KR100880702B1 - Apparatus for irradiating ultraviolet ray - Google Patents

Abstract

An object of the present invention is to make it possible to individually set conditions of ultraviolet rays irradiated from a plurality of head portions.

The ultraviolet irradiating apparatus includes a plurality of head portions 120 and a controller portion 10 having at least one semiconductor element capable of irradiating ultraviolet rays as an ultraviolet light source. The controller unit can switch between the storage unit 116 for storing the plurality of ultraviolet irradiation conditions set in the setting unit 140, the setting mode for setting the ultraviolet irradiation conditions, and the irradiation mode for irradiating ultraviolet rays to the operation panel 144. In the irradiation mode, a control unit 114 for calling the ultraviolet irradiation condition setting stored in the storage unit 116 and controlling the semiconductor element of the head unit 120 in accordance with the ultraviolet irradiation condition setting is provided. The irradiation mode further includes a collective irradiation mode for irradiating ultraviolet rays from all the head portions 120 and an individual irradiation mode for irradiating ultraviolet rays from the specific head portion 120.

Description

Ultraviolet irradiation device {APPARATUS FOR IRRADIATING ULTRAVIOLET RAY}

1 is a block diagram of an ultraviolet irradiation device according to Embodiment 1 of the present invention.

2 is a front view and a cross-sectional view showing a head portion of the ultraviolet irradiation device according to Embodiment 1 of the present invention.

3 is an exploded perspective view of the head of the ultraviolet irradiation device according to Embodiment 1 as viewed from above.

4 is an exploded perspective view of the head portion of the ultraviolet irradiation device according to Embodiment 1 as viewed from below.

FIG. 5 is a perspective view illustrating a state in which the connectors of FIG. 4 are respectively connected. FIG.

FIG. 6 is a view illustrating a state in which UVLEDs are tightly fixed to a front end surface of a cooling block. FIG.

7 is an exploded view showing an example of a lens holder and its internal structure;

8 illustrates an example of a method of fixing a cooling block and a lens holder.

9 is a front view illustrating an example layout of a display unit and a setting unit provided on the front panel of the controller unit;

10 is a flowchart illustrating a method for setting ultraviolet irradiation conditions according to Embodiment 1 of the present invention.

11 is a graph showing a state in which an irradiation pattern of ultraviolet rays is changed to a step type.

12 is a flowchart showing in detail a method of setting ultraviolet irradiation conditions in FIG. 10;

Fig. 13 is a state transition diagram showing an example of the hierarchical menu used for the ultraviolet irradiation device.

14 is a state transition diagram showing an example of the hierarchical menu in the irradiation mode.

Fig. 15 is a state transition diagram showing an example of the hierarchical menu in the setting mode.

Fig. 16 is a state transition diagram showing details of a setting editing menu in the setting mode.

17 is a front view of a controller unit of the ultraviolet irradiation device according to Embodiment 2 of the present invention.

18 is a front view and a sectional view of the head of the ultraviolet irradiation device according to Embodiment 3 of the present invention.

19 is an exploded perspective view showing the head of FIG. 18;

20 is a plan view and a side sectional view of a head of the ultraviolet irradiation device according to Embodiment 4 of the present invention.

21 is a perspective view of the head of FIG. 20;

The perspective view which shows the example of the support method of the head part in Embodiments 1-3 of Embodiment of this invention.

The bottom view which shows the head part of the ultraviolet irradiation device which concerns on Embodiment 5 of this invention.

24 is a flowchart illustrating a method for setting ultraviolet irradiation conditions in the ultraviolet irradiation device according to Embodiment 5 of the present invention.

Fig. 25 is a graph showing an irradiation pattern of ultraviolet rays made into a functional type in the method for setting ultraviolet irradiation conditions according to the sixth embodiment of the present invention.

Fig. 26 is a flowchart showing a procedure for setting ultraviolet irradiation conditions according to Embodiment 6 of the present invention.

27 is a block diagram of an ultraviolet irradiation device according to Embodiment 7 of the present invention.

Fig. 28 is a circuit diagram showing an example of a circuit for realizing a disconnection detection function.

29 is a state transition diagram showing an example of a hierarchical menu for copying setting of ultraviolet irradiation conditions.

<Explanation of symbols for main parts of drawing>

100, 700: ultraviolet irradiation device 110, 210, 710: controller

112: power supply unit 114, 714: control unit

116: memory 120, 320, 420, 520: head

120l: pole member 1202, 4202: holder

1203, 1229, 1230, 1241, 1242, 1230: set screw

122, 422: head body portion 1221: upper case member

1222: lower case member 1223: base member

1224: board 1225: cable connector                 

1226: indicator LED 1227: memory

1228: regulating circuit 1231, 1244: connecting connector

1232: through hole 124, 424: cooling block

1243: proximal end protrusion 1245: protective plate

126, 426: lens holder 1261A, 1261B: first lens

1262: spacer 1263: lens fixing cap

130: cable portion 140: setting portion

142: display unit 144, 244: operation panel

144A, 144B, 144C, 144D: <,>, ∧, ∨ switch

144E: Escape Switch 144F: Enter Switch

145: channel display lamp 146: ultraviolet irradiation lamp

147: power switch 148: batch irradiation switch

150, 350, 450, 550, 550A, 550B, 550C, 650: UVLED

160: head connection connector 170: individual irradiation lamp

180, 380: Individual irradiation switch 290, 390: Individual setting switch

292: individual display unit 7101: external connection device

292: driving circuit 619: exclusive OR circuit

H: target Tr: transistor

R: load resistance

This invention relates to the ultraviolet irradiation device which irradiates the ultraviolet-ray which hardens ultraviolet curable resin used for the attachment of an accessory component, etc., the setting method of ultraviolet irradiation conditions, and an ultraviolet irradiation method.

Previously, UV curable resins in fields such as sterilization, treatment, spectroscopic (luminescence) diagnosis by observation of ultraviolet rays inside and outside the living body in the medical field, observation of minerals and cores, or assembly of electronic parts. The ultraviolet irradiation device was used for the purpose of hardening | curing. Among them, an ultraviolet irradiation device for curing an ultraviolet curable resin is used for the purpose of irradiating ultraviolet rays to an ultraviolet curable resin, which is widely used in the formation of a resist coating or in the printing field, and in the field of adhesion fixing of accessory parts in an assembly process such as an optical pickup. do. This type of ultraviolet irradiation device is provided with a controller which is a device body incorporating a power supply circuit, a head for irradiating ultraviolet rays, and a cable connecting them. A high-pressure mercury lamp or mercury xenon lamp, which is an ultraviolet light source, is embedded in the controller, and the ultraviolet rays are transmitted to the head by an optical fiber such as quartz glass embedded in a cable connecting the controller and the head. Patent Document 1 describes a conventional example of a method for fixing and fixing a accessory part using such an ultraviolet irradiation device. Moreover, there exists also the ultraviolet irradiation apparatus which can connect a some head to the same controller, and can irradiate an ultraviolet-ray from a several place.                         

However, this ultraviolet irradiation device has a problem in that the irradiation conditions of ultraviolet rays cannot be changed for each head because the ultraviolet irradiation device has a structure in which many light paths are diverted from the same ultraviolet source to transmit ultraviolet rays to each head. In particular, since a plurality of heads can be irradiated only at the same output and irradiation timing, work cannot be performed with different settings for each head, and a work utilizing a plurality of heads cannot be performed. If the user can set the individual output, irradiation timing, etc. for each head according to the use conditions, the usability can be remarkably improved, but in the conventional ultraviolet irradiation device, the ultraviolet rays are transmitted using the same ultraviolet source. For this reason, it was physically impossible to set other conditions such as ultraviolet output or irradiation time. For example, the irradiation timing of ultraviolet rays cannot be interlocked between a plurality of heads, and irradiation starts and ends at the same timing with all heads. In addition, even if the head does not need to be irradiated, it is irradiated together when the other head is irradiated simply by connecting to the controller. For this reason, in order to obtain the ultraviolet-ray of other irradiation conditions, the ultraviolet irradiation device must be prepared as many as the number of conditions, and it was very inconvenient.

In addition, since the conventional ultraviolet irradiation device uses a high-pressure mercury lamp or a mercury xenon lamp as an ultraviolet light source, it generates a large amount of heat and power, and requires a cooling mechanism. There is a drawback that the energy consumption is large and the lamp life is shortened. Moreover, since the adjustment of the ultraviolet output is a structure performed by a mechanical shutter, fine adjustment is difficult. In addition, when the lamp deteriorates, the glass may be cracked, and the high-pressure gas sealed inside the glass tube may cause the glass tube to rupture. Therefore, the lamp that has elapsed for a certain time must be replaced. There was also a flaw.

In addition, since the cable is connected to the controller and the head by using an optical fiber such as quartz glass, a thick cable coated with a metal flexible cable or the like must be used to protect the optical fiber. In particular, the optical fiber cannot be bent freely because the bending angle is limited. In addition, the optical fiber has a problem that the cable length cannot be lengthened because transmission loss is proportional to the length.

In order to solve these problems, the present applicant has developed a UV irradiation apparatus using a high-power ultraviolet light emitting diode (UVLED) by replacing a high-pressure mercury lamp or a mercury xenon lamp with an ultraviolet light source, and installing the LED on the head instead of the controller of the main body. (Patent application 2003-158958, and patent application 2003-317622). This ultraviolet irradiation device is provided with a gas injection port for injecting an inert gas such as nitrogen gas into the head portion, whereby oxygen molecules in the vicinity of the surface of the resin in contact with the air when irradiated with ultraviolet light to the ultraviolet curable resin to cure In conjunction with the resin molecules, occurrence of a phenomenon (so-called oxygen inhibition) that inhibits the curing reaction of the resin is inhibited, thereby promoting curing of the resin. However, these apparatuses require a mechanism for providing an inert gas injection port in the head portion, which has a problem that the configuration is slightly complicated and the apparatus is enlarged. In addition, there is a problem that the cable connecting the controller and the head requires a gas tube for delivering an inert gas in addition to the optical fiber, and the cable becomes plural or thick, resulting in poor processing of the head connected to the cable.

[Patent Document 1] Publication No. 10-209492

SUMMARY OF THE INVENTION The present invention has been made to solve such a problem, and a main object of the present invention is to provide an ultraviolet irradiation device having a plurality of head portions, which is capable of individually setting conditions of ultraviolet rays irradiated from each head portion to improve usability. It is providing the ultraviolet irradiation device, the setting method of ultraviolet irradiation conditions, and an ultraviolet irradiation method.

In order to achieve the above object, the ultraviolet irradiating apparatus of the present invention is an ultraviolet irradiating apparatus for irradiating ultraviolet rays for curing an ultraviolet curable resin, and includes a plurality of head portions (l20) including one or more semiconductor elements capable of irradiating ultraviolet rays as an ultraviolet source. ), A setting unit including an operation panel l44 capable of individually setting ultraviolet irradiation conditions for each head unit 120, and a display unit 142 capable of displaying the setting contents set in the operation panel 144 ( 140, the storage unit 116 for storing a plurality of ultraviolet irradiation conditions set by the setting unit 140, a setting mode for setting ultraviolet irradiation conditions, and an irradiation mode for irradiating ultraviolet rays, respectively. Can be switched to, and when the irradiation mode is set, the ultraviolet irradiation condition setting stored in the storage unit 116 is called and the head unit 120 is A controller unit 110 having a control unit l14 for controlling a conductor element, a power supply unit 112 for supplying a drive current to the semiconductor element, and an electrical connection between the head unit 120 and the controller unit 1010. It characterized in that it comprises a cable unit 130 having an electrical signal line for. The use of semiconductor elements with lower power consumption compared to high-pressure mercury lamps, mercury xenon lamps, and the like for the ultraviolet source can reduce the size of the device and contribute to the reduction of operating costs. In addition, by enabling the plurality of head portions l20 to individually set the conditions of the ultraviolet output, each of the head portion 120 can be used independently, excellent characteristics that can be irradiated with a plurality of ultraviolet rays under various ultraviolet irradiation conditions This is realized. In particular, by setting a plurality of ultraviolet irradiation conditions and calling them to use them, it is possible to register and use frequently used settings or complicated settings to improve usability.

