounds may preferably be effected by using a kneading means, such 
as a three-roll mill, capable of uniformly and finely dispersing the 
hydrazide which is generally solid. 
The amine-type room temperature hardener used in the present invention may 
include: aliphatic polyamines, polyamide resins and isocyanate compounds 
which are generally used as a room temperature hardener (activatable at 
20.degree.-30.degree. C.) for epoxy resins. Specific examples thereof may 
include: piperazine, ethylenediamine, diethylenetriamine, and 
triethylenetetramine. It is also possible to suitably use reaction 
products between modified or unmodified aliphatic amines and fatty acids, 
such as dimer acids polyamides. 
The amine-type room temperature hardener is added so as to cause a 
selective reaction with a low-molecular weight fraction (having a 
molecular weight of 500 or less) of the epoxy resin in the sealant in 
advance to increase the molecular weight. Accordingly, it is preferred to 
add the amine-type room temperature hardener in a proportion of 0.2-0.8 
equivalent, further preferably 0.25-0.5 equivalent, per one equivalent of 
the low-molecular weight fraction of epoxy resin in the sealant. 
Further, it is preferred to add the amine-type room temperature hardener in 
a proportion of 1.0-3.0 wt. %, further preferably 1.8-3.0 wt. %, of the 
total of the hardener and the one-pack type thermosetting epoxy resin 
adhesive. A proportion of below 1.0 wt. % is insufficient to prevent the 
sealant flow. A proportion of above 3.0 wt. % results in a pot life which 
is too short for a practical production process. 
The sealant according to the present invention can contain various fillers, 
examples of which may include: 
(1) inorganic fillers inclusive of: carbonates, such as calcium carbonate 
and magnesium carbonate; sulfates, such as barium sulfate and magnesium 
sulfate; silicates, such as aluminum silicate and zirconium silicate; 
oxides, such as iron oxide, titanium oxide, aluminum oxide and zinc oxide; 
potassium titanate, kaolin, talc, asbestos powder, quartz powder, mica, 
and glass fiber; and 
(2) organic fillers inclusive of: polyethylene powder, polypropylene 
powder, polyester powder, polyvinyl chloride powder, polystyrene powder, 
polyvinyl acetate powder, polymethacrylate powder, polyurethane powder, 
polyester powder, urea resin powder, phenolic resin powder, benzoquanamin 
resin powder and epoxy resin powder. 
Generally, the fillers may desirably be used in an amount of 1-100 wt. 
parts per 100 wt. parts of the epoxy resin while the addition amount can 
remarkably vary depending on the sealant composition, particularly the 
kind of the filler per se. 
In general, filler amount of less than 1 wt. part is liable to result in 
difficulties, such as poor application or printing characteristic and poor 
retentivity of the applied pattern. A filler amount of more than 100 wt. 
parts is liable to cause difficulties in application, e.g., by screen 
printing. The mixing of the filler may preferably be effected by using a 
kneading means, such as a three-roll mill, for communication so as to 
prevent clogging of a screen for screen printing, etc. 
In the present invention, the sealant or adhesive may preferably contain a 
solvent, which may desirably have a boiling point of 
70.degree.-250.degree. C. Examples of such a solvent may include: 
hydrocarbons, such as n-heptane,n-octane,n-decane, cyclohexane, benzene, 
toluene, xylene, ethylbenzene, diethylbenzene, amylbenzene, naphthalene 
and pinene; halogenated hydrocarbons, such as carbon tetrachloride, 
ethylene chloride, 1,1,1-trichloroethane, 1,1,1,2-tetrachloroethane, 
hexachloroethane, hexachloroethane, trichloroethylene, 
tetrachloroethylene, 1,2,3-trichloropropane, butyl chloride, amyl 
chloride, 2-ethylhexyl chloride, ethylene bromide, tetrabromoethane, 
chlorobenzene, 1,2,4-trichlorobenzene, and bromobenzene; alcohols, such as 
ethanol, isopropanol, n-amyl alcohol, fusel oil, n-hexanol, methylamyl 
alcohol, 2-ethylbutanol, n-heptanol, n-octanol, n-decanol, cyclohexanol, 
benzyl alcohol and furfuryl alcohol; ethers and acetals, such as n-butyl 
ether, n-hexyl ether, ethyl phenyl ether, 1,4-dioxane, trioxane and 
diethyl acetal; esters, such as propyl formate, isobutyl formate, ethyl 
acetate, n-butyl acetate, benzyl acetate, isoamyl butylate, ethyl lactate, 
methyl benxoate and diethyl oxalate; polyhydric alcohols and derivatives 
thereof, such as ethylene glycol, methyl cellosolve, methyl cellosolve 
acetate, cellosolve acetate, dibutyl cellosolve, methyl carbitol, carbitol 
acetate, butyl carbitol, propylene glycol and hexylene glycol; 
ion-containing solvents, such as dimethyl sulfoxide, and 
nitrogen-containing solvents, such as N,N-dimethylformamide. 
