JPS63212585A - Ink jet recording method - Google Patents

Abstract

PURPOSE:To obtain a fresh recording image in which neither satellite dot nor fog is generated by containing liquid solvent and specific weight of recording agent to the liquid solvent in recording solution, and regulating specific heat, thermal expansion coefficient, thermal conductivity and surface tension to specific ranges, respectively. CONSTITUTION:In a recording method for recording by operating thermal energy at recording solution, discharging the solution from an exhaust port to form a flying solution droplet, the solution contains liquid solvent and 1-50pts.wt. of recording agent with respect to 100pts.wt. of the solvent, its specific heat is regulated to 0.1-4.0J/kg, its thermal expansion coefficient is regulated to 0.1X10<-3>-1.8X10<-3>deg<-1>, its thermal conductivity is regulated to 0.1X10<-3>-50X10<-3>W/cm.deg., its viscosity at 20 deg.C is regulated to 0.3-30CPS, and its surface tension is regulated to 10-60dyne/cm. The solution contains the liquid solvent, the recording agent for forming a recording image, and an additive to be added to obtain desired properties, and aqueous, nonaqueous, solubility, conductivity and insulation properties can be obtained by the types and the composition ratio of the solvent and the additive in the range for obtaining the above physical properties.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention relates to an inkjet recording method that uses thermal energy to record by jetting a recording liquid as droplets.

[Conventional technology]

Non-impact recording methods have recently attracted attention because the noise generated during recording is so small that it can be ignored. Among them, high-speed recording is possible,
Moreover, the so-called inkjet recording method, which allows recording on plain paper without the need for special fixing treatment, is an extremely powerful recording method, and various methods have been devised, improved, and commercialized. Some have been developed, and efforts are still being made to put them into practical use.

In this type of inkjet recording method, recording is performed by causing droplets of a recording liquid called ink to fly and adhere to a recording member. There are several types of methods for controlling the flight direction of the generated recording liquid droplets.

Representative examples include: USP3060429 (Teletype method).

USP 3596275 (method S W e e ).

USP3298030 (Lewis/Brown method).

USP3416153 (Hertz method).

USP 3747120 (S t e m m
e method).

USP3683212 (Zoltan method).

It is described in each publication of USP3946398 (Kyser/5ears method).

The recording methods described in these publications separate droplets by applying mechanical vibration to a pressurized liquid flow, or change the volume of a recording liquid chamber filled with recording liquid by mechanical action. Either the recording liquid is ejected from the ejection port to form flying droplets.

Regarding these methods, Japanese Patent Publication No. 54-13783, USP No. 2556550, and Japanese Patent Application Laid-open No. 1320-1982
No. 36 and Japanese Unexamined Patent Publication No. 51-19303 describe inkjet recording methods that utilize thermal energy.

[Problems to be solved by the invention]

However, the method described in Japanese Patent Publication No. 54-13783 is essentially USP3298030, USP35
This method differs from the method described in No. 96275 in that it uses a change in surface tension due to thermal energy of ink (recording liquid) to separate droplets from a pressurized jet.

The method described in USP 2,556,550 is a method of recording by discharging ink from an ejection port by thermal expansion of the ink or the substrate, and is disclosed in Japanese Patent Application Laid-open No. 132036/1983,
and Japanese Patent Application Laid-Open No. 19303/1983, thermal energy is applied locally to ink in an ink reservoir whose top surface is open to form bubbles, and the bubbles float up in the ink to lower the ink liquid level. This is a method of recording by attaching droplets that are generated when the cartridge ruptures to the recording paper. None of these methods uses thermal energy to form bubbles and then ejects ink from the ejection port to form flying droplets (in addition, what kind of recording liquid (ink) is used? Regarding whether materials with such physical properties can be applied to inkjet recording methods that use thermal energy,
There is only a description of water-based ink or water and amino black ink, and nothing else is described.

Furthermore, although USP 3,747,120 lists heating coils as an example of pressure increasing means,
The recording liquid used is only described as ink.

As described above, in the past, there has been no inkjet recording method that uses thermal energy to provide a clear recorded image without the generation of satellite dots or fogging of the recorded image.

Therefore, the present invention has been made in view of the above-mentioned points, and an object of the present invention is to provide an inkjet recording method using novel thermal energy that does not generate satellite dots and provides clear recorded images without fogging. With the goal.