In addition, the other ultraviolet irradiation device of the present invention is an automatic irradiation mode for irradiating ultraviolet rays from an arbitrary head portion l20 according to a preset ultraviolet irradiation condition at the time of operating the irradiation mode of the ultraviolet irradiation device, and ultraviolet irradiation at the timing input from the outside. It characterized in that it comprises a manual irradiation mode for turning on / off. This configuration enables independent ultraviolet irradiation for each head unit 120 under preset conditions in addition to a mode in which ultraviolet irradiation is turned on / off in response to an input such as a switch or a trigger, and furthermore, irradiation output and time for each head unit. An automatic irradiation mode capable of changing the power supply is provided, and it is possible to independently use the plurality of head portions 120 with one ultraviolet irradiation device that has not been realized in the past.

In addition, the other ultraviolet irradiation device of the present invention is a batch irradiation mode for irradiating ultraviolet rays from all heads 120 during the irradiation mode operation of the ultraviolet irradiation device, and an individual irradiation mode for irradiating ultraviolet rays from a specific head portion l20. Equipped. This configuration makes it easy to use part or all of the head portion 120.

In addition, another ultraviolet irradiation device of the present invention is characterized in that the controller unit 110 includes a batch irradiation switch for executing the batch irradiation mode and a separate irradiation switch for executing the individual irradiation mode separately. This configuration makes it possible to quickly call up the collective irradiation mode and the individual irradiation mode, making it easy to use each mode.

Moreover, the other ultraviolet irradiation apparatus of this invention is that the said batch irradiation mode is equipped with the batch automatic irradiation mode which irradiates an ultraviolet-ray according to preset ultraviolet irradiation conditions, and the batch manual irradiation mode which performs ON / OFF of ultraviolet irradiation manually. It features. In this configuration, in addition to the batch manual irradiation mode for turning on / off each head portion 120 at the same timing, a batch automatic irradiation mode for independently operating each head portion l20 under preset conditions can be used. Use according to the head part use is aimed at.

Moreover, the other ultraviolet irradiation apparatus of this invention is characterized in that the said individual irradiation mode is an individual manual irradiation mode which performs ON / OFF of ultraviolet irradiation manually. By this structure, ultraviolet irradiation of each head part 20 can be called by arbitrary timing.

In addition, another ultraviolet irradiation device of the present invention is characterized in that the individual irradiation mode is provided with an individual automatic irradiation mode for irradiating ultraviolet rays according to preset ultraviolet irradiation conditions and an individual manual irradiation mode for manually turning on / off ultraviolet irradiation. It is done. In this configuration, in addition to being able to call the ultraviolet irradiation of each head 120 at an arbitrary timing, ultraviolet irradiation of each head portion l20 can be realized by various irradiation patterns in which irradiation conditions are set in advance.

Further, another ultraviolet irradiation device of the present invention sets the permission / deny of ultraviolet irradiation for each head portion 120 or for each semiconductor element included in each head portion 120 in setting ultraviolet irradiation conditions in a batch irradiation mode. It is characterized by being configured as possible. This configuration eliminates the necessity of using all of the head portions 120 connected as in the conventional ultraviolet irradiation device, and only the desired head portion l20 can be used, thereby improving usability.

In addition, the other ultraviolet irradiation device of the present invention is configured such that the display unit 142 can display a screen for selecting and calling a desired setting among a plurality of ultraviolet irradiation condition settings stored in the storage unit 116. do. With this configuration, a plurality of ultraviolet irradiation condition settings can be registered in advance, and arbitrary settings can be called and used, so that appropriate irradiation according to the use conditions can be called to easily obtain ultraviolet irradiation of a desired pattern.

In addition, the ultraviolet irradiation device of the present invention is characterized in that the display unit 142 can display the ultraviolet irradiation conditions set by the setting unit 140 as a graph. As a result, the set condition can be visually grasped, so that the setting can be easily performed, and at the same time, even when the setting is called, the lower limit pattern can be checked quickly, improving usability.

Further, another ultraviolet irradiation device of the present invention is characterized in that the semiconductor element is an ultraviolet light emitting diode l50. This configuration can contribute to the miniaturization of the ultraviolet irradiation device, the reduction of the power consumption, the extension of the lifespan, and the reduction of the running cost by using the ultraviolet light emitting diode 150 having a small and low power consumption.

Moreover, the other ultraviolet irradiation apparatus of this invention is comprised so that the ultraviolet irradiation conditions set with respect to one head part 120 can be radiated to another head part l20. This configuration can reduce the trouble of repeatedly performing the same setting, and in particular, setting work can be largely omitted in the case of using a plurality of head portions.

Further, the other ultraviolet irradiation device of the present invention further includes an operation failure detection unit that issues a warning when an electrical operation failure of the drive circuit 618 of the semiconductor element is detected. This configuration makes it possible to easily detect the occurrence of a problem in the hardware, and it is possible to take appropriate countermeasures promptly, thereby increasing the stability of the work and the reliability of the device.

In addition, the method for setting the ultraviolet irradiation conditions of the present invention is an operation capable of individually setting the ultraviolet irradiation conditions for the plurality of head portion 120 and each head portion 120 including one or more semiconductor elements capable of irradiating ultraviolet rays A controller including a panel 144, a setting unit 140 including a display unit 142 capable of displaying the setting contents set in the operation panel 144, and a power supply unit 112 for supplying driving current to the semiconductor device. It is a method for setting ultraviolet irradiation conditions in an ultraviolet irradiation device including a cable portion (10) having a portion (10) and an electrical signal line for electrically connecting the head portion (120) and the controller portion (110). The method includes the step of selecting a semiconductor element for irradiating ultraviolet rays or a head portion 120 including the semiconductor element, and setting the irradiation time and / or irradiation output for the selected semiconductor element or head portion l20. A step of setting irradiation conditions to be provided is provided. The use of semiconductor elements with lower power consumption compared to high-pressure mercury lamps, mercury xenon lamps, and the like for the ultraviolet source can reduce the size of the device and contribute to the reduction of operating costs. In addition, by allowing the plurality of heads 120 to individually set the conditions of the ultraviolet output, each of the heads 120 can be used independently, the excellent feature that can be irradiated with a plurality of ultraviolet light under various ultraviolet irradiation conditions This is realized.

In addition, the method for setting other ultraviolet irradiation conditions of the present invention is configured such that the ultraviolet irradiation device sets a plurality of ultraviolet irradiation conditions so as to individually store and call each of the ultraviolet irradiation conditions set. It is characterized by including the step of selecting the set number of ultraviolet irradiation condition setting. For this reason, by setting a plurality of ultraviolet irradiation conditions and making them callable and using them, it is possible to register and use frequently used settings or complicated settings, thereby improving usability.

In addition, according to another method of setting the ultraviolet irradiation conditions of the present invention, the ultraviolet irradiation conditions set for one head portion 120 are configured to be copyable to the other head portion 120. This saves the trouble of repeatedly performing the same setting, and in particular, in the case of using a plurality of head portions, the setting work can be largely omitted.

Moreover, the setting method of the other ultraviolet irradiation conditions of this invention is provided with the setting mode which the said ultraviolet irradiation apparatus sets the ultraviolet irradiation conditions, and the irradiation mode which irradiates an ultraviolet-ray so that switching is possible, The said irradiation mode is further preset The automatic irradiation mode which irradiates an ultraviolet-ray from the arbitrary head part 120 according to an ultraviolet irradiation condition, and the manual irradiation mode which turns on / off an ultraviolet irradiation at the timing input from the outside are provided, The setting method of an ultraviolet irradiation condition is It is further characterized by including a step of selecting any one irradiation mode. Therefore, in addition to the mode in which the ultraviolet irradiation is turned on or off in response to an input of a switch or a trigger, independent ultraviolet irradiation can be set for each head portion l20 under preset conditions. An automatic irradiation mode capable of changing the time is provided, and it is possible to independently use the plurality of head portions l20 with one ultraviolet irradiation device that has not been realized in the past.

Moreover, the setting method of the other ultraviolet irradiation conditions of this invention is equipped with the setting mode which the said ultraviolet irradiation apparatus sets the ultraviolet irradiation conditions, and the irradiation mode which irradiates an ultraviolet-ray so that switching is possible, The said irradiation mode consists of all the head parts ( The collective irradiation mode which irradiates an ultraviolet-ray from 120, and the individual irradiation mode which irradiates an ultraviolet-ray from the specific head part 120 are further provided, The setting method of an ultraviolet irradiation condition includes the step which selects an irradiation mode in either one. It is characterized by further comprising. For this reason, a plurality of irradiation modes are provided in the ultraviolet irradiation device, so that various situations can be coped with, and the irradiation mode can be selected even when setting the ultraviolet irradiation conditions, and the appropriate ultraviolet irradiation conditions can be set.

According to another method of setting ultraviolet irradiation conditions of the present invention, in the step of setting the ultraviolet irradiation conditions, the step of setting the ultraviolet irradiation conditions by selecting a preset irradiation pattern by changing the irradiation time and / or the irradiation output is set. It is characterized by including. This makes it possible to easily set even a setting including a complicated change by selecting from a previously set irradiation pattern, thereby simplifying the setting work. Moreover, there is also an advantage that proper use can be achieved by preparing an irradiation pattern according to the purpose of use of the ultraviolet irradiation device.

The method for setting another ultraviolet ray irradiation condition according to the present invention is characterized in that the step of setting the ultraviolet ray irradiation condition by selecting a preset irradiation pattern includes selecting a predetermined function and inputting a constant of the function. It is done. This makes it possible to easily set even a setting including a complicated change by selecting from the irradiation pattern designated by the function, which simplifies the setting work. Further, there is also an advantage that proper use can be achieved by preparing an irradiation pattern according to the purpose of use of the ultraviolet irradiation device.

Moreover, in the method of setting other ultraviolet irradiation conditions of this invention, the said function is P = at + c

P = a * (1-EXP (-b * t)) + c

P = a * (EXP (b * t) -1) + c

(a, b, c are integers set according to conditions). This makes it possible to easily perform setting including complicated changes by selecting from the irradiation pattern designated by the function, thereby simplifying the setting work. In addition, there is also an advantage that can be properly used by preparing an irradiation pattern according to the purpose of use of the ultraviolet irradiation device.

In addition, another ultraviolet irradiation condition setting method according to the present invention is characterized in that it comprises a step of designating which semiconductor element is targeted when the head portion 120 has a plurality of semiconductor elements. For this reason, a plurality of semiconductor elements can be switched and used, and the semiconductor element can be driven simultaneously to increase the amount of ultraviolet rays, or alternatively, to prolong life.

Another ultraviolet irradiation condition setting method according to the present invention is characterized in that, when the head portion 120 has a plurality of semiconductor elements, a command for all semiconductor elements can be specified. As a result, the setting work in the case of setting the same condition to a plurality of semiconductor elements can be simplified.

According to another ultraviolet irradiation condition setting method of the present invention, in the setting of ultraviolet irradiation conditions, the permission / deny of ultraviolet irradiation can be set for each head portion l20 or for each semiconductor element provided in each head portion 120. Characterized in that the configuration. For this reason, since it is not necessary to use all the connected head part l20 like the conventional ultraviolet irradiation apparatus, only the desired head part 120 can be used, and usability improves.

