JPH06143678A - Optical printing head and manufacture thereof - Google Patents

Abstract

PURPOSE:To obtain an inexpensive optical printing head which prevents the deterioration of the efficiency, improves the production yield and conforming with the mass production. CONSTITUTION:The manufacture includes a process to align light emitting diode array chips 14 having a plurality of light emitting diodes 17 formed linearly, a process to seal the arranged light emitting diode array chips 14 by a first light-permeable insulating resin 15, a process to set the first light-permeable insulating resin, and a process to grind an electrode part 18 or a metallic projecting part 19 of the light emitting diode array chip 14 to be parallel to the surface of the chip where the light emitting diodes are formed so as to bring the part 18 or 19 in touch with the free space. Moreover, the manufacture has a process to form a circuit conductor layer 13 on the surface where the electrode 18 or metallic protrusion 19 is exposed to the free space, and a process wherein a second light-permeable insulating resin 16 is applied onto the surface where an end face of an optical fiber 12 of an optical fiber array substrate obtained by passing and burying the optical fiber 12 in a base glass 11 in the thicknesswise direction is exposed, and set after the optical fiber array substrate is turned facedown.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical print head for converting an electric signal into an optical image using an optical fiber array substrate for transmitting a one-dimensional optical image, and is suitable for an electrophotographic printer, a digital copying machine and the like. The present invention relates to an optical print head that records an image in the width direction of a recording medium in close proximity to or in close contact with an optical recording paper or an electrophotographic photosensitive member, and a method for manufacturing the same.

[0002]

2. Description of the Related Art In recent years, an optical print head used as a writing light source for a non-impact printer has been developed and is becoming popular.

In an optical print head for converting this one-dimensional image information into an image from an electric signal, one light beam emitted from a gas laser or a semiconductor laser is modulated by an optical modulator, and a rotary polygon mirror is used to form an electrophotographic photosensitive member. A head that uses an electrophotographic photosensitive member with a selfoc lens array that emits a plurality of light beams emitted from a head that irradiates upwards and a long light emitting diode array in which a plurality of light emitting diode array chips are linearly mounted is commercialized. . Among them, the latter optical print head using a long light emitting diode array has a high light quantity and is capable of parallel writing, or has a feature that an optical system can be designed small. It is applied to facsimiles.

As a head using the light emitting diode array, there has been proposed an optical print head using an optical fiber array substrate, which does not use an optical lens, in addition to a head using a converging rod lens array which is an equal magnification optical lens. (JP-A-55-98879). The latter optical print head does not require a converging rod lens array, so that it is easier to downsize the device, and it is inexpensive.

Conventionally, optical fiber arrays have been used as a means of transmitting image information. Such an optical fiber array is shown in FIG. 6C as means for removing light having an angle larger than the incident angle corresponding to its numerical aperture (NA) in order to prevent crosstalk of transmitted optical image information. As described above, the optical fiber is used in which the clad 65 having a small refractive index is formed around the core 64 of the optical fiber, and the light absorber layer 66 is further formed around the clad 65. To obtain an optical fiber array substrate in which a large number of optical fibers are embedded in a glass substrate, a large number of optical fibers are individually sandwiched between base materials such as base glass, or a plurality of optical fibers 63 are provided as shown in FIG. 6B. Optical fiber bundle 6
2 was formed, stacked in three rows, sandwiched between base materials such as base glass 61, pressed, heated, and melted to form the optical fiber array substrate shown in FIG. 6 (a).

An example of a conventional optical print head will be described below. FIG. 3A is a sectional structural view of a conventional optical print head in a light emitting diode array chip arrangement direction. FIG. 3B is a cross-sectional view of a conventional optical print head in a direction orthogonal to the light emitting diode array chip arrangement direction. In FIGS. 3A and 3B, 31 is a base glass, 32 is an optical fiber, and a circuit conductor layer 33 is formed thereon. Reference numeral 34 is a light-emitting diode array chip, 35 is a light-emitting diode, and 36 is an electrode, which is flip-chip mounted at a predetermined position on the circuit conductor layer 33 via a transparent insulating resin 37.