[Means and actions to solve the problem]

According to the present invention, there is provided an inkjet recording method in which recording is performed by applying thermal energy to a recording liquid and ejecting the recording liquid from an ejection port to form flying droplets, the recording liquid being connected to a liquid medium and the liquid. The recording agent is contained in an amount of 1 to 50 parts by weight per 100 parts by weight of the medium, and has a specific heat of 0.1 to 4. OJ/gk1
Thermal expansion coefficient is 0. lX10-3~1.8X10-"
d e g-1, thermal conductivity is o, 1 x to-” ~
50X 1O-3W/cm * deg, viscosity at 20℃ 0.3~30CPS, surface tension lO~
An inkjet recording method is provided, which is characterized in that the inkjet recording method is adjusted to a range of 60 dyne/cm.

First, an overview of the inkjet recording method of the present invention will be explained with reference to FIG.

FIG. 1 is an explanatory diagram for explaining the basic principle of the inkjet recording method of the present invention.

A recording liquid 3 is supplied into the nozzle liquid path 1 to which a pressure P is applied by an appropriate pressurizing means such as a pump to such an extent that it cannot be discharged from the orifice (discharge port) 2 by itself. Now, when the recording liquid 3a in the liquid path l at a distance l from the ejection port 2 is subjected to the action of thermal energy, the width of the liquid path 1 changes depending on the amount of energy applied due to a sudden change in the state of the recording liquid 3a. ! A part or substantially all of the recording liquid 3b present therein is ejected from the ejection port 2, flies as a droplet in the direction of the recording member 4, and adheres to a predetermined position on the recording member 4.

The size of the recording liquid droplet 5 ejected from the ejection port 2 and flying is determined by the amount of thermal energy applied and the width Δl of the portion 3a that is affected by the thermal energy of the recording liquid existing in the liquid path l. Inner diameter d1 of the liquid path 1 Distance from the position of the discharge port 2 to the position where thermal energy is applied 11 Pressure applied to the recording liquid P1 Depends on the specific heat, thermal conductivity, coefficient of thermal expansion, etc. of the recording liquid. Therefore, by changing any one or more of these factors, the size of the droplet 5 can be easily controlled, and the droplet diameter or spot diameter can be set to any desired diameter as desired. It is possible to record on the recording member 4 as follows. In particular, the fact that the distance l can be arbitrarily changed means that the position at which thermal energy is applied during recording can be changed as desired, and therefore the amount of applied thermal energy per unit time does not have to be changed. (In both cases, the size of the recording liquid droplet 5 ejected from the ejection port 2 can be arbitrarily controlled during recording, and a recorded image with gradation can be easily obtained.

The thermal energy applied to the recording liquid 3 in the liquid path 1 may be applied continuously over time, or may be applied in pulses of 0N.
- It may be turned OFF to act discontinuously.

When acting in a pulsed manner, the frequency, amplitude, and pulse width can be easily selected and changed as desired, so the size of the droplet and the number of droplets generated per unit time can be easily changed. The number number can be controlled extremely easily.

When thermal energy is applied to the recording liquid 3 in a temporally discontinuous manner, the applied thermal energy can carry recording information.

In this case, since thermal energy is applied to the recording liquid 3 according to the recording information signal, each droplet 5 ejected and flying from the ejection port 2 carries recording information, and therefore all of them carry recording information. Attach to 4.

When thermal energy is not made to carry recording information and is applied discontinuously to the recording liquid 3, it is preferable to act discontinuously at a certain frequency.

In this case, the frequency depends on the type of recording liquid used within the scope of the present invention and its physical properties, the form of the liquid path, the volume of the recording liquid in the liquid path, the recording liquid supply speed to the liquid path, and the diameter of the ejection port. , is determined as desired in consideration of the recording speed, etc., but is usually 1 to 1000 KHz, preferably 50 to 1000 KHz.
Preferably, the frequency is 500 KHz.

When thermal energy is applied continuously over time,
Droplet size and number of droplets generated per unit time N
o is the amount of thermal energy acting per unit time, liquid path l
The inventors have confirmed that the pressure P1 applied to the recording liquid in the recording liquid mainly depends on the specific heat, coefficient of thermal expansion and thermal conductivity of the recording liquid, and the energy for the droplets to fly out from the discharge port 2. There is. Therefore, among these, by controlling the amount of thermal energy and/or pressure P acting per unit time, the size of the droplets and the number N of droplets can be controlled.

can be controlled.

In the present invention, the thermal energy that acts on the recording liquid 3 is generated by supplying thermal conversion energy to a thermal conversion body. As thermal conversion energy, any energy that can be converted into thermal energy can be used, but
Generally, electrical energy and electromagnetic energy are preferred because of their ease of supply, transmission, control, etc. As electromagnetic wave energy, laser, maser-1
Energy such as infrared rays, ultraviolet rays, visible light, high frequency waves, and electron beams can be mentioned. In particular, laser energy is preferred because of its advantages such as high heat conversion efficiency, easy transmission, supply, and control, and the ability to miniaturize the device.