In addition, the method for setting the ultraviolet irradiation conditions according to the present invention can individually set the ultraviolet irradiation conditions for the plurality of head portion 120 and each head portion l20 including one or more semiconductor elements capable of irradiating ultraviolet rays. The setting unit 140 including an operation panel 144, a display unit 142 capable of displaying the setting contents set in the operation panel 144, and a plurality of ultraviolet irradiation conditions set in the setting unit 140 are respectively stored. The operation unit 144 can switch between the storage unit 116 to be set, the setting mode for setting the ultraviolet irradiation conditions, and the irradiation mode for irradiating ultraviolet rays, and the ultraviolet rays stored in the storage unit 116 in the irradiation mode. A control unit 114 for controlling the semiconductor element of the head unit 120 according to the ultraviolet irradiation condition setting by calling the irradiation condition setting, and a power supply unit 112 for supplying a driving current to the semiconductor element. A method for setting ultraviolet irradiation conditions in an ultraviolet irradiation device comprising a controller portion 110 and a cable portion 130 having an electrical circuit for electrically connecting the head portion 120 and the controller portion 110. to be. This method comprises the steps of selecting a setting number of ultraviolet irradiation condition setting, setting an ultraviolet irradiation condition including setting of irradiation time and irradiation output for this selected semiconductor element or head portion 120, and setting ultraviolet rays. It is characterized by including the step of saving the setting of irradiation conditions. The use of semiconductor elements with lower power consumption compared to high-pressure mercury lamps, mercury xenon lamps, and the like for the ultraviolet source can reduce the size of the device and contribute to the reduction of operating costs. In addition, by allowing the plurality of heads 120 to individually set the conditions of the ultraviolet output, each head 120 can be used independently, and excellent ultraviolet light can be irradiated with a plurality of ultraviolet irradiation conditions. The feature is realized. In particular, by setting a plurality of ultraviolet irradiation conditions and making them callable to use, it is possible to register and use frequently used settings or complicated settings, thereby improving usability.

In another method of setting the ultraviolet irradiation condition according to the present invention, the display unit 142 may display the ultraviolet irradiation condition set by the setting unit 140 as a graph. As a result, the set conditions can be visually grasped, so that the setting can be easily performed, and the pattern used when the setting is called can be quickly confirmed, thereby improving usability.

In addition, the method for setting other ultraviolet irradiation conditions of the present invention is characterized in that the semiconductor device is an ultraviolet light emitting diode (150). For this reason, it is possible to contribute to the miniaturization of the ultraviolet irradiation device, the reduction of the power consumption, the extension of the lifespan, the reduction of the running cost, etc. by using the ultraviolet light emitting diode 150 of small size and low power consumption.

In addition, the ultraviolet irradiation method of the present invention includes a plurality of head portions 120 including one or more semiconductor elements capable of irradiating ultraviolet rays, and an operation panel l44 capable of individually setting ultraviolet irradiation conditions for each head portion 120. ), A setting unit 140 including a display unit 142 capable of displaying the setting contents set in the operation panel l44, and a storage unit for storing a plurality of ultraviolet irradiation conditions set in the setting unit 140, respectively. 116, the setting mode for setting the ultraviolet irradiation condition and the irradiation mode for irradiating ultraviolet light can be switched by the operation panel 144, and the setting of the ultraviolet irradiation condition stored in the storage unit 116 is called during the irradiation mode. The control unit 114 for controlling the semiconductor element of the head unit 120 according to the ultraviolet irradiation condition setting, the power supply unit 112 for supplying a driving current to the semiconductor element, and the set ultraviolet irradiation condition. UV irradiation comprising a controller unit 110 having an irradiation switch for calling and executing, and a cable unit 130 having an electrical signal line for electrically connecting the head unit 120 and the controller unit 110. An ultraviolet irradiation method using a device, comprising: selecting a desired setting number from the plurality of ultraviolet irradiation condition settings previously set, and setting the selected ultraviolet irradiation condition by operating the irradiation switch; Characterized in that. As a result, the plurality of heads 120 can be independently set in advance to register the conditions for irradiating ultraviolet light under various conditions, and thus easily call up the ultraviolet irradiation conditions according to the use situation or purpose. The setting for each 120 becomes easy, and usability is improved.

In addition, another ultraviolet irradiation method of the present invention has a function of issuing a warning when an electrical operation failure of the driving circuit 618 of the semiconductor element is detected based on the electrical state of the input side terminal and the output side terminal of the semiconductor element. . As a result, the occurrence of a hardware problem can be easily detected, a prompt and appropriate countermeasure can be achieved, and the stability of the work and the reliability of the device can be improved.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described based on drawing. However, embodiment shown below illustrates the ultraviolet irradiation device, the ultraviolet irradiation setting method, and the ultraviolet irradiation method for embodying the technical thought of this invention, and this invention sets the ultraviolet irradiation device and ultraviolet irradiation conditions. The method and the ultraviolet irradiation method are not specified as follows.

In addition, in this specification, the number corresponding to the member shown by embodiment is attached to the member shown in the "column of a claim" and the "construction column of an invention" so that a claim may be easily understood. However, the member displayed in the claims is not identified as a member of the embodiment. In addition, the size, positional relationship, etc. of the member which each figure shows may be exaggerated for clarity. In addition, in the following description, about the same name and code | symbol, the same or same member is shown, and detailed description is abbreviate | omitted suitably. In addition, each element constituting the present invention may be configured such that a plurality of elements are constituted by the same member and a plurality of elements are combined with one member, or conversely, the function of one member may be shared by a plurality of members. .

[Embodiment 1]

1 is a block diagram of an ultraviolet irradiation device according to Embodiment 1 of the present invention. In the ultraviolet irradiation device 100 shown in this figure, the controller unit 110 and the head unit 120 are connected to the cable unit 130. The head part 120 has a semiconductor element which emits ultraviolet rays for curing the ultraviolet curable resin. The controller unit 110 includes a power supply unit 112, a control unit 114, and a storage unit 116 for driving the semiconductor element of the head unit 120, and the driving signal of the semiconductor element through the cable unit 130 ( Electrical signal) to the head 120. In this figure, only one head portion 120 is connected to the controller portion 110, but as described later, a plurality of head portions can be connected to the controller portion, and ultraviolet irradiation conditions can be set independently of each other. Moreover, the ultraviolet irradiation device can switch between the setting mode which sets an ultraviolet irradiation condition, and the irradiation mode which irradiates an ultraviolet-ray actually. The ultraviolet irradiation conditions set by the setting unit 140 (described later) in the setting mode are stored in the storage unit 116. The setting unit 140 sets a plurality of ultraviolet irradiation conditions and stores them in the storage unit 116. In the irradiation mode, the control unit 114 calls up the necessary ultraviolet irradiation condition setting from the storage unit 116, and according to this setting, the control unit 1 14 supplies a drive current from the power supply unit 112 to the head unit 120 to supply the head. The semiconductor device of the unit 120 is controlled.

(Semiconductor element)

As the semiconductor device, a semiconductor light emitting device such as a light emitting diode (LED) or a semiconductor laser (LD) can be used. Compared with mercury xenon lamps and the like, these semiconductor devices are ideally used because they have excellent characteristics such as small size, high efficiency, low calorific value and long life, and strong resistance to mechanical vibration. In this embodiment, an ultraviolet light emitting diode (UVLED) which directly irradiates ultraviolet light is used as a semiconductor element. UVLED can use what used the nitride compound semiconductor represented by general formula InxAlyGa1-x-yN (0 <= x, 0 <= y, x + y <= _l ) for the active layer (light emitting layer), for example. In the light emitting layer, a double hetero structure, a single quantum well structure (SQW), a multi quantum well structure (MQW), or the like can be appropriately employed. Moreover, it is a matter of course that it is not limited to the UVLED which irradiates an ultraviolet-ray directly, For example, the structure which converts irradiation light of LED into an ultraviolet light using a wavelength conversion element etc. can also be employ | adopted suitably.

UVLEDs are turned on only when necessary, that is, they are not turned on all the time, so that power consumption can be suppressed to extend the life of the UVLEDs. However, it is also possible to adopt a configuration in which the UVLED is always turned on and the shutter is mechanically operated to turn on / off the ultraviolet light, as in a conventional high pressure mercury lamp.

As the wavelength of the ultraviolet rays output from the semiconductor element, near ultraviolet rays in the vicinity of 300 to 400 nm, for example, around the wavelength of 380 nm can be used, and the wavelength is determined according to the ultraviolet curable resin used. As the ultraviolet curable resin, for example, an alicyclic epoxy resin, an epoxy resin containing a glycidyl group-containing epoxy resin, an ultraviolet ray activated adhesive including an ultraviolet ray activated cationic polymerization catalyst, a cationic polymerization inhibitor, and the like can be used. Ultraviolet wavelength, a purpose of use, and a use are not limited to this.

(Cable part 130)

The cable unit 130 uses a wire harness in which a power line and a signal line are bundled. Since the cable unit 130 is a simple electric signal line that does not include an optical path such as an optical fiber made of quartz glass, it is used in a conventional ultraviolet irradiation device without being restricted by the entire length due to the limitation of bending angle or light attenuation. It can be thinner and lighter than the cable, making it highly flexible and very easy to handle. In addition, it can be made long because there is no restriction on the overall length. For this reason, when setting and using different ultraviolet irradiation conditions for the several head part 120, since a cable can be extended and connected to one ultraviolet irradiation apparatus, it can respond flexibly to the design and arrangement of a system.

(Head part 120)

2-5, the external appearance of the head part 120 of an ultraviolet irradiation device is shown. FIG. 2A is a front view of the head 120, and FIG. 2B is a partial sectional view showing the internal structure. 3 to 5 are exploded views of the head 120, FIG. 3 is an exploded perspective view seen from above, FIG. 4 is an exploded perspective view seen from the lower side opposite to FIG. 3, and FIG. 5 is a connection connector of FIG. 1231 and l244 are respectively shown perspective views each showing a state of being connected. The head part 120 shown in these figures is the head main body part 122 with which the cable part 130 was connected to the base end side, the cooling block 124 which detachably couple | bonded with the front end side, and the removable part at the front end side. It is provided with an interchangeable lens holder 126 that is coupled securely. The head main body 122 is sized to be grasped by the user, and as shown in FIG. 3, the case body 1221 and 1222 and the base end member 1223 separated up and down are combined to form an empty box. A case 1224 is provided and a substrate 1224 is housed therein. A cable connector 1225 to which the cable part 130 is connected is attached to the base end member 1223, and the cable part 130 and the board 1224 are electrically connected through the cable connector 1225.

The substrate 1224 includes an electronic component for controlling driving by supplying a driving current received from the cable unit 130 to the UVLED 150. The indicator LED 1226 is mounted on the board | substrate 1224 as an indicator which shows the ON / OFF state of ultraviolet irradiation. In the example of FIG. 3, two indicator LEDs 1226 are disposed to increase the amount of light. However, one LED may be used by using a light quantity and a high brightness LED required as an indicator. Moreover, it can also be set as three or more LED.

On the substrate 1224, various electronic components for receiving a driving signal generated by the control unit 114 of the controller unit 110 and supplying a driving current to the UVLED 150, a memory unit 1227, an adjusting circuit 1228, and the like. This is implemented. The memory unit 1227 is used to store the operating time of the head unit 120 and to record the initial characteristics of the UVLED 150, and can suitably use an EEPROM which is a nonvolatile memory.                     

(Adjustment work of UVLED150)

Semiconductor devices such as the UVLED 150 have a good linearity with respect to the drive current, but the output tends to decrease with use time. Therefore, accurate output control can be maintained by adjusting the drive current in consideration of the variation in the output due to deterioration over time. The adjustment of the drive current is performed for each head portion 120 by an adjusting circuit l228 such as a semi-fixed resistor (current adjusting trimmer) as shown in Fig. 2B and the like. In addition, in the example of FIG. 2 (b), the semi-fixed resistors constituting the adjusting circuit 1228 are mounted on the substrate in the head portion 120 so that they cannot be adjusted from the outside. The situation in which the drive current is changed by the operation of is avoided. However, it is also possible to employ a configuration in which the drive current can be adjusted externally. For example, a specially shaped tool may be used to adjust the resistance value, or a small hole may be opened in the case of the head portion 120 to adjust the resistance value from the hole, or the controller portion 110 or the head portion 120 may be adjusted. The adjustment function of the adjustment circuit 1228 can be called by specific operation, such as long press of the individual setting switch provided in the figure).