The operation of the optical print head constructed as described above will be described below with reference to FIGS. 3 and 4. FIG. 4 is a sectional configuration diagram of a conventional optical print head unit. Reference numeral 41 denotes a chassis in which a conventional optical print head is incorporated, and an electrophotographic photosensitive member 42 is arranged in the vicinity thereof. An organic photoconductor (OPC), an amorphous silicon photoconductor, or the like is used as the electrophotographic photoconductor. In the optical print head, the light emitting diode 35 is driven by the signal current flowing through the circuit conductor layer 33.
Light having a wavelength corresponding to the energy gap of the substance forming the light emitting diode is radiated and is incident on the optical fiber. Of these, the light 43 incident on the optical fiber at an angle i smaller than the angle corresponding to the numerical aperture NA of the optical fiber is transmitted through the optical fiber after repeating complete reflection, and is emitted from the other end face of the optical fiber array substrate. , A predetermined position on the electrophotographic photosensitive member 52 is irradiated to draw a latent image in the electrophotographic process. On the other hand, the light 44 incident on the optical fiber at an angle i ′ larger than the angle corresponding to the numerical aperture NA of the optical fiber penetrates the optical fiber and is transmitted between the optical fibers one after another. However, since the light absorber layer is provided on the outermost periphery of the optical fiber and the light transmitted between the optical fibers is absorbed in this way, it penetrates the optical fiber array substrate and reaches the electrophotographic photosensitive member 42. Never reach.

Next, a conventional method for manufacturing an optical print head
This will be described below with reference to FIG. Figure 5 shows conventional light
6A and 6B are a perspective view and a structural view showing a method for manufacturing the print head.
It First, using a semiconductor process, a single crystal III-V group
On the conductor substrate (wafer), such as light emitting diode and bump
Make one with electrodes. If necessary, on the electrode part 33
As the metal projection electrode portion 38, several μm is formed by a plating method or the like.
Form a structure that protrudes from the wafer surface by about 20 μm
It After that, this wafer is cut by high-precision dicing technology.
Cut off and make a light emitting diode array chip. Optical fiber
The array substrate is the optical fiber of FIGS. 6 (a), (b) and (c).
Bar array substrate 63 has a core diameter of 10 to 25 μm
(Here, 20 μm) Optical fiber with numerical aperture NA = 0.57
Formed in Ba. Each core 64 has a thickness of about 2 μm
The clad 65 and the light absorber layer 66 with a thickness of about 2 μm
It is covered. Collecting multiple optical fibers like this
The optical fiber bundle 62 is formed. Next, the thermal expansion of the optical fiber
Between the base glass 61, which has almost the same characteristics as the coefficient
, Stack the optical fiber bundles 62 in three rows and sandwich them.
It is placed in a container and is heated and pressurized to melt and integrate. This
Therefore, the optical fiber bundle, which was initially circular, was deformed and
A shape such as a polygon or a hexagon is shown. This light phi
Place the LED array chip on the array substrate
Thick film printing technology or vapor deposition and photo-etching on the first main surface.
5 to form the circuit conductor layer 33 using the etching technique.
(A). Next, on this substrate, an acrylate-based transparent photocurable
Of chemical-type insulating resin 37 by stamping method or screen printing method
Etc., apply a predetermined amount, and then light-emitting diode array chip
Electrode 34 or metal protrusion 38 is a circuit conductor.
Feet one chip at a time so that it contacts the predetermined position of the layer 33.
Place down (Fig. 5b) ₁~ B₂). Then this
The light emitting diode array chip 34 is attached to the metal collet 5
1, while applying pressure from above, transparent photo-curing insulating resin
37 through the optical fiber array substrate, the ultraviolet lamp 52
To irradiate ultraviolet rays 53 to cure and complete mounting
5 (c).

[0009]

However, in the manufacturing process as described above, the light emitting diode array chip is aligned at a predetermined position on the optical fiber array substrate.
Since chips are arranged one by one, the number of manufacturing steps is very high, and there is a problem that mass productivity is poor. Also, after moving the next chip to the immediate vicinity of the already mounted chip,
If it is not placed with strict position accuracy, it is placed at a predetermined position, and the next chip will ride on the previous chip, or it will hit and crack, causing not only poor performance but also process yield. It was a cause of drastically lowering. For this reason, in the conventional optical print head manufactured by such a manufacturing method, not only is there a limit to increasing the process yield, but it is also difficult to increase the productivity, and such a method makes it possible to mass-produce at low cost. It has been difficult to provide optical print heads for.

In view of the above problems, according to the present invention, after mounting the light emitting diode array chips one by one without mounting them in an array, the circuit conductor layers are directly and collectively mounted on the electrodes or the metal protrusions of the light emitting diode array chips. Formable,
An optical print head having high productivity and a manufacturing method thereof are provided.