In the case of employing electrical energy as heat conversion energy in the present invention, the heat converter may be provided in direct contact with the liquid path 1, or a material with high heat conduction efficiency may be interposed between the heat converters. Alternatively, in either case, the thermal energy generated from the heat converter provided in the liquid path 1 is transferred to the recording liquid 3 to act on it.

Furthermore, in the case where this electric energy is employed, at least the portion of the liquid path 1 on which the electric energy acts may itself be constituted by a heat converter.

When electromagnetic wave energy is employed as the heat converter energy, the heat converter may be the recording liquid 3 itself, or may be attached to the liquid path 1.

For example, if the recording liquid 3 contains an electromagnetic wave energy absorbing heating substance, the recording liquid 3 directly absorbs the electromagnetic wave energy and generates heat, causing a state change and causing the recording liquid to flow through the discharge port 2 of the liquid path 1. The droplets can be ejected and fly, and if, for example, an electromagnetic wave energy absorbing heat generating layer is provided on the external surface of the liquid path l, the layer absorbs the electromagnetic wave energy and generates heat, and the generated thermal energy is transferred to the liquid. The liquid is transmitted to the recording liquid 3 via the path-forming member, thereby causing a state change in the recording liquid 3, and the droplets can be ejected and flown out of the liquid path 1.

As the recording member 4 used in the present invention, all those commonly used in the technical field of the present invention are effective.

Examples of such recording materials include paper, plastic sheets, metal sheets, and laminated sheets of these materials, but paper is preferred due to medium recording performance, cost, handling, etc. It is considered suitable. Examples of such paper include plain paper, high-quality paper, lightweight coated paper, coated paper, art paper, and the like.

The recording liquid used in the present invention has materials selected and composition ratios adjusted so as to have the above-mentioned thermophysical property values and other physical property values, and in addition, the recording liquid used in the conventional recording method is different from the recording liquid used in conventional recording methods. In addition to being chemically and physically stable, it also has excellent responsiveness, fidelity, and thread-forming ability, does not harden in the liquid path, especially at the ejection port, and can be moved in the liquid path according to the recording speed. The recording material must be able to be distributed at a high speed, be fixed on the recording material quickly after recording, have sufficient recording density, and have a good shelf life.
The physical property values are adjusted to provide the following characteristics.

The recording liquid used in the present invention is composed of a liquid medium, a recording agent that forms a recorded image, and additives added to obtain desired characteristics. By selecting the type and composition ratio, it is possible to obtain any of aqueous, non-aqueous, soluble, conductive, and insulating properties.

The liquid medium used in the present invention can be broadly classified into aqueous media and non-aqueous media, but the liquid medium used may have the above-mentioned physical properties such that the recording liquid prepared has other properties. It is selected from the following in consideration of the combination with the selected constituent components.

In the present invention, examples of such non-aqueous media include methyl alcohol, ethyl alcohol, n-propyl alcohol, isopropyl alcohol, n-butyl alcohol, 5eC-butyl alcohol, tert-butyl alcohol, isobutyl alcohol, and pentyl alcohol. , C1-10 alkyl alcohols such as hexyl alcohol, heptyl alcohol, octyl alcohol, nonyl alcohol, decyl alcohol; for example, hexane, octane, cyclopentane, benzene, toluene,
Hydrocarbon solvents such as Kijirol; for example, carbon tetrachloride,
Halogenated hydrocarbon solvents such as trichloroethylene, tetrachloroethane, and dichlorobenzene; Ether solvents such as ethyl ether, butyl ether, ethylene glycol diethyl ether, and ethylene glycol monoethyl ether; For example, acetone, methyl ethyl ketone, methyl propyl ketone, and methyl Ketone solvents such as amyl ketone and cyclohexanone; ester solvents such as ethyl formate, methyl acetate, propyl acetate, phenyl acetate, and ethylene glycol monoethyl ether acetate; alcohol solvents such as diacetone alcohol; petroleum hydrocarbon solvents, etc. can be mentioned.

These liquid media listed above are appropriately selected and used so as to satisfy the affinity with the recording agent and additives used and the above-mentioned properties as a recording liquid. Two or more types may be mixed and used as appropriate within the range in which a recording liquid having the characteristics can be prepared. Further, within the above conditions, these non-aqueous media and water may be mixed and used.

Among the above-mentioned liquid media, water or water/alcohol-based liquid media are preferred in consideration of pollution, ease of availability, ease of preparation, and the like.

