NL8005451A - Curing photosensitive resin layers - using a flash discharge lamp having a glass bulb contg. a rare gas - Google Patents

Abstract

Photosensitive resin layers having the main photosensitive peak in the wavelength region not more than 4500 Angstroms are cured to form solid layers of thickness 100 microns or less using a flash discharge lamp with its glass bulb filled with a rare gas as the main component, the emission energy J(oule) generated from the lamp being controlled within the range of J/S=0.02-8, where S(cm.2) is the area to be irradiated. Layers of thickness more than 100 microns are obtd. when the emission energy is controlled within the range of J/Sd=0.002-2, where d (micron) is the thickness of the cured layer. The flash discharge lamp used is a cold light source capable of instantly producing the total designed amt. of light. Applications include photoengraving, printing inks, coating compsns. and adhesives.

Description

u.o. 29505 1

A method for making photosensitive resin layers more durable,

The invention relates to a method of making photosensitive resin layers more durable and more particularly relates to a method of making photosensitive resin layers more sustainable with ultraviolet light generated by a flash discharge lamp.

Hardly more than a decade has passed since attention first focused on photosensitive resins. However, their use has risen markedly as a result of ongoing development efforts, beginning with the initial use of photo-engraving materials, while the scope now also includes printing ink, coating compositions, adhesives and other industrial products.

They are used in the form of sheets, films, patterns and letters and are preserved from the liquid in the solid state by irradiation with ultraviolet light. Chemically, this process involves photopolymerization of low molecular weight materials induced by ultraviolet light, but in some cases also refers to "drying" when it comes to paint and printing ink.

In conventional processes, a mercury discharge lamp, or a mixed metal vapor discharge lamp, a modification of the mercury discharge lamp in which part of the mercury has been replaced by other metals, is used as a source of ultraviolet light. However, these lamps suffer from the following drawbacks: 1) Generally, even the most advanced types take a few tens of seconds to generate the desired amount of light after the lamp has been turned on, even in the most advanced types. This results in poor efficiency.

2) It is known, in order to overcome this difficulty, to place the lamp in a housing 35 provided with a shutter, the preservation of which is effected by opening the shutter intermittently. The complicated structure of this housing, its troublesome handling and unnecessary power consumption are after 80 05 45 1%

* V

2 parts which adhere to the working method.

5) in order to efficiently emit light in the wavelength range effective for photopolymerization, the balloon wall must always be maintained at a high temperature to ensure a high vapor pressure of the metal at all times. As a result, the lamp life is generally short. Because of the large amount of heat produced combined with the longer required irradiation time, a sharper production of images can be physically influenced or influenced by a thermochemical reaction that takes place together with the photochemical reaction, for example when it concerns letters and patterns that are composed are from fine lines.

The object of the invention is now to provide a new method for making photosensitive resin layers more durable, which method does not suffer from the above drawbacks. To this end, the invention provides a method for making photosensitive resin layers more durable with a peak in the photosensitivity in the wavelength range not higher than 4500? to form solid layers using a flash discharge lamp whose glass balloon is filled with a thin gas as the main component controlling the energy density Q of the radiation (in joules / 25 cm ^ .msec) in the range of 0.1 £ Q <450. The energy density Q of the radiation is expressed in the following formula: Q = J / (§ D2Lt) where J: the electrical input energy of the emission 30 (joule) D: internal diameter of the flash discharge lamp (cm) L ·: · flash discharge distance ( cm) * t: pulse width at 1/3 of the peak-peak value of the current waveform 55 P: the circle constant.

Another object of the invention is to provide a method for preserving photosensitive resin layers having a peak photosensitivity in the wavelength range of not more than 450θϋ using a 40 flash discharge lamp whose glass balloon is filled with 80 05 45 1 3 light gas as a main component, the pulse width t (at 1/3 of the peak height) of the flash light generated by the flash discharge lamp is controlled in the range of 0.05 (msec) thth4 (msec).

Briefly stated, the invention is characterized by the use of a flash discharge lamp as a source of ultraviolet light, which flash discharge lamp forms a cold light source capable of directly producing the total desired amount of light, whereby the emitted energy of the relevant flash discharge lamp can become considerable. controlled.

Flash discharge lamps are already used for various industrial applications. However, it has been shown that they can be used successfully as a means of preserving photosensitive resin layers, as evidenced by the invention, although under certain circumstances, which required detailed and extensive investigation.

The invention embodies the result of this research.