If the solvent has a boiling point of below 70.degree. C., the solvent is 
liable to be evaporated to increase the viscosity of the adhesive 
containing the solvent during the storage or application operation of the 
adhesive, whereby the processability of the adhesive is impaired. A 
solvent having a boiling point of above 250.degree. C. requires a long 
time for the pre-drying step and is liable to remain in the adhesive after 
the application, whereby the performance of the liquid crystal in the cell 
can be impaired or the adhesion performance can be deteriorated thereby. 
Such a solvent is desirably used in the present invention so as to provide 
the adhesive with an appropriate fluidity and an appropriate 
applicability. The amount of the solvent is selected so as to be adopted 
to these purposes and may suitably be in the range of 0-70 wt. parts per 
100 wt. parts of the epoxy resin in general. The solvent may be used 
singly or in mixture of two or more species. 
The above-mentioned components of the sealant including the epoxy resin, 
potential hardener, room temperature hardener, filler, solvent and other 
optional additives can be mixed in an arbitrary order provided that they 
can be sufficiently mixed and the room temperature hardener is added in a 
rather late stage so as to provide an appropriate length of pot life. 
The particulate adhesive 109 to be used in combination with the sealant 
according to the present invention may for example comprise epoxy resin 
particles having an average particle diameter of 0.3-500 microns and 
containing a potential hardener (as disclosed in, e.g., Japanese Laid-Open 
Patent Applications (JP-A) Sho 62-174726 and Sho 62-174284). The potential 
hardener may for example be an addition product between diglycidyl ethers 
of bisphenols or condensation products thereof and polyhydric phenol 
compounds. 
As described hereinbefore, when a conventional sealant is used and the 
heating of a particulate adhesive is performed simultaneously with 
pressure bonding of the sealant, the problem of a sealant flow is 
encountered. This is considered because, when the substrate are entirely 
heated to a softening temperature of the particulate adhesive 
simultaneously with the pressure bonding of the sealant, a relatively 
fluid low-molecular weight portion of the sealant which is also caused to 
assume a lower viscosity as a whole is separated by flowing from the mass 
of the sealant under the application of the pressure and due to a 
preferential decrease in surface tension. In the present invention, 
however, such a low-molecular weight portion of the epoxy resin is 
selectively reacted in advance, i.e., the one-pack type thermosetting 
epoxy adhesive is modified with an amine-type room temperature hardener, 
before use of the adhesive, so that the adhesion is effected without such 
a sealant flow even when the sealant is heated to a softening temperature 
of the particulate adhesive at the time of pressure bonding. 
Hereinafter, the present invention will be explained based on actual 
examples of cell preparation. 