In addition to ensuring that the recording liquid to be prepared has the above-mentioned physical properties, the recording agent is also used to prevent sedimentation and agglomeration in liquid channels and recording liquid supply tanks due to long-term storage, as well as transport pipes and liquid channels. It is necessary to select and use materials in relation to the liquid medium and additives so as not to cause clogging.

From this point of view, in the present invention, it is preferable to use a recording agent that is soluble in a liquid medium, but even a recording agent that is dispersible or poorly soluble in a liquid medium may be dispersed in the liquid medium. It can be used if the particle size of the recording agent is made sufficiently small.

The recording agent that can be used in the present invention is appropriately selected depending on the recording member so as to fully suit the recording conditions thereof.

Dyes that can be effectively used in the present invention are those that can satisfy the above-mentioned characteristics of the prepared recording liquid, and examples of dyes that are preferably used include direct dyes as water-soluble dyes, Basic dyes, acid dyes, soluble vat dyes, acidic mordant dyes, mordant dyes, sulfur dyes as water-insoluble dyes, vat dyes, alcoholic dyes, oil-soluble dyes, disperse dyes, etc., as well as thren dyes. , naphthol dye, reactive dye, chromium dye, 1
: type 2 complex salt dye, l: type l complex dye, azoic dye,
It is selected from cationic dyes and the like.

Specifically, for example, Resolin Lil Blue PRL, Resolin Yellow PGG, and Resolin Pink PRR.

Resolin Green PB (manufactured by Bayer), Sumikalon Blue 5-BG, Sumikalon Red E-EBL.

Sumikalon Yellow E-4GL, Sumikalon Brilliant Blue 5-BL (manufactured by Sumitomo Chemical), Diamondx Yellow BG-SE, Diamondx Red BN-8
E (manufactured by Mitsubishi Kasei), Kayalon Polyester Light Flavin 4GL, Kayalon Polyester Blue 3R-SF
, Kayaron Polyester Yellow YL-3E1 Kaya Set Turquoise Blue 776, Kaya Set Yellow 902,
Kayaset Red 026, Prozionlet H-2B,
Prodione Blue H-3R (manufactured by Nippon Kayaku), Revafix Golden Yellow PR, and Revafix Sprill Red P-B.

Revafix Grill Orange P-GR (manufactured by Buyer), Sumifix Yellow GR3, Sumifix Red B1 Sumifix Pril Red BS, Sumifix Pril Blue RB, Direct Black 40 (manufactured by Sumitomo Chemical), Diamond Mirror Brown 3G, Diamond Mirror Yellow G1 Diamond Mirror Blue 3R, Diamirror Prill Blue B1 Diamond Mirror Prill Red BB (manufactured by Mitsubishi Kasei), Remazol Red B Lumazol Blue
3R, Remazol Yellow GNL, Remazol Prill Green 6B (manufactured by Hoechst), Cibacron Prill Yellow, Cibaclon Prill Red 4GE (manufactured by Ciba Geigy), Indico, Direct Deep Black E
m Ex, Diamine Black BH, Congo Red, Serious Black, Orange ■, Amido Black 10
B1 Orange RO, Metaneil Yellow, Pictoria Scarlet, Nigrosine, Diamond Black PBB
(manufactured by Egame), Diacit Blue 3G, Diacito Fast Green GW.

Diacite Milling Navy Blue R1 Indanthrene (manufactured by Mitsubishi Kasei), Zapon Dye (manufactured by BASF)
, Orazole dye (manufactured by CIBA), Lanasin dye (manufactured by Mitsubishi Kasei), Guacrylic Orange RL-E.

Among Guacrylic Brilliant Blue 2B-E1 Diacrylic Turquoise Blue BG-E (manufactured by Mitsubishi Kasei), those which provide the recording liquid with the above-mentioned physical properties can be preferably used.

These dyes are appropriately selected as desired and used after being dissolved or dispersed in the liquid medium used.

As pigments that can be effectively used in the present invention, many inorganic pigments and organic pigments are used, and in particular, when infrared rays are used as heat conversion energy, pigments with high infrared absorption efficiency are used. is preferably used. Specific examples of such pigments include inorganic pigments such as cadmium sulfide, sulfur, selenium, zinc sulfide, cadmium sulfoselenide, yellow lead, zinc chromate, molybdenum red, and Guinea.
Green, titanium white, zinc white, petal, chromium oxide green, red lead, cobalt oxide, barium titanate, titanium yellow, iron black, navy blue, litharge, cadmium red, sulfide chain, lead sulfate, barium sulfate, ultramarine, carbonic acid Calcium, magnesium carbonate, lead white, cobalt violet,
Examples include cobalt blue, emerald green, and carbon black.