In order to regularly adjust the driving current, the user is reported to the user every time the use time of each head 120 reaches a predetermined time and prompts the adjustment of the driving current. The memory part 1227 provided in each head part 120 updates and stores the drive time integration value of UVLED 150, ie, the drive integration time. The control unit 110 of the controller unit 110 controls the driving of the UVLED 150 of the head unit 120 through a D / A converter, a drive circuit, and the like, and at the same time, calculates an integrated value of the driving time of the head unit 120. In the memory section 1227. This recording (update memory) is performed every predetermined time (for example, every minute). When the driving integration time read out from the memory unit 1227 reaches a predetermined adjustment time, the control unit 114 outputs a notification to perform the adjustment operation of the UVLED 150. As the notification output, for example, a blinking display of a LED, a buzzer brightness, or the like is used. Alternatively, when the controller 110 is provided with a display capable of displaying a message, a message for prompting the adjustment operation of the UVLED 150 may be displayed using the display. The user grasps that the time required for the adjustment operation has been reached by the notification output, and performs the current correction using the adjustment circuit 1228 as described above. For example, it adjusts so that driving current may become large in consideration of the fall of the output with respect to the reference driving current.

In addition, when the driving integration time reaches the life of the UVLED 150, a notification output for prompting the replacement of the UVLED 150 may be made.

The memory unit 1227 can also store data on initial characteristics of the UVLED 150 and use it for adjusting the drive current. In general, since there is an individual difference (variation) in the initial luminance of the UVLED 150, the initial luminance adjustment circuit 1228 is usually required for the driving circuit on the head 120 side of the UVLED 150. A semi-fixed resistor or the like is used for the initial luminance adjusting circuit, and for example, the adjusting circuit 1228 shown in Fig. 2B can be used in combination. And. It is necessary to perform initial adjustment by the initial brightness adjustment circuit in each head part 120 so that the ultraviolet irradiation power may become a predetermined value for every head part l20.

In the ultraviolet irradiation device of Embodiment 1, the initial luminance adjustment as described above is stored by storing the initial characteristic data regarding the initial measured initial luminance of the UVLEDs 150 mounted in each head portion 120 in the memory portion 1227. The circuit and the initial adjustment work using it become unnecessary. That is, the control unit 114 reads out the initial characteristic data from the memory unit 1227 and determines an appropriate basic driving current (exactly a digital value corresponding thereto) according to the initial characteristic data.

The digital value corresponding to the drive current output from the controller 114 is converted into an analog voltage by a D / A converter and given to a drive circuit. The drive circuit drives the UVLED 150 of the head 120 with a drive current corresponding to a given analog voltage. Moreover, since this drive current can be adjusted up and down by the setting part l40, the ultraviolet irradiation output can be adjusted by this.

By providing the memory unit 1227 on the head 120 side as described above, accurate adjustment according to the characteristics of the UVLED 150 provided in the head 120 can be realized. For example, in the case where the channel of the head connection connector 160 of the controller unit 110 connecting the head unit 120 is uniquely fixed, the above adjustment is performed even if the memory unit is provided on the controller unit 110 side. It is possible. This is because the memory unit on the controller unit 110 side can store the driving integration time and initial characteristic data for each channel. However, in the case where the channel of the connection portion of the head portion 20 is changed, the above method cannot cope, and the user must memorize the ultraviolet irradiation device and the channel number of the connection portion for each head portion 120 by any means. It takes time and worsens usability. Therefore, as described above, by providing the memory unit 1227 on the head unit 120 side, even if the head unit 120 is connected to any channel number of any ultraviolet irradiation device, accurate driving according to the characteristics of the head unit 120 Current regulation is realized to improve usability.

(Cooling block 24)

In addition, since the UVLED 150 that emits ultraviolet rays tends to have a larger self-heating rate than the LED that emits visible light, it is preferable to provide a heat radiating mechanism to the head 120 so that it can be stable and used for a long time. In the example shown in FIGS. 2-5, the UVLED 150 is connected to the cooling block 124. FIG. The cooling block 124 functions as a heat sink that cools heat generated during the operation of the UVLED 150, and is made of a metal having good thermal conductivity such as aluminum. UVLED 15 is tightly fixed to the front end surface of the cooling block 124. FIG. 6 is a view illustrating a state in which the UVLED 150 is tightly fixed to the front end surface of the cooling block 124. As shown in this figure, the UVLED 150 is fixed to the front end surface of the cooling block 124 by three fixing screws 1241.

(Lens holder 126)

The lens holder 126 houses one or more optical lenses 1261 for condensing ultraviolet rays emitted from the UVLEDs 150. 7 is an exploded view showing an example of the lens holder l26 and its internal structure. In this example, the first lens 1261A and the second lens 1261B are fixed to the inside of the lens holder 126 by the spacer 1262 and the lens fixing cap 1263 with two lenses. The lens may be composed of one piece, but the lens size tends to increase with one lens due to the refractive index. Thus, in the first embodiment, two optical lenses 1261 are used, and the first lens 1261A and the second lens 1261B are irradiated with ultraviolet light from the UVLED 150 to the outside, thereby the size of the lens itself. The size of the lens holder 126 and the head 120 can be reduced.

8 is a diagram illustrating an example of a fixing method between the cooling block 124 and the lens holder 126. In this example, the cooling block l24 and the lens holder 126 are fixed to each other by three fixing screws 1242. Yet, by preparing and replacing a plurality of types of lens holders 126 having different synthetic focal lengths of the lenses, the tip of the head portion 120 and the UV irradiation target (by the ultraviolet curable resin) are used while the same head portion 120 is used. It can correspond to the case where the distance of the adhesive fixing part) changes.

Returning to FIG. 3, the fixing method of the cooling block 124 and the head main-body part l22 is demonstrated. After fixing the cooling block 124 and the lens holder 126 as described above, the upper case member 1221 and the lower case member 1222 constituting the head body portion 122 are joined to each other and the tip portion is the cooling block. The proximal end protrusion 1243 of 124 is sandwiched between and fixed to the cooling block 124 with fixing screws 1229, respectively. In addition, the base end member 1223 is fixed to the base end surfaces of the upper case member 1221 and the lower case member 1222 using the fixing screw 1230.

As shown in FIGS. 4 and 5, the cooling block 124 including the cable connector 1225 or the UVLED 150 is electrically connected to the substrate through the connecting connectors 1231 and 1244, respectively. As a result, the UVLED 150 is driven and controlled by receiving power from the controller unit 110 through the cable unit 130. As described above, each block requiring electrical connection is connected to each other through a connector to facilitate disassembly of each part, so that maintenance work such as replacement or repair can be easily performed. In particular, the head portion 120 shown in the drawing has a structure in which the head body portion 122, the cooling block l24, and the lens holder 126 are combined in order, so that the division for each unit is easy and the head portion excellent in maintainability ( 120). .

4 and 5, through holes 1232, which are screw holes for fixing the head 120 to a holder, are opened in the lower case member 1222. As shown in FIG. When fixing the head portion 120 by screwing screws, the lower case member 1221 is provided with a protective plate (as shown in FIG. 3) so that the tip of the screw does not damage the substrate 1224 or the mounting parts on the substrate. 1245 is fixed to block the through hole 1232 and the substrate 1224.

(Controller section 110)

9 is a front view of the controller unit 110. In this example, the four-channel controller 110 which can connect four head parts 120 is shown. The number of heads 120 to which the head 120 can be connected is determined by the number of channels. The number of channels may be 3 or less, or 5 or more. The controller part 110 shown in this figure has the display part 142 and the operation panel 144 provided in the front panel as the setting part 140 for setting the ultraviolet irradiation conditions of the UVLED 150 individually. In FIG. 9, the display unit 142 is disposed above the front panel and the operation panel 144 is disposed below the front panel.

(Operation panel 144)                     

The operation panel l44 constituting the setting unit 140 includes <,>, ∧, ∨ switches 144A, 144B, 144C, and 144D, which are the selector switches up, down, left, and right, the escape switch 144L, and the enter switch 144F. Are arranged respectively. The user operates these switches to set the ultraviolet irradiation condition of the UVLED 150 in a predetermined order. In addition, not only this example, but various input devices, such as a cross key, a ten key, and a jog dial, can be used for the operation panel 144. As shown in FIG. It may also be a touch panel in which the operation panel is integrated with the display unit. Various switches provided on the operation panel 144 can be used in common for the operation of the respective head units 120, and can be set by switching the channels to which the head units 120 are connected.

In addition, the switches of the setting unit 140 do not need to be fixed to the controller unit 110, and may be provided as the controller unit 110 and the individual members. For example, a console, a remote controller, a foot switch, and the like, in which a switch is provided in a setting unit which is separate from the controller unit 110 and connected to the controller unit 110 by wire or wirelessly, are also within the scope of the present invention. to be. Moreover, you may comprise so that setting and operation can be performed from the external connection device connected to the ultraviolet irradiation device, as mentioned later.

In addition, in this specification, the setting part also includes the form used in addition to the setting of ultraviolet irradiation conditions, and also includes an irradiation switch used at the time of operation | movement of an ultraviolet irradiation apparatus, for example. In addition, when the foot switch is connected to the controller unit 110 as an irradiation switch, for example, a delay of the ON / OFF input may be set in order to prevent chattering caused by disturbance. The on timing (delay setting) and the off timing (delay setting) of the ultraviolet rays can be set individually or collectively using the setting unit. ,                     

(Display part 142)

Moreover, the display part l42 which comprises the setting part 140 is equipped with the 7 segment indicator which used the LED or the liquid crystal display. The user performs the setting operation while displaying and confirming the ultraviolet irradiation conditions such as the output of the ultraviolet rays and the irradiation time set by the operation panel 144 on the display unit 142. The display unit 142 switches the setting conditions of each head unit 120 to display one screen. As described later, a plurality of display units may be provided for each head unit 120 individually. In addition, although the ultraviolet output is set and displayed by the relative intensity value, for example, the drive impact coefficient of the UVLED 150, you may display by the absolute output value (mW etc.). In addition, the display unit 142 can be constituted by liquid crystal or organic EL, and enable graphical display such as icon display. It is also possible to enable color display.

In addition, a channel display lamp 145 is provided for each channel under the display unit 142. Accordingly, the channel currently selected and displayed on the display unit 142 can be distinguished. In the example of FIG. 4, four channel display lamps 145 of 1 to 4 channels are provided. In addition, an ultraviolet irradiation lamp 146 is disposed adjacent to these channel display lamps 145. The ultraviolet irradiation lamp 146 functions as a pilot lamp indicating that the ultraviolet rays are irradiated (emission) from a certain head portion 120, and are formed of, for example, an LED or the like. That is, when the LED of the ultraviolet irradiation lamp 146 is lighting, a user is notified that ultraviolet rays are irradiating.

The power switch 147 and the collective irradiation switch 148 are provided below the operation panel 144. The power switch 147 is a switch for turning on / off the power of the ultraviolet irradiation device. For example, by adopting a key switch for the power switch l47, a situation in which the switch suddenly turns ON can be avoided.

(Batch switch 148).

The collective irradiation switch 148 may independently irradiate ultraviolet rays from all the head parts 120 according to respective ultraviolet irradiation conditions set in advance for each of the head parts l20 by the setting unit 140.

(Head connector 160)

In addition, the head connection connector 160, the individual irradiation lamp 170, and the individual irradiation switch 180 are provided in each head part 120 below the front panel. In FIG. 9, the head connection connector 160 arranged vertically on the left side is a connector for connecting the cable of the head part 120. As described above, the controller unit 110 of FIG. 9 is provided with four channel head connection connectors 160 to connect four head units 120. Of course, it is not necessary to use all channels, and of course, only any of these channels can be used depending on the use conditions.

(Individual survey lamp 170)

In addition, an individual irradiation lamp 170 is disposed adjacent to the right side of each head connection connector 160. The individual irradiation lamp 170 is a lamp for indicating that ultraviolet rays are irradiated from the head 120 UVLED 150 connected to each channel. As a result, the user can confirm from which head unit 120 ultraviolet rays are currently irradiated. LED etc. can also be used for the individual irradiation lamp 170. Further, when the collective irradiation switch 148 is pressed, all the individual irradiation lamps 70 are turned on.                     