EXAMPLE 1 
A one-pack type thermosetting epoxy adhesive (trade name: STRUCT BOND 
XN-21F, 300 poise (25.degree. C.), mfd. by Mitsui Toatsu Kagaku K.K.) was 
sufficiently mixed with an amine-type room temperature hardener (trade 
name: X-705, mfd. by Mitsui Toatsu Kagaku K.K.) in an amount of 2 wt. % of 
the total of the adhesive and the hardener and the mixture was left 
standing in a sealed state at 20.degree.-25.degree. C. for 100 hours. The 
thus treated mixture sample (sealant) was subjected to measurement of 
molecular weight distribution by GPC (gel permeation chromatography) using 
an apparatus (trade name: Model 150C mfd. by Waters Co.) The GPC chart of 
the sample thus obtained is shown in FIG. 5 along with that of the epoxy 
adhesive before the modification with the amine-type room temperature 
hardener. FIG. 5 clearly shows a selective decrease in amount of the 
low-molecular weight fraction. 
Then, a cell was prepared according to a process as illustrated in FIG. 4. 
More specifically, referring to FIG. 2, on one of a pair of 1.1 mm-thick 
glass substrates 101 already subjected to aligning treatment, a diluted 
adhesive (36 poise at 25.degree. C.) obtained by mixing the above-prepared 
sample adhesive with methyl carbitol as a solvent in a ratio of 6:1 
(sample:solvent) was applied in a prescribed pattern 210 having an average 
width of 1 mm and an average height of 3-5 microns (step 401) so as to 
surround a square display area 211 (having a diagonal size of 15 inches) 
and then subjected to leveling and drying at 90.degree. C. for 5 min. on a 
hot plate (step 402). 
Then, on one side of the one substrate thus treated, spacer beads (trade 
name: Silica Microbeads, mfd. by Shokubai Kasei K.K.) were dispersed at a 
rate of 300.+-.100 beads/mm.sup.2, and on the other substrate, adhesive 
particles (trade name: Torepearl, mfd. by Toray K.K.) were dispersed at a 
rate of 35.+-.5 particles/mm.sup.2. Then, the thus substrates were 
superposed with each other (steps 403-405). 
The superposed structure was pre-heated at 70.degree. C..+-.7.degree. C. 
for 5 min. under a pressure of 560.+-.40 g/cm.sup.2, then supplied with a 
pressure of 2300.+-.40 g/cm.sup.2 for 2 min. (step 406) and then subjected 
to curing under pressure and heating at 630 g/cm.sup.2 and 150.degree. C. 
for more than 30 min. (step 403) to prepare a blank liquid crystal cell, 
whereby the sealant was sufficiently pressure-bonded without causing 
sealant flow to provide a uniform gap in the display area of 1.37.+-.0.05 
micron. 
COMATIVE EXAMPLE 1 
A blank liquid crystal cell was prepared in the same manner as in Example 1 
except that the amine-type hardener was not added whereby a part of the 
sealant caused flowing-out. 
EXAMPLE 2 
A blank liquid crystal cell was prepared in the same manner as in Example 1 
except that the mixture of the epoxy adhesive and the amine-type hardener 
was left standing for 300 hours instead of 100 hours, whereby the sealant 
was sufficiently pressure-bonded without causing sealant flow to provide a 
uniform gap in the display area of 1.37.+-.0.05 micron. 
COMATIVE EXAMPLE 2 
A blank liquid crystal cell was prepared in the same manner as in Example 1 
except that the mixture of the epoxy adhesive and the amine-type hardener 
was left standing for 80 hours instead of 100 hours, whereby a part of the 
sealant caused flowing-out. 
COMATIVE EXAMPLE 3 
A blank liquid crystal cell was prepared in the same manner as in Example 1 
except that the mixture of the epoxy adhesive and the amine-type hardener 
was left standing for 400 hours instead of 100 hours, whereby the sealant 
was not sufficiently deformed to result in an insufficient bonding between 
the substrates. 
EXAMPLE 3 
A blank liquid crystal cell was prepared in the same manner as in Example 1 
except that the mixture of the epoxy adhesive and the amine-type hardener 
was left standing for 90 hours and then diluted with methyl carbitol as a 
solvent in a ratio of 3:1 (=mixture: solvent) to provide a diluted 
adhesive (sealant) having a viscosity of 12 poise at 25.degree. C. The 
cell was prepared without causing sealant flow, and in this case, the 
printing of the sealant was stably and continuously effected at a rate of 
4 or more times as fast as that in Example 1. 