Many of the organic pigments are classified as dyes and overlap with dyes in many cases, but specifically, the following are preferably used in the present invention.

a) Insoluble azo type (naphthol type) Brilliant Carmine BS, Lake Carmine FB.

Brilliant Fast Scarlet, Lake Red 4R
, Para Red, Permanent Red R1 Fast Red FGR, Lake Bordeaux 5B, Vermilion No. 1.
Vermilion No. 2, Toluidine Maroon b) Insoluble azo type (anilide type) Diazo Yellow, Fast Yellow 61 Fast Yellow 10G1 Diazo Orange, Parcan Range, Pyrazolone Red C) Soluble Azo type Lake Orange, Brilliant Carmine 3B.

Brilliant Carmino 6B, Brilliant Scarlet G Blue-Killed C Blue-Killed D Blue-Killed R1 Watching Red, Lake Bordeaux 10B, Bonmaroon L, Volmaroon Md) Phthalocyanine-based Phthalocyanine Green Phthalocyanine Green, e) Dyeing Lake-based Yellow Lake, Eosin Lake, Rose Lake, Violet Lake, Blue Lake, Green Lake, Sepia Lake f) Mordant system Alizarin Lake, Madder Carmine g) Vat dye system Industhrene system, Fast Blue Lake (GGS) h)
Basic dye lake system: rhodamine lake, malachite green lake i) Acidic dye lake system: fast sky blue, quinoline yellow lake, quinacridone system, dioxazine system In the present invention, the quantitative relationship between the above-mentioned liquid and the recording agent is as follows: In addition to being prepared so that the recording liquid has the above-mentioned physical property values, conditions such as clogging of the wave path, drying of the recording liquid within the liquid path, bleeding when applied to the recording member, and drying speed, etc.
The recording agent is usually 1 to 50 parts by weight per 100 parts of the liquid medium.
parts, preferably 3 to 30 parts, optimally 5 to 10 parts.

When the recording liquid is a dispersion system (a system in which the recording agent is dispersed in a liquid medium), the particle size of the dispersed recording agent depends on the type of recording agent, the recording conditions, the inner diameter of the wave path, the diameter of the ejection opening, and the diameter of the recording member. It is determined as desired depending on the type, etc., but if the particle size is too large, sedimentation of recording agent particles may occur during storage, resulting in uneven density or clogging of wave channels. This is undesirable because it may cause density unevenness in the recorded image.

Taking these matters into consideration, in the present invention, the particle size of the recording agent used as a dispersion recording liquid is usually 0. O1～
30μ, preferably 0.01-20μ, optimally 0. O1
It is desirable that the thickness be ˜8μ. Furthermore, it is preferable that the particle size distribution of the dispersed recording agent be as narrow as possible, and it is usually D±3μ, preferably D±1.5μ (where D is the average particle size). ).

Examples of additives used in the present invention include viscosity modifiers, surface tension modifiers, pH modifiers, resistivity modifiers, wetting agents, infrared absorbing exothermic agents, and the like.

In addition to obtaining the above-mentioned physical property values, the viscosity modifier and surface tension modifier must also be able to flow through the liquid path at a sufficient flow rate depending on the recording speed, and to prevent the recording liquid from flowing at the discharge port of the liquid path. It is added to prevent wraparound and prevent bleeding (spreading of spot diameter) when applied to a recording member.

The viscosity modifier and surface tension modifier are selected from commonly known agents as long as they are effective and do not adversely affect the liquid medium and recording material used, so as to satisfy the desired properties. used.

Specifically, viscosity modifiers include polyvinyl alcohol, hydroxypropyl cellulose, carboxymethyl cellulose, hydroxyethyl cellulose, methyl cellulose, water-soluble acrylic resin, polyvinyl pyrrolidone,
Gum arabic starch and the like can be exemplified as suitable examples.

In the present invention, surface tension modifiers that are appropriately selected and suitably used as desired include anionic, cationic, and nonionic surfactants. Specifically, as anionic surfactants, polyethylene Glycol ether sulfuric acid, ester salts, etc.; cationic compounds such as poly2-vinylpyridine derivatives, poly4-vinylpyridine derivatives; nonionic compounds such as polyoxyethylene alkyl ether, polyoxyethylene alkyl phenyl ether, polyoxyethylene alkyl ester, polyoxy Examples include ethylene sorbitan monoalkyl ester and polyoxyethylene alkylamine. In addition to these surfactants, there are also amino acids such as jetanolamine, propatoolamine, and morpholinic acid, basic substances such as ammonium hydroxide and sodium hydroxide, and substituted pyrrolidones such as N-methyl-2-pyrrolidone. Used effectively.