Figure 1 schematically shows a device for carrying out the method according to the invention.

Figure 2 schematically illustrates the configuration of a flash discharge lamp used in accordance with the invention and the power supply circuit therefor.

Figure 1 shows a preferred embodiment of the invention in which an ink layer 2 is printed on an acrylic sheet to a thickness of about 20 microns and is preserved using a flash discharge lamp 4 with an adjacent mirror 3. Figure 2 illustrates a preferred configuration of said flash discharge lamp 304 and the associated power supply circuit. The reference numeral 3 'illustrates the support frame for an internal * reflecting surface in order to efficiently direct the flash light to the article to be irradiated with minimum loss, the reference numeral 5 denotes a glass balloon, the reference numeral 6 stands for a metal cap with which the ends of the balloon are hermetically sealed, number 7 is a cathode, number 8 is an anode, L is the discharge distance and D is the internal diameter of the balloon. The power supply circuit for starting the flash discharge lamp 4 includes a high voltage generator 80 05 45 1 * 4 HV which is connected via the charge resistor E, the discharge capacitor 0 and the trigger switch SW, and a pull electrode 9 connected to the aforementioned high-voltage generator HV. If the trigger switch SW is closed for applying a high electrical potential to the flash discharge lamp and for ionizing the gas contained in the balloon, the electric charge accumulated in the discharge capacitor will discharge, causing the lamp to light flash emits.

The ink 2 is an offset printing ink with a photosensitive main peak in the wavelength range of not more than $ 4500, for example, "Toka TJV-Cure BF" (from Toka Shikiso Kagaku Kogyo). This ink can be directly preserved by ultraviolet irradiation of the flash discharge lamp without any detrimental thermal effect. In an example, a layer of figures, symbols, letters and the like was printed with a thickness of about 20 microns and immediately cured to obtain a sufficiently solid layer after irradiation under the following conditions: 20 discharge length D «26 cm, inner diameter of the balloon D = 0.8 cm, pressure of the xenon gas charge »200 mm Hg, energy emitted J = 800 joules (leading to a radiation energy density Q => 20.4), and a flash light pulse width t = 3 msec. A number of flash discharge lamps with 25 different balloon diameters of at least 0.3 cm and with different discharge distances of at least 3 cm were fabricated and their glass balloons filled with xenon or other rarefied gases, or a mixture thereof. Similar experiments as described above were performed using these lamps at different Q values ranging in the range 0.01 to 600. This experiment showed that if Q is less than 0.1, then a portion of the ink layer not preserved. On the other hand, if Q is greater than 450, bubbles are found in the preserved ink layer. The former difficulty can be attributed to the insufficient amount of ultraviolet light in the wavelength range of not more than $ 4500, while the latter difficulty can be attributed to the over-40 moderately large amount of energy generated within a given 80 05 45 1 4-5 time period. is issued. In any case, only satisfactory results can be achieved in the range of 0.1 ^ 450.

In another series of experiments, in which t was varied in the range from 0.01 to 6, it was shown that if t is less than 0.05, part of the ink layer is not preserved, while if t is greater than 4 on the other hand, bubbles are found in the preserved ink layer. The former difficulty is probably due to the unfinished progress of the photo-induced radical polymerization due to the insufficient exposure time; however, in the latter case, on the contrary, it is likely that the polymerization is adversely affected by heat because of the increased amount of heat radiation (7000I or more) combined with the effect of the pulse width. In any case, only satisfactory results can be achieved within the range of 0.05 <t <4.

From the foregoing, it is apparent that the invention relates to a method of preserving photosensitive resin layers to obtain a satisfactory solid film free from the drawbacks that cannot be overcome in conventional methods using a flash discharge lamp as the source of ultraviolet light, which forms a cold light source capable of directly producing the total desired amount of light, whereby the energy radiated by this flash discharge lamp can be properly controlled, which is of great value in practical applications.

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Claims (2)

1. A method of preserving photosensitive resin layers having a photosensitive main peak in the wavelength area of not more than 4500A, characterized by the use of a flash discharge lamp whose glass balloon is filled with a thin gas as the main component, the radiant energy density Q of the light generated by this flash discharge lamp is controlled in the range of 0.1 _ $ _ 450. 10 2. A method for making photosensitive resin layers more durable according to claim 1, characterized in that the pulse width t of the flash light emitted by the flash discharge lamp is controlled in the range of 0.05 (msec) wte4 (msec). ✓You * * Kt He * * * * * * * 1 80 05 45 1