(Individual count switch 180)

In addition, the individual irradiation switch l80 is disposed on the right side of the individual irradiation lamp 170. The individual irradiation switch 180 is a switch for individually turning on / off the ultraviolet output of the head unit 120 connected to each channel. By providing the individual irradiation switch 180 for each channel, the ultraviolet output of the head unit 120 connected to each channel can be operated individually, and in particular, by providing a dedicated switch, a small number of operations (such as pressing a button) can be achieved. Since the output of each head part 120 can be turned ON / OFF, an ultraviolet irradiation device can be used more conveniently. However, it is also possible to configure so that the operation panel 144 can operate ON / OFF of each channel, without providing an individual irradiation switch.

In the above, the layout arrangement | positioning of the setting part 140 was demonstrated based on FIG. 9, Of course, these arrangements can be changed arbitrarily. For example, in the example of FIG. 9, a plurality of channels are arranged vertically and a head connecting connector 160, an individual irradiation lamp 170, and an individual irradiation switch 180 for each channel are arranged in the horizontal direction. As a form, a channel can be arrange | positioned in a horizontal direction, and head connection connector, individual irradiation lamp, individual irradiation switch, etc. for every channel can also be arrange | positioned in a vertical direction. In addition, although the irradiation lamp and the irradiation switch were provided separately in the said embodiment, when using the switch with a backlight which lights up in an on state, these can also be integrated in one member.

As shown in FIG. 1, the controller unit 110 includes a power supply unit 112 and a control unit 114. The commercial power supplied from the AC inlet is supplied to the power supply 112 through the line filter, the fuse, and the power switch 147, and the DC stabilization voltage generated by the power supply 112 is supplied to the controller 114. The control unit 114 can be realized with a gate array such as a microprocessor (MPU), LSI, FPGA, or ASIC. In addition, the control unit 114 includes a memory and controls the intensity of the near-ultraviolet rays from each head unit 120, the irradiation timing, and the like in accordance with a program stored in advance and a user's setting operation. The control unit 114 is connected to a terminal block board and a communication connector, so that external control devices such as a computer or a programmable logic controller (PLC) can be connected to the controller unit 10 by using these interfaces. An external connection device can be used for setting of ultraviolet irradiation conditions and ON / OFF operation of an ultraviolet irradiation device, as mentioned later. That is, the setting unit 140 provided in the controller unit 110 of the ultraviolet irradiation device may be set or operated, and the ON / OFF of the ultraviolet irradiation device may be operated by trigger input from an external connection device.

In addition, four head connection connectors 160 are connected to the control unit 114, and each head unit 120 is connected to the control unit 114 of the controller unit 1010 through these head connection connectors 160. In addition, the control unit 114 provides an electric signal for driving control of the UVLEDs 150 of each head unit 120 to each of the head units 120, and the near-ultraviolet rays from the head units 120 are irradiated with intensity or irradiation. Control the timing. In addition, the front panel substrate is connected to the control unit 114. The display panel 142 and the setting unit 140 provided on the front panel of the controller unit 110 and various switches are mounted on the front panel substrate. The user may individually set the intensity and irradiation timing of the near ultraviolet rays of the four head units 120 using the display unit 142 and the setting unit 140.

 [Switch Mode]                     

As mentioned above, the ultraviolet irradiation device which concerns on this embodiment can switch between the setting mode which sets ultraviolet irradiation conditions, and the irradiation mode which irradiates an ultraviolet-ray by a control part. To switch between the setting mode and the irradiation mode, a dedicated changeover switch can be provided, or a combination or a long press of a specific switch can be used. In this embodiment, the setting mode and irradiation mode are switched between each other by long pressing (for example, 3 seconds or more) of the escape switch 144E in the operation panel 144 shown in FIG. 9.

[Investigation mode]

The details of the irradiation mode will be described below. First, in this embodiment, the collective irradiation mode which irradiates an ultraviolet-ray from all the head parts 120 in the irradiation mode of an ultraviolet irradiation device, and the individual irradiation mode which irradiates an ultraviolet-ray from one head part 120 are provided. . As described above, when the collective irradiation switch 148 is operated, the collective irradiation mode is executed, and when the individual irradiation switch 180 is operated, the individual irradiation mode is executed.

In addition, each irradiation mode can be classified into an automatic mode and a manual mode, respectively. The automatic mode is a mode in which irradiation output or irradiation time can be changed in accordance with preset ultraviolet irradiation conditions. That is, in the automatic mode, when the irradiation start instruction is received, irradiation is started with the irradiation pattern registered for each head unit 120 in advance, and after the completion of the irradiation, the ultraviolet irradiation is automatically stopped. On the other hand, the manual mode is a mode which switches ON / OFF of ultraviolet irradiation at a specified timing. That is, when receiving the irradiation start command, the investigation is continued with a constant output until receiving the irradiation stop command. The output starts when the irradiation switch is turned on and ends when it is turned off. As described later, the ultraviolet output value can be changed even in the manual mode.                     

The irradiation start and stop instruction of the ultraviolet ray in the irradiation mode are realized by the trigger input from the irradiation switch or the terminal block provided in the controller unit 110 as described above. In addition, in the embodiment, when the irradiation switch is pressed once, the irradiation mode is executed, and when it is pressed again, the irradiation mode is stopped or stopped. In the case of interruption, irradiation mode is resumed by holding a pause state and pressing a switch again.

[Manual irradiation mode]

The ultraviolet irradiation device can store the plurality of ultraviolet irradiation conditions set by the setting unit 140 in the storage unit 16. In addition, it is possible to preserve the operation mode for each ultraviolet irradiation condition setting. In the manual mode, the ultraviolet output value can be stored for each head portion 120. Therefore, in the individual manual irradiation mode, the plurality of heads 120 can be irradiated with different ultraviolet outputs, respectively. In addition, in the batch manual irradiation mode, each head unit 120 may simultaneously start different ultraviolet outputs and terminate irradiation at the same time. In addition, since the irradiation permit / deny can be set for each head unit 120, even if the head unit 20 is connected to the ultraviolet irradiation device, it is possible to irradiate only the desired head unit 120. In the conventional ultraviolet irradiation device, all the heads connected to the same device are output at the same output and timing, so as long as the heads are connected to the device, the output is necessarily generated together with the outputs of the other heads and the irradiation cannot be stopped. On the other hand, in this embodiment, since each head part 20 is independent, there exists an advantage that the permission / disallowance of ultraviolet irradiation can be set easily.

[Auto investigation mode]                     

In addition, the irradiation pattern can be stored for each head even in the automatic mode. Therefore, in the batch automatic irradiation mode, the plurality of heads 120 can simultaneously start irradiation in different irradiation patterns and end irradiation at different timings. As described above, such an operation could not be realized by the conventional ultraviolet irradiation device. In particular, although the heads could not be stopped at different irradiation patterns or at different timings, the present embodiment enables independent outputs of different heads and outputs at different timings, thereby enabling ultra-high degree of ultraviolet irradiation. As described above, since the irradiation permit / deny can be set for each head unit 120, even if the head unit 120 is connected to the ultraviolet irradiation device, it can be irradiated only in the desired head unit 120. In addition, when the irradiation start instruction can be inputted for each head portion, ultraviolet irradiation can be started at a different timing for each head portion. For example, individual irradiation switches may be provided as many as the number of head portions, or the number of terminal block trigger inputs may be prepared as many as the number of head portions.

Incorporating the operation mode described above, in the batch automatic irradiation mode, all heads 120 are irradiated with ultraviolet rays under ultraviolet irradiation conditions such as ultraviolet output and irradiation time set in advance for each head unit 120. When the collective irradiation switch is pressed, ultraviolet irradiation is started from each head unit 120, and ultraviolet irradiation is performed independently of various outputs in time. In addition, the end of ultraviolet irradiation differs for every head part 120 according to each setting, and it ends automatically for every head part 120 when setting is complete | finished.

In addition, in the batch manual irradiation mode, ultraviolet rays are output at a constant value from all the heads 120 when executed. When the collective irradiation switch is pressed, ultraviolet irradiation is started from each head unit 120, and when the collective irradiation switch is pressed again, the ultraviolet irradiation of each head unit 120 is stopped. Even in this case, the ultraviolet output value can be changed for each head.

In addition, when the individual manual irradiation mode is executed in each head portion l20, ultraviolet rays are output from the head portion 120 at a predetermined value. Also in this case, the ultraviolet output value for each head can be changed.

[Individual Auto Survey Mode]

The individual automatic irradiation mode is a mode for setting ultraviolet irradiation conditions for each head unit 120. The function corresponding to the individual automatic irradiation mode is practically realized by using the batch automatic irradiation mode even without special installation. In other words, by irradiating only specific UVLED and not irradiating other UVLED, UV irradiation condition such as irradiation time and output of the specific UVLED is set. You can run a survey. In this case, however, only a specific UVLED can execute ultraviolet irradiation, and in order to execute an operation corresponding to an individual automatic irradiation mode to other UVLEDs, it is necessary to enable a plurality of batch automatic irradiation modes in parallel. On the other hand, it is possible to set the batch automatic irradiation mode to operate a plurality of UVLEDs. However, when the operation timing for each UVLED changes, it becomes difficult to respond. On the other hand, it may be considered that it is convenient for the user to set and execute automatic irradiation for each head part, so that the individual automatic irradiation mode may be separately installed.

[Setting method of ultraviolet irradiation condition]                     

Next, the setting method of ultraviolet irradiation conditions is demonstrated based on FIG. Here, a combination of a plurality of square waves as shown in Fig. 11 (a) in order to obtain a pattern in which the ultraviolet rays irradiated from each head portion 120 changes in step shape with time as shown in Fig. 11 (b). Consider an example in which the conditions for the individual square waves are set. In addition, the set of ultraviolet irradiation conditions which consist of each square wave shown in FIG. 11, ie, a combination of constant irradiation output and irradiation time, is called a step here.

[Square wave shape irradiation pattern]

10 shows an outline of a setting method in the case where the head 120 includes one UVLED 150. In Fig. 10, first, the number of the head portion 120 is selected in step S100l. As described above, in the present embodiment, four head units 120 are connected to channels 1 to 4, and the channel 120 selects which channel to set. Next, in step S1002, the step number is selected. Steps are set in order from 1, and in the present embodiment, up to 20 steps can be set in one ultraviolet irradiation condition setting. Next, the irradiation time of the ultraviolet ray is set in step S1003 according to the selected step. Here, the number of seconds is specified. In addition, the irradiation output of the ultraviolet ray is specified in step S1004. Here, the normalization of the drive current value is set using percentage. More specifically, the DC drive current value, that is, the one corresponding to the light amount is set. In step S1005, the settings are temporarily saved, and at the same time, the process returns to the step of selecting the step number and loops until the settings are completed for all necessary steps. In this way, when the ultraviolet irradiation pattern as shown in Fig. 11 is set, the ultraviolet irradiation condition setting is preserved.                     

In addition, each of the above steps may be appropriately replaced with the order. For example, irradiation time may be set after setting irradiation output first.

12 is a flowchart showing the above steps in more detail. First, in step S1201, the number (setting number) of ultraviolet irradiation condition setting is selected. In this embodiment, 20 ultraviolet irradiation condition settings can be recorded from no0 to no19. Next, the irradiation mode is selected in step S1202. There are three types of irradiation modes U0 to 2, which specify the distinction between the batch manual irradiation mode, the individual manual irradiation mode, and the batch automatic irradiation mode. In addition, in this embodiment, the mode corresponding to an individual automatic irradiation mode is not employ | adopted. Next, in step S1203, the channel number which connected the head part 120 which sets the ultraviolet irradiation condition is selected. Here, four of channel numbers CH1 to 4 are selected.