Next, some embodiments are explained for explaining application of a liquid 
crystal cell according to the present invention to a display apparatus and 
a recording apparatus. 
FIG. 6 is a block diagram showing principally an electrical system of a 
display apparatus incorporating a liquid crystal cell according to the 
present invention Signals applied to the scanning electrodes are formed by 
sending a clock signal (CS) generally by a clock signal generator to a 
scanning electrode selector for selecting a scanning electrode and then to 
a scanning electrode driver. On the other hand, signals (DM) for the data 
electrodes are supplied to a data electrode driver through a data 
modulator where data signals and an auxiliary signal are formed from 
output signals (DS) from a data generator and a clock signal (CS). 
FIG. 7 shows an example of such a signal outputted from the data modulator. 
Further, FIG. 8 shows a circuit formation of the data modulator for 
outputting the signal shown in FIG. 7, which includes two inverters 811 
and 812, two AND circuits 813 and 814 and an OR circuit 815. 
A structure similar to the above-described liquid crystal display apparatus 
can be used as a liquid crystal shutter array in an image recording 
apparatus. 
FIG. 9 illustrates an electrophotographic image recording apparatus in 
which such a liquid crystal shutter array is used for modulating and 
controlling light-exposure of a photosensitive member. Referring to FIG. 
9, the image recording apparatus includes an exposure lamp 901 as a light 
source, a liquid crystal shutter array 902, an array of short-focus image 
formation elements 903, a photosensitive drum 904, an electric charger 
905, a developing device 906, a developing sleeve 907, a transfer guide 
908, a transfer charger 909, a cleaning device 910, a cleaning blade 911, 
and a conveyer guide 912. In operation, the photosensitive drum 904 
rotating in the direction of an arrow as shown is charged by means of an 
electric charger 905 and then exposed to modulated light depending on 
image signals to form an electrostatic latent image. Optical modulation 
for producing the modulated light is performed, as shown in FIG. 10, by 
transmitting or interrupting light from the exposure lamp 901 by means of 
the liquid crystal shutter array 902 arranged in parallel with the axis of 
the photosensitive drum 904. In the liquid crystal shutter array, a large 
number of liquid crystal shutter elements (pixels) are arranged in a 
staggered fashion so as to increase the arrangement density of the shutter 
elements. A rod lens 1015 may be used as desired for condensing the light 
from the exposure lamp 901 onto the liquid crystal shutter array 902. 
The thus formed electrostatic latent image is developed by attachment of a 
charged toner on the developing sleeve 907. The toner image thus formed on 
the photosensitive drum 904 is transferred to a transfer paper 913 
supplied from a paper-supplying cassette (not shown) under discharge from 
the backside of the transfer paper 913 by the transfer charger 909, and 
the transferred toner image on the transfer paper 913 is conveyed by the 
conveyer means 912 to a fixing device (not shown) and fixed thereat onto 
the transfer paper 913. On the other hand, a portion of the toner 
remaining on the photosensitive drum 904 without being transferred is 
scraped off the drum surface by the cleaning blade 911 to be recovered in 
the cleaning device 910. The charge remaining on the photosensitive drum 
is extinguished by illumination from a pre-exposure lamp 914. 
As described above, according to the present invention, a one-pack type 
thermosetting epoxy adhesive is used as a sealant for a liquid crystal 
cell after modification with an amine-type room temperature hardener 
preferentially with respect to its low-molecular weight fraction, whereby 
it becomes possible to introduce a particulate adhesive in a display area 
while avoiding a flow of the sealant and also the sealant can be printed 
continuously for an extended time. 
As a result, it becomes possible to stably provide a liquid crystal cell of 
a large area with a uniform and a highly accurate gap. Accordingly, by 
using the liquid crystal cell according to the present invention in a 
display apparatus or a recording apparatus, it is possible to improve the 
quality or function of display or recording and also possible to increase 
the productivity of these apparatus.