These surface tension modifiers do not adversely affect each other or other constituents, and provide the above-mentioned physical properties to the recording liquid being formulated, so that a recording liquid having a desired value of surface tension is formulated. If necessary, two or more types may be used in combination within the range specified above.

The amount of these surface tension modifiers to be added is determined as appropriate depending on the type, other constituent components of the recording liquid to be prepared, and desired recording characteristics. Usually 0.0001 to 0.1 parts by weight, preferably 0.0001 to 0.1 parts by weight.
It is desirable that the amount is 0.001-0.01 parts by weight.

The pH adjuster is used to maintain a predetermined pH value in order to maintain the chemical stability of the prepared recording liquid, for example, to prevent changes in physical properties due to long-term storage and to prevent sedimentation and aggregation of the recording agent and other components. It is added at the right time and in an appropriate amount within a range that does not deviate from the physical property values.

The pH adjuster preferably used in the present invention includes:
Almost any pH can be used as long as it can control the pH value to a desired level without adversely affecting the recording liquid being prepared.

Specific examples of such pH adjusters include lower alkanolamines, monovalent hydroxides such as alkali metal hydroxides, and ammonium hydroxide.

These pH adjusters are added in a necessary amount so that the recording liquid to be prepared has a desired pH value within a range that does not deviate from the above-mentioned physical property values.

When recording by charging recording liquid droplets, the specific resistance of the recording liquid acts as an important factor on its charging characteristics.

That is, in order to charge the recording liquid droplets so that good recording can be performed, the recording liquid must be prepared so that the specific resistance value is usually 10 -3 to 1 ollΩcm.

Therefore, in order to obtain a recording liquid having such a specific resistance value, the specific resistance adjusting agent that is added in the required amount as desired is as follows:
Specific examples include inorganic salts such as ammonium chloride, sodium chloride, and potassium chloride, water-soluble amines such as triethanolamine, and quaternary ammonium salts.

In the case of recording in which the recording liquid droplets do not need to be charged, the specific resistance value of the recording liquid may be arbitrary.

The lubricant used in the present invention is one that is more effective than those commonly known in the technical field related to the present invention, provided that the recording liquid to be prepared does not deviate from the above-mentioned physical properties. In particular, thermally stable ones are preferably used. Specific examples of such lubricants include polyalkylene glycols such as polyethylene glycol and polypropylene glycol; Alkylene glycols containing; lower alkyl ethers of diethylene glycol such as ethylene glycol methyl ether, diethylene glycol methyl ether, and diethylene glycol ethyl ether; glycerin; lower alkoxy triglycols such as methoxy triglycol and ethoxy triglycol; N-vinyl-2 -pyrrolidone oligomer; and the like.

These wetting agents are added in the required amount as desired to satisfy the desired characteristics of the recording liquid, but the amount added is usually 0.1% based on the total weight of the recording liquid. -1
Desirably, the content is 0 wt%, preferably 0.1-8 wt%, optimally 0.2-7 wt%.

In addition to being used alone, the above lubricants may be used in combination of two or more types provided that they do not adversely affect each other.

The recording liquid used in the present invention is added with necessary amounts of the above-mentioned additives as desired, and the recording liquid has excellent formation properties and film strength when attached to a recording member. For example, resin polymers such as alkyd resins, acrylic resins, acrylamide resins, polyvinyl alcohol, polyvinylpyrrolidone, etc. may be added in order to obtain the same.

In the present invention, when electromagnetic wave energy, particularly infrared rays, is used, it is desirable to add an infrared absorbing exothermic agent to the recording liquid in order to make the action of the energy more effective. As the infrared absorbing exothermic agent, many of them are included in the above-mentioned recording materials, but dyes and pigments with particularly high infrared absorbance are mentioned as suitable ones. Inorganic pigments such as carbon black, ultramarine, cadmium yellow, red iron, chrome yellow, and azo, triphenylmethane, quinoline, anthraquinone, and phthalocyanine pigments include alcohol-soluble nigrosine that can be made water-soluble. Preferred examples include organic pigments such as pigments and the like.

In the present invention, when the infrared absorbing exothermic agent is added separately from the recording agent, the amount of the infrared absorbing exothermic agent added is usually 0.01 to 10 wt%, preferably 0.1 to 5 wt%, based on the total weight of the recording liquid. %
It is desirable that this is done.

In particular, if it is insoluble in the liquid medium used, depending on the particle size when dispersing it, there is a risk of sedimentation, aggregation, and nozzle clogging during storage or retention of the recording liquid. It is desirable to use the minimum amount within the range that shows the effect. The recording liquid used in the present invention has specific heat, coefficient of thermal expansion, thermal conductivity, viscosity, surface tension, pH, and charged recording liquid droplets in order to have the various recording properties described above. In the case of recording with specific resistance, the composition is adjusted so that characteristic values such as specific resistance fall within a specific condition range.