Next, in step S1204, it is set whether or not ultraviolet ray output is permitted to the head portion 120 connected to the selected channel number. By allowing the head portion 120 to be allowed or denied to be irradiated with ultraviolet rays, it is possible to use it without outputting ultraviolet rays from all of the connected head portions 120 as in the prior art. If the output is permitted, the process proceeds to step S1205. If the output is not allowed, the process proceeds to step S1204-1 to determine whether or not the settings of all the head parts 120 are finished. If not, the process returns to step S1203. If the setting of the other head part 120 is continued, and the setting of all the head parts 120 is complete | finished, it jumps to process S1111.

In the case where a plurality of UVLEDs are provided as described later, permission / disallowment of ultraviolet irradiation can be set for each UVLED.                     

Next, it is determined whether or not the irradiation mode selected in step S1202 in step S1205 is an automatic mode. In the case of the automatic mode, the step number is selected in the next step S 1206. Up to 20 step numbers can be set from S0 to S19. If it is not in the automatic mode, the step number selection is unnecessary, so the process jumps to step S1207. In step Sl207, the irradiation time is set. Enter the number of seconds here. Next, the irradiation output is set in step S1208. In this case, the duty ratio is entered. Next, it is determined whether or not all necessary step number settings are completed in step S1209, and if not, the process returns to step S1206 to repeat the setting of the next step number. When it is finished, the process proceeds to step S1210 to determine whether or not the settings of all the head parts 120 have been completed. If not, the process returns to step S1203 and repeats the setting of the other head parts l20. In the case of having finished, the process proceeds to step S1211 where the above settings are stored in the storage unit 116 and terminated.

[Hierarchy menu]

Next, the display switching in the display unit 142 provided in the controller unit 110 will be described. In this embodiment, the hierarchical menu method is adopted. 13 shows an example of the hierarchical menu. As shown in this figure, the ultraviolet irradiation device can be switched between the irradiation mode and the setting mode, and various menu items can be further selected in each mode. In addition, various setting items may exist for the selected menu item, and as shown in the downward direction in FIG.

[Display in investigation mode]                     

Next, the display example of the display part 142 in irradiation mode is demonstrated based on FIG. In the irradiation mode, as shown in Fig. 14, items such as setting number display during operation, current timer value display, current irradiation power value display, cumulative irradiation time display, and the like are switched and displayed. The switching of items is performed by the left and right <,> switches 144A and 144B. In addition, when the escape switch 144E is pressed for a long time while displaying the top layer, the mode between the irradiation mode and the setting mode is changed as described above. On the other hand, when the escape switch 144E is pressed for a long time in a layer other than the top level, the state transitions to the top level layer of the mode.

(Display setting number during operation)

The setting number display during operation shows the setting number currently being selected. In this example, J0 is selected. The setting number can store up to 20 settings from no0 to J19, and an arbitrary setting number is selected therefrom. 14, the channel display lamp 145 provided below the display part 142 displays the head part 120 to which irradiation is set by the setting number currently displayed. Therefore, the user can easily determine which head portion 120 is irradiated with ultraviolet rays from the selected setting number. This example shows that the UVLED 15 is operated in all the head portions 120 of the channels 1-4.

The setting number is changed in the setting mode as described later in this embodiment. However, the setting number may be changed in the irradiation mode. For example, a method of pressing the enter switch 144F on the screen of FIG. 14 to move to the selection menu of the setting number, a method of changing the setting number by pressing the ∨, ∨ switches 144C, l44D on the screen of FIG. It can be adopted.

(Display current timer value)

The current timer value display indicates the irradiation time of ultraviolet rays. In the example of FIG. 1, it is shown that it is set to irradiate for 12 second from the head part 120 connected to the channel 1. As shown in FIG. When the ultraviolet irradiation condition setting of the corresponding setting number is executed, the remaining irradiation time is displayed as the number of seconds from the set irradiation time in a countdown manner, so that the user can easily know the remaining time. In the case of displaying a channel for which the irradiation time is not set, the elapsed time is displayed as the number of seconds by the count-up method when the channel is stopped. This allows the user to see how much time has elapsed. As described above, by automatically switching the time display method to the countdown type and the count up type according to the setting of irradiation time, the user can know whether the irradiation time is set, the elapsed time and the remaining time. It can be used conveniently for grasping. In addition to the number of seconds, the time display unit may appropriately adopt a display in the number of minutes, the number of hours, or the rate of progress.

In the example of FIG. 14, the irradiation time of the channel 1 is displayed, but when the X and Y switches 144C and 144D are pressed in this state, other channel information can be switched and displayed. As described above, in the present embodiment, the <and> switches 144A and 144B are used to switch menus, and the V and V switches 144C and 144D are used to select and change item values, respectively. In the example of FIG. 14, when the switch 144C is pressed, the channel 2 is switched in the order of 3 → 4 → 1. At the same time, the lighting of the channel display lamp 145 is switched to the channel so that it is possible to determine which item (in this case, the irradiation time) currently being displayed is the information of the head 120 connected to which channel. In addition, when information of a channel for which irradiation is not set is displayed, the display unit 142 is displayed as "---".

It is also possible to configure the channel information to be automatically switched and displayed sequentially without performing these switch operations.

(Display current survey power value)

The current irradiation power value display indicates the output value of the ultraviolet irradiation. In this example, the relative intensity is indicated by the percentage display of the drive current value of the UVLED of the channel 1, but the display by other units such as the percentage display with the maximum output of 100 or the number of output watts can be appropriately employed. . In this case, the information on the other channels can be switched and displayed by pressing the V and V switches 144C and l44D as described above.

(Display cumulative survey time)

The cumulative irradiation time display shows the cumulative value of the irradiation time of ultraviolet rays, that is, the total usage time of the UVLED. As a result, it is possible to obtain the target of how long the UVLED is used, to determine the lifespan and to adjust the driving current. Here again, the information of the other channels can be displayed by switching between the V and V switches 144C and 144D. In addition, in order to distinguish a unit in FIG. 14, display of "h" and "H" is distinguished, "h" has shown x10 hours, and "H" has shown x100 hours, respectively. In this way, the distinction between the uppercase and lowercase letters of the symbol causes the unit to be large or small, and thus a large amount of information can be displayed on a small display screen.

In the above, the display example of the display part l42 in irradiation mode was demonstrated. Of course, other display items may be added or configured to display only arbitrary items.

In the example of FIG. 13, in the irradiation mode, the menu item basically functions as the switching of the display unit 142, and thus no hierarchical structure is provided. Of course, the display items and the like may be switched in a hierarchical structure.

[Setting Mode]

Next, with reference to FIG. 15 and FIG. 16, the detail of the method of setting the ultraviolet irradiation condition in a setting mode is demonstrated. In the setting mode as shown in Fig. 15, four items of the setting number menu during operation, the setting editing menu, the communication condition menu, and other condition menus are switched by the? And? Switches 144A and 144B. The selection of the menu can be executed by pressing the enter switch 144F to enter the setting mode of the selected item. In addition, the escape switch 144E can be pressed to return to the upper layer.

Of course, a plurality of items may be integrated or other items may be added. For example, the communication condition menu and other condition menus may be combined into one, or the edit setting menu may be divided into two.

(Setting No. menu during operation)

The setting number menu during operation selects the setting number of the ultraviolet irradiation condition setting used in the irradiation mode. Here, among the ultraviolet irradiation condition settings that have already been set and stored, a desired setting number is selected by the ∧ and ∨ switches 144C and 144D. Pressing the enter position 144F after the selection, the display unit 142 displays &quot; End &quot; to save the selected setting number and return to the setting number menu during operation.

In the present embodiment, the setting number menu during operation and the setting editing menu to be described later are provided separately, but these may be integrated. In this case, the selected number is retained at the time of the last setting operation, and it is treated as if the setting of this number is selected in the irradiation mode.

(Edit Settings Menu)

The setting edit menu is a menu for setting ultraviolet irradiation conditions. The details of the setting editing menu are shown in FIG. Large items included in the setting editing menu include setting screens for selecting the editing setting number and selecting the irradiation mode. When the setting on each setting screen is completed and the enter switch 144F is pressed, the screen advances to the next setting screen.

(Select Edit Settings Number)

First, in the selection of the edit setting number, the setting number is selected. In the present embodiment, up to 20 settings can be saved from no0 to 19 as described above. Of course, more or less numbers can be set.

(Investigation mode selection)

Next, the irradiation mode is selected with respect to the selected setting number. As described above, the control mode selects one of three types U0 to 2, that is, a batch manual irradiation mode, an individual manual irradiation mode, and a batch automatic irradiation mode. When the irradiation mode is selected and the enter switch 144F is pressed, "End" is displayed on the display unit 142, and the above setting is temporarily saved, and the editing channel selection is made at the same time.

In the editing channel selection, the channel number to which the head 120 to be set is connected is selected from CH1 to CH4. Next, the process proceeds to the output permission selection and selects whether to permit the ultraviolet output to the head portion 20 of the channel number selected above. In the case of permission, "on" is displayed. In the case of permission, "off" is displayed on the display unit 142. Pressing the enter switch 144F in this state proceeds to the step number selection screen or the step number selection not possible display according to the irradiation mode selected as the irradiation mode selection screen.

(Detailed setting of the batch auto investigation mode)

When the batch automatic irradiation mode is selected on the irradiation mode selection screen, the flow advances to the step number selection screen and the step number is selected. As described above, up to 20 step numbers can be set from S0 to 19, and the number of steps is set in order. When the step number is selected, the irradiation time setting screen is displayed and the ultraviolet irradiation time is input. Then enter the survey output as well. These input values are increased or decreased by the? And? Switches 144C and 144D. For convenience of input, the previous setting value may be copied and input as an initial value, or pressed and held for high speed. When the above setting is completed, pressing enter switch 144F temporarily saves the setting and returns to the step number selection screen. At this time, the value which increased 1 to the set step number is input as an initial value. When the setting of all the step numbers is completed, pressing the escape switch 144E returns to the edit setting number selection screen.

(Detailed setting of batch manual survey mode and individual manual survey mode)                     

On the other hand, when the batch manual irradiation mode or the individual manual irradiation mode is selected on the irradiation mode selection screen, the step number cannot be selected on the output permission selection screen because the output becomes a constant value and the step for changing the output cannot be selected. Proceed to At this time, the display portion 42 shows "s .---" to indicate that the step number cannot be selected. Since the irradiation time is not set in the manual irradiation mode, pressing the enter switch 144F in this state brings up the irradiation output setting screen. As described above, when the output switch is set to the duty ratio and the enter switch 144F is pressed, the setting is saved and the screen returns to the edit channel number selection screen. The ultraviolet irradiation condition is set in the edit setting menu as described above.

(Communication condition menu)

In the communication condition menu, set the communication condition when connecting the ultraviolet irradiation device and the external connected device through the RS-232C interface. In the example of FIG. 15, baud rate selection, stop bit parity selection, and delimiter checksum selection can be set from the communication condition menu. When the setting on each setting screen is completed and the enter switch 144F is pressed, the screen advances to the next setting screen. First, in the baud rate selection, the? And? Switches 144C and 144D are selected from the preset 1200 bps, 2400 bps, 4800 bps, 9600 bps, 19200 bps, and 38400 bps, and are determined by the enter switch 144F. In the display unit 142, the number of display digits is saved by displaying "b.384" and the like at x100. Moreover, if it supports by hardware, you may set the baud rate value of that excepting the above.

In the stop bit parity selection, the stop fit is 1 or 2, there is no parity, and even and odd numbers can be selected respectively. In the example of FIG., A combination of these is presented as a choice in advance, and there is no stop bit 1 parity (display "y.1 n" on the display unit 142), a stop bit 1 parity even number (y.lE), and a stop bit. 1 parity odd ("y.1o"), stop bit 2, no parity ("y.2n"), stop bit 2 parity even ("y.2E"), stop bit 2 parity odd ("y 2o &quot;) from among the 에서 and ∨ switches 144C and 144D to determine the enter switch 144F.