In other words, these physical properties have important relationships with the stability of the stringing phenomenon, responsiveness and fidelity to thermal energy action, image density, chemical stability, fluidity in the liquid path, etc. Therefore, in the present invention, it is necessary to pay sufficient attention to these matters when preparing the recording liquid.

The above-mentioned physical properties of the recording liquid that can be effectively used in the present invention are preferably as shown in Table 1 below. It is not necessary to satisfy the numerical conditions as shown, and it is sufficient that some of these physical properties take values that satisfy the conditions in Table 1, depending on the required recording characteristics. Regarding specific heat, coefficient of thermal expansion, thermal conductivity, viscosity, and surface tension,
The values in the table need to be specified. Of course, it goes without saying that the more of the above-mentioned physical properties of the prepared recording liquid that satisfy the values shown in Table 1, the better the recording will be.

.tau.-4" Table 1 *Conditions when recording medium droplets are charged and used Example 1 Image recording was carried out using the apparatus schematically shown in FIG. In FIG. 2, the nozzle 99 is installed at its tip in contact with the heat generating part of the electrothermal converter 100, and at one end there is a pump for supplying recording liquid into the nozzle 99. 101 are connected. 102 is a pipe for transporting the recording liquid from a recording liquid storage tank (not shown) to the pump 101. Electrothermal converter 10
0, in order to vary the position where thermal energy is applied to the nozzle 99, six heating elements (not visible in the drawing at the bottom of the nozzle 99) are independently attached in the direction of the central axis of the nozzle 99. A selective electrode 103 (A1. A2
．． A3°A41 A51 A6) and the common electrode 104 are connected.

Reference numeral 105 is a rotatable drum on which the recording member is attached and rotated, and the scanning speed of the nozzle 99 and its rotation speed can be appropriately timed.

When recording images, the recording liquid used was the product name Bl.
ack17-1000 (A, B, manufactured by Dick Co.), and the recording liquid had the above-mentioned physical properties. The recording conditions are shown in Table 2.

Table 3 shows the spot diameters on the recording liquid on the recording member obtained when image recording was performed by driving each heating element of the electrothermal transducer 100. From the results shown in Table 3, it was found that by changing the position where the thermal energy of the nozzle 99 is applied, the spot diameter of the recording liquid formed on the recording member can be changed.

Next, the electrothermal converter 100 is driven so that a signal corresponding to the input signal of one of the six heating elements is inputted to a predetermined heating element according to the input level of the recording information signal. When an image was recorded, an image with extremely excellent gradation and clear image quality was obtained.

Table 2 Table 3 Example 2 When an image was recorded using the printer shown schematically in FIG. 3, a clear image was obtained.

In FIG. 3, 106 is a recording head, which includes a nozzle 108 having an ejection opening (orifice) for ejecting recording liquid, and an electrothermal converter 107 provided surrounding a part of the nozzle 108. It is made up of. Recording head 10
6 is connected by a pipe joint 109 to a pump 110 for supplying recording liquid to the nozzle 108, and the recording liquid is transported to the pump 110 from the direction of the arrow in the figure.

Reference numeral 111 denotes a charging electrode for charging recording liquid droplets ejected from the ejection opening of the nozzle 108 according to a recording information signal, and 112a and 112b deflect the flying direction of the charged recording liquid droplets. It is a deflection electrode. 113 is a gutter for collecting recording liquid droplets unnecessary for recording; 11
4 is a recording member.

The recording liquid used for image recording was Ca5io.
C.

This was an ink for J and P, and the recording liquid had the above-mentioned physical properties. The recording conditions are shown in Table 4.

Table 4 Example 3 The apparatus used in this example will be explained with reference to FIG.

FIG. 4 is a schematic perspective view for explaining the configuration of the device used in this example. In the figure, a laser beam emitted by a laser oscillator 115 is guided to an entrance aperture of an acousto-optic modulator 116. In the modulator 116, the laser beam is modulated in intensity according to the recording information signal input to the modulator 116. The optical path of the modulated laser beam is refracted toward the beam expander 118 by the reflected light 117 and enters the beam expander 118 . The beam diameter of the modulated laser beam is expanded by the beam expander 118 while it remains a parallel beam. Next, the laser beam whose beam diameter has been expanded is incident on the polygon 119. polygon 119
is attached to the rotating shaft of the hysteresis synchronous motor 120 and rotates at a constant speed. The laser beam swept horizontally by the polygon 119 is f-
A nozzle array 124 is aligned with the tip of the multi-nozzle recording head 123 via a reflecting mirror 122 by a θ lens.
The image is focused on a predetermined position of each nozzle. Due to the image formation of the laser beam on the nozzle array 124, the recording liquid in each nozzle is affected by thermal energy, and small droplets of the recording liquid are ejected from the nozzle ejection ports and recorded on the recording member 125. . Recording liquid is supplied to each nozzle of the recording head 123 via a transport pipe 126. The recording head 123 used in this example has a nozzle array with a total length of 20 cm.