Similarly, in the delimiter checksum selection, CR or ETX and checksums can be selected as delimiters, respectively. In the example shown in Fig. 1, these combinations eliminate the delimiter CR checksum (display "d.C0" on the display unit 142), the delimiter CR checksum ("d.C1"), and the delimiter ETX checksum (" d.E0 &quot;) and delimiter ETX checksum (&quot; d.E1 &quot;) as the? and? switches 144C and 144D, and are determined by the enter switch 144F.

(Other Conditions menu)

Input condition selection and lighting alarm time edit can be set in other condition menu. Input contact selection sets the delay time to prevent chattering, such as when a foot switch is connected. The lighting alarm time edit sets a time for giving a warning due to deterioration of the UVLED.

The structure of the hierarchical menu described above is an example, and other structures may be appropriately employed. For example, although the horizontal direction switch was used for the menu selection and the vertical direction switch was used for setting the selected item, the horizontal direction and the vertical direction may be exchanged.

[Embodiment 2]                     

In addition to the configuration having the setting unit in common as in the first embodiment, an individual setting switch 290 and an individual display unit 292 may be provided for each head unit. 17 is a front view of the controller unit 210 of the ultraviolet irradiation device according to Embodiment 2 of the present invention. The individual setting switch 290 shown in this figure is used for setting the ultraviolet-ray output irradiated from each head part, and increasing or decreasing irradiation time, and an up-down switch etc. can be used. In this embodiment, ultraviolet irradiation conditions for each channel can be set by the individual setting switch 290, and ultraviolet irradiation conditions can also be set using the operation panel 244 described above. It is also possible to omit the common operation panel and to set only the individual setting switch 290.

The individual display unit 292 can use a seven segment indicator or the like to display the set output or irradiation time. In addition, only the individual setting switch 290 or the individual display portion 292 may be provided for each channel.

[Embodiment 3]

In addition, the individual setting switch or the individual irradiation switch for adjusting the ultraviolet output of each head part may be provided in the head part 120 instead of the controller part 1010. 18-19 shows the head part 320 of the ultraviolet irradiation device which concerns on Embodiment 3 of this invention. As shown in these figures, the individual irradiation switch 380 for turning on / off the ultraviolet irradiation from the UVLED 350 to the head 320, and the individual setting switch 390 for adjusting the output level of the ultraviolet ray. Install it. Individual setting switch 390 may use an up-down switch consisting of two push switches. As shown in Fig. 18B and 19, these switches are mounted on a substrate. The other member can use the structure like FIG. 3 mentioned above. This configuration can be suitably used in this form because the user can adjust the output in the range of the hand when the user grips the head 320 by hand.

In addition, although not shown in figure, individual display parts, such as a 7 segment indicator, can also be provided in a head part, respectively. Alternatively, only the individual setting switch or the individual irradiation switch may be provided in the head portion, and the remaining members may be provided on the controller portion side.

 [Embodiment 4]

In each of the above embodiments, the direction in which the cable portion and the ultraviolet rays are irradiated is substantially straight along the longitudinal direction of the head portion (straight type). On the other hand, the head part 420 of the ultraviolet irradiation device which concerns on Embodiment 4 of this invention shown in FIG. 20 is the angle type comprised so that the ultraviolet irradiation direction from the UVLED 450 may be substantially orthogonal to the longitudinal direction of the head part 420. FIG. I make a type. 20 is a plan view and a cross-sectional view of the head portion 420, and FIG. 21 is a perspective view illustrating an example of a supporting method of the head portion 420. FIG. As shown in these figures, the head main body 422 and the lens holder 426 are angularly coupled through the cooling block 424 to form an angle head 420.

As shown in FIG. 21, in the angle type head part 420 of Embodiment 4, the holder 4202 holding the head main body part 422 can be provided, and the head part 420 can be fixed by this. . In this case, a margin arises in the upper space of the head part 420. That is, when fixing the head part 420 to a facility, it is suitable for the case where it is difficult to ensure sufficient space above the head part 420 by facility relationship. Moreover, the visibility when observing the object (point) of ultraviolet irradiation from the upper side over the head part 420 is excellent.

On the other hand, an example of the supporting method of the head type 120 of the straight type in Embodiments 1-3 mentioned above is shown in FIG. In the example of FIG. 22A, the head 120 is fixed by holding the pawl member 1201 fixed to the back of the head main body 122 at approximately right angles by screwing with a holder 1202. In the example of FIG. 22 (b), by using the two screw holes formed in the back surface of the head main-body part 122, it is prevented from directly turning by the fixing screw 1203 to the fixing object H, such as a wall surface. In either case, a space for the cable part 130 is required above the head part 120. In the case of the angle type head part 120 of Embodiment 4 shown in FIG. 20, FIG. 21, since the cable part 130 extends to the side, a problem does not arise even if there is no space in the upper space of the head part 420. FIG. Do not.

[Embodiment 5]

In each of the embodiments described above, as shown in FIG. 3 and the like, each head portion is provided with one UVLED. However, a plurality of semiconductor elements may be provided in the head portion 520. By using a some semiconductor element, it becomes possible to adjust the irradiation amount and irradiation area of an ultraviolet-ray as needed. 23 shows a head portion 520 including a plurality of UVLEDs 550 in the ultraviolet irradiation device according to Embodiment 5 of the present invention. FIG. 23A shows an example in which 12 UVLEDs 550A are arranged approximately uniformly on the bottom of the columnar cooling block. FIG. 23 (b) shows an example in which three rows x three columns = nine UVLEDs 550B are arranged in a substantially square cooling block. Of course, the UVLEDs 550 may be arranged in l rows or two rows, or may be arranged in four or more rows. FIG. 23C shows an example in which two rows x three columns = six UVLEDs 550C are disposed in a substantially rectangular cooling block extending in one direction. In the structure of this example, ultraviolet rays can be cured by irradiating a resin applied to a thin and long region by a plurality of UVLEDs 550C lined in the longitudinal direction at once.

Of course, the number and arrangement pattern of UVLEDs and the like can be suitably employed. By simultaneously turning on and using a plurality of UVLEDs, output can be increased by increasing the amount of ultraviolet rays. In addition, by switching only the specific UVLEDs among the plurality of UVLEDs and turning the other UVLEDs off, the UVLEDs are alternately used to avoid the continuous use of specific UVLEDs, thereby prolonging the lifespan of each device. Can be extended. In addition, it is possible to determine whether each UVLED or all UVLEDs have reached the end of their lifespan and to warn the user by prompting a user with a message, an indication or a voice. In addition to the deterioration caused by the lifetime, the output of semiconductor devices such as UVLEDs may become unstable or inoperable even due to poor electrical contact or disconnection. For this reason, you may add the disconnection detection function which monitors the energized state of electric current, and issues a warning when it does not energize. Alternatively, a malfunction of the driving circuit system can be detected based on the electrical state of the input terminal and the output terminal of the driving element such as the semiconductor element. Thereby, the problem by electrical contact can be detected easily, and the installation or maintenance work of an ultraviolet irradiation device can be made easy.

28 shows an example of a circuit for realizing the disconnection detecting function. In this circuit example, the abnormality is detected based on the drive signal and the output of the UVLED 650, which is a semiconductor element. Specifically, it determines whether it is abnormal or normal by the combination of the input of the drive signal which drives the UVLED 650, and the output side of the drive circuit 618. As shown in FIG. The circuit shown in FIG. 28 connects the transistor Tr as the UVLED 650 and its driving circuit 618. An input terminal of a trigger signal for instructing the start of ultraviolet irradiation is connected to the base (point A in FIG. 28) of the transistor Tr, the collector is connected to the cathode of the UVLED 650, and the emitter (point B) is loaded. Grounded via resistor R. In addition, an alarm output terminal indicating an abnormality is connected to the exclusive logical sum circuit 619 of the A point and the B point. By this wiring, when the signal levels of the input signal (point A) of the driving current of the UVLED 650 and the voltage (point B) between both ends of the load resistor R are detected by the exclusive OR circuit 619, the drive is driven. It is possible to detect two problems that the UVLED 650 is lit even though the UVLED 650 does not light up when the signal is input or the drive signal is not input. When the point A and the point B are both high, the driving signal is input and the UVLED 650 is turned on. When the point A and the point B are both low, the driving signal is not input and the UVLED 65O is turned off. In either case, the alarm output does not detect any abnormality in the LOW mode. On the other hand, if the A point is HlGH and the B point is LOW, the driving signal is input, but the UVLED 650 is turned off. On the contrary, if the A point is LOW and the B point is HIGH, the driving signal is not input, but the UVLED 650 is turned on. All of them become abnormal operation. In this case, the alarm output goes HIGH and an abnormality is detected so that a predetermined abnormality notification operation is executed. As the above notification means, for example, a method of displaying a message on a display unit of a controller unit, a visual means of installing a dedicated display unit or lamp for notifying a change in a flashing pattern or a change in color or an abnormality detection, or in addition to an alarm, a warning sound, or a voice map. A method for appealing to the hearing such as notification by using, a physical and mechanical notification means by vibrating the head portion including the semiconductor element, and the like can be suitably used. In addition, the controller unit may transmit a warning signal to the outside to cause the external connection device to perform a predetermined operation such as a warning display. In this figure, although the UVLED 650 and the driving circuit 618 are shown in close proximity for explanation, the driving circuit 6l8 is actually embedded in the controller portion, and the UVLED 650 is embedded in the head portion. It is electrically connected in the negative.

In addition, in the case of providing a plurality of UVLEDs having the same characteristics, UVLEDs having different characteristics may be provided in the same head portion. For example, by changing and using UVLEDs having different wavelengths, it is possible to change the wavelength of ultraviolet rays that can be irradiated from the same head portion. In the case of using UVLEDs having different characteristics, the drive current or the like corresponding to each UVLED is set in advance on the head side. In addition, of course, it is also possible to provide UVhead of a different characteristic between each head part.

In the case where a plurality of semiconductor elements are provided in the head portion 520, elements to be turned on must be distinguished from others, and element identification information such as individual ID numbers is assigned to each semiconductor element. When the ultraviolet irradiation condition is set, element identification information of which element is to be turned on is also set. When the plurality of semiconductor elements are turned on, setting copying may be made possible so that the same setting can be easily performed on these semiconductor elements. The object of copying is not limited to the same head portion, but may be between different head portions or between different ultraviolet irradiation devices. For example, a setting copy screen is displayed on the transition screen, and the head number of the copy source and the head number of the copy destination are displayed. Specify. Moreover, it is also possible to copy the conditions set by one head part to all head parts. For example, "A" indicating all is specified instead of the number assigned to the head as a copy destination. Alternatively, you can save the condition set in another head and call it. In this way, the ultraviolet irradiation condition set by one head part can be easily copied to another head part, and the labor of a setting operation can be simplified. In addition, when all the elements are turned ON in one setting, "all" can be designated as element identification information. For example, enter "A" on the setting screen. This saves the trouble of setting the same ultraviolet irradiation conditions for each element. Moreover, of course, it is also possible to irradiate an ultraviolet-ray by changing a current value with some semiconductor element.

Here, an example of a setting copy function for copying a condition set in the edit setting menu will be described with reference to FIG. FIG. 29 is a state transition diagram illustrating a modification of the hierarchical menu in the setting mode of FIG. 15. In the example of FIG. 29, as a menu selectable from the setting menu, a setting copy menu is added to the setting number menu, the setting editing menu, and the like during operation of FIG. 15. In this example, the display shows "copy" when the setting copy menu is selected. Selecting and executing the Copy Settings menu brings up the Edit Setting Number Selection screen, and the user selects an Edit Setting Number that preserves the desired setting. If the edit setting number is specified numerically and executed, the screen returns to the channel number selection screen of the copy source. In this example, "Org" indicating the original of the copy source is displayed on the screen. In this screen, the user specifies numerically the channel number of the head portion in which the condition to be copied is preset. When the copy source is determined, the copy destination channel number selection screen is displayed next. In this example, &quot; dst &quot; indicating the destination of the copy destination is displayed on the screen, and the head channel number of the other party to be copied in the same manner is designated numerically. If you want to copy settings for all channels other than one channel as the copy destination, specify "A" or the like indicating all for the channel number. When copying is executed, "End" is displayed on the screen indicating that copying has been determined, and the screen returns to the top of the setting copy menu. Other menu screens such as the setting number menu during operation, the setting editing menu, the communication condition menu, and other condition menus are the same as in FIG. In this example, only copies of the same edit setting number can be copied, but copying over the edit setting number can be configured. In this case, the edit setting number containing the setting of the copy source and the edit setting number containing the setting of the copy destination are specified.