The number of nozzles was 4/mm, and the diameter of the ejection opening was 40μ.

Other recording conditions are shown in Table 5, and the recording liquid used is shown below.

Table 5 Recording liquid: Alcohol-soluble nigrosine dye (manufactured by Orient Chemical Co., Ltd., 5pir) to 4 parts by weight of ethylene glycol
It Black SB) 1 part by weight was added and mixed and dissolved. 60 parts by weight of this solution was poured into 94 parts by weight of water containing O, 1w% dioxin (trade name) and thoroughly stirred. The solution thus obtained was filtered twice using a Millipore filter with an average pore size of lOμ to obtain an aqueous recording liquid. The recording liquid was prepared to have the various physical properties described above.

Example 4 In this example, image recording was performed using a multi-nozzle recording head 127 schematically shown in a partial perspective view in FIG.

To explain with reference to FIG. 5, the recording head 127 has a large number of nozzles 128 having discharge ports (orifices) for discharging recording liquid arranged in parallel, and a nozzle holding member 129.
．． 130. 131. The nozzle array 133 is formed by being held by a nozzle 132, and a common recording liquid supply chamber 134 is connected to each nozzle. Recording liquid supply chamber 1
34 is supplied with recording liquid from the direction of the arrow in the figure through a transport pipe 135.

Now, FIG. 6 shows a partial cross-sectional view taken along the dotted line x'-y' in FIG.

An electrothermal converter 136 is attached to the surface of the nozzle 128 independently for each nozzle.

The electrothermal converter 136 has a heating element 1 on the surface of the nozzle 128.
37, electrodes 138 at both ends of the heating element 137. 139,
Common lead electrode 1 common between each nozzle from electrode 138
40, it is composed of a lead electrode 141 selected from the electrode 139 and an oxidation-resistant film 142.

143, 144 are electrically insulating sheets, 145.146
．． 147. .

148 is a rubber cushion for preventing mechanical destruction of the nozzle 128.

Now, when a signal corresponding to recording information is input to the electrothermal converter 136, the heating element 137 generates heat, and the state of the recording liquid 149 in the nozzle 128 changes due to the action of the thermal energy, causing the nozzle 128 to change its state. A small drop of recording liquid from the orifice 15
0 is ejected and adheres to the recording member 151, and recording is performed.

Table 6 shows the recording conditions in this example. The recorded images obtained in this example were also extremely clear and of good image quality. Moreover, the average spot diameter of the recorded image was about 60 μm.

Table 6 Examples 5 to 9 Images were recorded using the recording apparatus shown in FIG. When recording was performed, recorded images of extremely excellent quality were obtained on plain paper in all cases.

[Brief explanation of the drawing]

FIG. 1 is a schematic explanatory diagram for explaining the outline of the inkjet recording method of the present invention; FIGS. 2 to 4 are schematic perspective views showing the configuration of the recording apparatus used in this embodiment; Figure 5 is a partial perspective view showing the configuration of the recording head of the recording apparatus used in this embodiment, and Figure 6 is the x' in Figure 5.
It is a y' cross-sectional view.

Claims (4)

[Claims] (1) An inkjet recording method in which recording is performed by applying thermal energy to a recording liquid and ejecting the recording liquid from an ejection port to form flying droplets, the recording liquid being a liquid medium and a liquid medium. Contains 1 to 50 parts by weight of recording agent per 100 parts by weight, has a specific heat of 0.1 to 4.0 J/gk, and has a coefficient of thermal expansion of 0.1 x 10^-^3 to 1.8 x 10. ^-^3
deg^-^1, thermal conductivity is 0.1 x 10^-^3~5
0x10^-^3w/cm・deg, viscosity at 20℃ 0.3~30cps, surface tension 10~60dyn
An inkjet recording method characterized in that the inkjet recording method is adjusted to a range of e/cm. (2) The inkjet recording method according to claim 1, wherein the recording agent is a dye. (3) The inkjet recording method according to claim 1, wherein the recording agent is a pigment. (4) The inkjet recording method according to claim 1, wherein thermal energy is applied in pulses to the recording liquid.