Next, the setting method of the ultraviolet irradiation condition when the head part 520 is equipped with the some UVLED 550 is demonstrated based on FIG. In FIG. 24, the head part 520 number selection step of step S2401 and the step number selection step of step S2402 are the same as those of step S1001 and step S1002 of FIG. Next, in step S 2402-1, the number of the UVLED 550 to be operated is selected. As described above, a plurality of UVLEDs 550 provided in the head unit 520 are previously given a unique ID number, and a number of UVLEDs 550 to be driven is selected. The following process S is the same as that of the process S1003, S1004, S1005 of FIG.

[Embodiment 6]

In addition, the setting of ultraviolet irradiation conditions can select a preset irradiation pattern other than the method of designating the irradiation time and the group of irradiation output to step type as mentioned above. For example, a method of selecting a functional irradiation pattern or an integer of a further selected function may be input. In these settings, a method of specifying and selecting a function number or an integer by a numerical value, and the method of graphically displaying and selecting a graph figure can be adopted. In addition, even in the former method of selecting by the numerical value, the set function may be confirmed in a graph. In order to enable such a graph display, a display unit 142 capable of displaying a figure is prepared.

[Function Survey Pattern]

25 is a graph showing an example of three patterns representing a function of irradiation time and irradiation output of ultraviolet rays as a function. Even with the pattern as shown in this figure, embodiment of this invention can irradiate an ultraviolet-ray. In the example of FIG. 25, three types of F1-F3 are shown as an example of a function.

F1: P-at + c

F2: P = a * (1-EXP (-b * t)) + c

F3: P = a * (EXP (b * t) -1) + c

(a, b, c are integers set according to conditions)

In addition to these, an n-order function can also be used. After selecting any one of the above functions, setting the constants a, b, and c determines the irradiation pattern. The constant is set in accordance with the conditions for use of the ultraviolet irradiation device. In the functions F1 to F3 illustrated in FIG. 25, the following values are set as constants set when the irradiation output of ultraviolet rays is raised to 70% in 10 seconds of irradiation time.

Fl: P = 71 (a = 7, c = 0)

F2: P = 70 * (1-EXP (-0.5 * t)) (a = 70, b = 0.5, c = 0)

F3: P = 10 * (EXP (0.21 * t) -1) (a = l0, b = 0.21, c = 0)

The procedure for setting the ultraviolet irradiation conditions in the irradiation pattern as in FIG. 25 will be described based on FIG. 26. First, the process of selecting the head number in step S2601 and the step number in step S2602 is the same as in FIG. 10. Next, the function number is selected in step S2602-1. Here, F0 to F3 described above can be selected as options of the function F. F = 0 is a stepped function for inputting irradiation time and irradiation output as described above. When F = 0 is selected in step S2602-l, irradiation time is input in step S2603 and irradiation output in step S2604, respectively, and the setting is saved in step S2605. When F = 1 is selected in step S2602-1, the constant a is input in step S2603-l and the constant b in step S2604-1, respectively, and the setting is saved in step S2605. When F = 2 or 3 is selected in step S2602-1, the constants a in step S2603-2 and the constants b and c are entered in step S2604-2, respectively, and the settings are saved in step S2605.

In addition to the above, as a method of setting the irradiation pattern, for example, after selecting the waveform of the irradiation pattern, inputting the irradiation time, automatically calculating the constant of the function, setting the method, setting the total irradiation amount or heat amount of ultraviolet rays, etc. Can be used as appropriate.

In the conventional ultraviolet irradiation device, since the output was changed by a mechanical shutter such as a high-pressure mercury lamp used as an ultraviolet light source, the minimum resolution of the ultraviolet output became coarse, resulting in a discrete change, and fine adjustment was not possible. The change was very difficult. In contrast, according to the present embodiment using the semiconductor element having a high linearity with respect to the drive current, an almost continuous output change is realized by adjusting the input current. Since the output can be changed linearly according to the drive current, the above pattern can also be supported. In addition, the approximation of the ultraviolet output and the continuous waveform also depends on the resolution of the A / D converter.

[Embodiment 7]

In each of the embodiments described above, setting of the ultraviolet irradiation condition is performed by the setting unit of the controller unit. However, setting of ultraviolet irradiation conditions can also be performed by the apparatus externally connected to an ultraviolet irradiation device. For example, in the seventh embodiment of the present invention, as shown in FIG. 27, the controller unit 710 of the ultraviolet irradiation device 700 is connected to an external connection device 7101 such as a computer or a PLC to connect the external connection device 7101. The ultraviolet irradiation condition set at the side is set to be transmitted to the controller unit 110.

The ultraviolet irradiation device 700 is provided with the interface for connecting with the external connection apparatus 7101. The interface is connected to the control unit 714 of the controller unit 710 so that the control unit 714 exchanges electrical signals or data communication with the external connection device 7101. The external connection device 710l and the ultraviolet irradiation device 700 may be connected in series, parallel, or 10BASE-T, 100BASE-TX, 1000BASE-T, or the like such as RS-232x, RS-422, USB, or IEEE1394. It can be electrically connected and communicated through a network. The connection is not limited to a physical connection using a wire, but may be a wireless connection using a wireless LAN such as IEEE802.11x or OFDM, or a radio wave such as Bluetooth, infrared, optical communication, or the like. In addition, setting information can be stored and read out through the recording medium. As the recording medium, a memory card, a magnetic disk, an optical disk, a magneto-optical disk, a semiconductor memory, or the like can be used.

The ultraviolet irradiation device, the setting method of ultraviolet irradiation conditions, and the ultraviolet irradiation method of this invention can be used suitably for adhesion | attachment with an ultraviolet curable resin in the assembly work of electronic components, such as a pickup. In particular, since the ultraviolet irradiation conditions can be set independently for each of the head portions to be irradiated with ultraviolet rays, for example, a plurality of users each use a head portion connected to the same ultraviolet irradiation device or use the same adhesive using an ultraviolet curing resin having a different curing time. It can be performed by an ultraviolet irradiation device.

According to the ultraviolet irradiation device, the setting method of the ultraviolet irradiation conditions, and the ultraviolet irradiation method of this invention, the ultraviolet irradiation device of a small power consumption can be realized by using a semiconductor element for an ultraviolet source. In particular, unlike high-pressure mercury lamps or mercury xenon lamps, semiconductor devices can be turned on only when necessary without always being turned on, so that power consumption can be suppressed, and the life of the devices themselves can also be used for a long time. In particular, the present invention makes it possible to individually set the ultraviolet output of each head by providing semiconductor elements in each of the plurality of head portions. Accordingly, each head portion can be used independently, and an excellent advantage can be obtained by irradiating a plurality of ultraviolet rays under different ultraviolet irradiation conditions using one ultraviolet irradiation device.

In particular, in an ultraviolet irradiation device having a plurality of irradiation modes, it becomes easier to select and use an irradiation pattern according to the purpose of use, and thus, ultraviolet irradiation adapted to various situations from the use of only one head portion to the use of a plurality of head portions. Is realized.

Claims (29)

An ultraviolet irradiation device for irradiating ultraviolet rays for curing the ultraviolet curable resin, A plurality of head portions 120 including at least one semiconductor element capable of irradiating ultraviolet rays as an ultraviolet source, A setting unit 140 for individually setting ultraviolet irradiation conditions for each head unit 120, A controller unit 110 including a power supply unit 112 for supplying a driving current to the semiconductor device; A cable part 130 having an electrical signal line for electrically connecting the head part 120 and the controller part 110; Irradiation mode for irradiating ultraviolet rays from each head portion, wherein the ultraviolet output value can be adjusted for each head portion, and a manual mode for switching on / off of ultraviolet irradiation at a specified timing, and irradiation output and And / or the irradiation time can be changed, and upon receiving the irradiation start instruction, the irradiation mode is started in advance with the irradiation pattern registered for each head unit 120, and after the termination, the automatic mode for switching the automatic mode that automatically stops the ultraviolet irradiation is switched. Way Ultraviolet irradiation device comprising a. The ultraviolet irradiation device according to claim 1, further comprising a batch irradiation switch (148) for executing a batch irradiation mode for irradiating ultraviolet rays from all heads (120). The ultraviolet irradiation apparatus according to claim 1, further comprising an individual irradiation switch (180) for each head portion for executing an individual irradiation mode for irradiating ultraviolet rays for each head portion (120). A head unit 120 including an ultraviolet light emitting diode as an ultraviolet irradiation source, Controller unit 110 capable of connecting a plurality of the head unit 120 An ultraviolet irradiation device having: And assigning and preserving a plurality of ultraviolet irradiation condition settings that can be used in the irradiation mode in advance, and allocating means for selecting and assigning setting numbers of the plurality of ultraviolet irradiation condition settings for each of the head units 120. UV irradiation device. The method of claim 4, wherein the ultraviolet irradiation condition setting, An ultraviolet irradiation device, characterized in that it is an irradiation pattern for changing a stepped form by combining a plurality of square waves composed of a combination of constant irradiation output and irradiation time. The method according to claim 4 or 5, As irradiation mode, A manual mode in which the ultraviolet output value can be adjusted for each head unit 120, and the ON / OFF of the ultraviolet irradiation is switched at a specified timing; Irradiation output and / or irradiation time can be changed in accordance with preset ultraviolet irradiation conditions, and upon receiving an irradiation start command, irradiation is started in advance with the irradiation pattern registered for each head unit 120, and automatically after the completion of irradiation An ultraviolet irradiation device, characterized in that the switch is configured to switch the automatic mode to stop. The method of claim 5, The irradiation mode further comprises a batch irradiation mode for irradiating ultraviolet rays from all the head portion 120 and an individual irradiation mode for irradiating ultraviolet rays from one head portion (120). The method according to any one of claims 1, 2, 3, 4, 5 or 7, The controller unit 110 includes a display unit 142 capable of displaying a figure, and is configured to display a preset irradiation pattern in a graph form on the display unit 142 so as to be selectable. The method according to any one of claims 1, 2, 3, 4, 5 or 7, Ultraviolet, characterized in that the controller unit 110 includes a memory unit 1227 for storing the integrated value of the driving time of the UVLED 150 of each head unit 120 and the channel number of the head unit 120 Probe device. The method of claim 8, The display unit 142 is configured to switch between the display of the irradiation mode for irradiating ultraviolet rays and the display of the setting mode for setting the ultraviolet irradiation conditions. The method of claim 8, When the display of the display unit (142) is in the irradiation mode, the elapsed time from the start of the ultraviolet irradiation can be displayed in a countdown formula. The method of claim 8, And a display means capable of displaying a channel number of information displayed in the irradiation mode when the display of the display unit 142 is in the irradiation mode. The method of claim 8, And a display for grasping the life of the UVLED (150) when the display of the display unit (142) is in the irradiation mode. The method of claim 13, Wherein the life indication of the UVLED (150) has a cumulative irradiation time indication for displaying a cumulative value of the UV irradiation time of the UVLED (150). The method according to any one of claims 1, 2, 3, 4, 5 or 7, The display of the setting mode includes a setting editing menu for setting the irradiation conditions. The method of claim 1, A memory unit is provided in each of the plurality of head units, and the controller unit integrates the driving time of the semiconductor elements of each head unit, and updates the stored value of the driving time in the memory unit of the head unit. . The method of claim 16, The controller unit reads the integrated value of the driving time of the semiconductor element of each head unit stored in the memory unit of each head unit to be connected, and notifies the outside when the accumulated value of the read driving time exceeds the predetermined accumulated time. Ultraviolet irradiation apparatus characterized by having a notification means. delete delete delete delete delete delete delete delete delete delete delete delete

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