[0011]

In order to solve the above-mentioned problems, the optical print head of the present invention has a first light-transmitting portion such that only the electrode portion or the metal projection portion formed on the electrode portion is in contact with the free space. Light emitting diode array chips linearly embedded in a transparent insulating resin, and a plurality of circuit conductor layers formed on the surface of the transparent insulating resin so as to be connected to the electrode portions or the metal protrusions. And an optical print head having a plurality of optical fibers penetrating and embedded in the thickness direction of the base glass, wherein the light emitting diodes of the light emitting diode array chip are end faces of the optical fibers of the optical fiber array substrate. The optical print head is arranged face down on the exposed main surface with the second translucent insulating resin interposed therebetween.

In order to solve the above problems, the method of manufacturing an optical print head according to the present invention includes a step of linearly arranging a plurality of light emitting diode array chips each having a plurality of light emitting diodes formed in a linear shape, and an array of the arranged light emitting diode arrays. A step of encapsulating the chip with a first translucent insulating resin; a step of curing the first transmissive insulating resin; and an electrode portion of the light emitting diode array chip or a metal projection portion formed on the electrode. The step of polishing parallel to the chip surface of the light emitting diode array chip on which the light emitting diode is formed so as to be in contact with the free space, and the circuit conductor layer on the surface where the electrode or the metal projection on the electrode is exposed in the free space. And a light emitting diode array chip coated with the first translucent insulating resin on which the circuit conductor layer is formed, and a plurality of optical fibers as a base. A step of applying the second light-transmissive insulating resin at a predetermined position on the main surface where the end surface of the optical fiber of the optical fiber array substrate embedded by penetrating in the thickness direction of the glass and then arranging face down And the second
Is a method for manufacturing an optical print head including a step of curing the transparent insulating resin.

[0013]

According to the present invention, it is not necessary to arrange the light emitting diode array chips one by one while aligning the light emitting diode array chips at a predetermined position on the optical fiber array substrate according to the above-described structure. Since the chips are not collectively moved and the chips are collectively arranged and then the chips are collectively wired, the chips do not run onto the next chip or the chips collide with each other to cause a crack, which does not deteriorate the performance. As a result, an optical print head with improved process yield and high productivity and mass productivity is provided.

[0014]

DESCRIPTION OF THE PREFERRED EMBODIMENTS An optical print head according to an embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 (a) is a perspective view of an optical print head according to a first embodiment of the present invention, and FIG. 1 (b) is a sectional structural view taken along the line AA 'of the present optical print head. FIG. 3C is a sectional structural view of the print head taken along the line BB ′. In FIG. 1A, 11 is a base glass, in which an optical fiber 12 is embedded so as to penetrate in the thickness direction. 13 is a circuit conductor layer. 14 is a light emitting diode array chip, 15 is a first translucent insulating resin,
16 is a second transparent insulating resin, 17 is a light emitting diode,
Reference numeral 18 is an electrode portion, and 19 is a metal projection portion. The light emitting diode array chip 14 is embedded in the first translucent insulating resin 15, and the circuit conductor layer 13 has a space between the first translucent insulating resin 15 and the second translucent insulating resin 16. Located and connected to the metal projection 19.

The structure and operation of the optical print head having the above structure will be described below with reference to FIGS. 1 (a), 1 (b) and 1 (c). A light emitting diode 17 and an electrode portion 18 are formed on the light emitting diode array chip 14. When necessary, metal projections 19 are further formed on the electrodes 18. The metal projection 19 may be formed by plating gold or the like, or may be formed by fusing a gold wire or the like in a spherical shape with heat energy and ultrasonic energy. Such a light emitting diode array chip 14 is arranged so as to be embedded in the first translucent insulating resin 15. The translucent insulating resin 15 may be translucent only in the light emission wavelength region of the light emitting diode, but the transmissivity of 90% or more is required. On the other hand, the electrode 18 or the metal projection 19 on the electrode
Is in contact with the interface of the first translucent insulating resin 15, and the circuit conductor layer 1 formed on the translucent insulating resin 15 is
3 is electrically connected. Further, the first translucent insulating resin on which the light emitting diode array chip and the circuit conductor layer are formed is adhered to the optical fiber array substrate via the second translucent insulating resin.

The operation of this optical print head is as follows. Through the circuit conductor layer 13 formed on the first translucent insulating resin 15, the light emitting diode array chip 14
An on / off electric signal is transmitted to each of the light emitting diodes 15 above, and the light emitting diode 15 is turned on and off accordingly. Since the light emitting diode can obtain light emission intensity proportional to the amount of current, multi-valued current control may be performed in addition to simply setting the binary current amount of ON / OFF.

The emitted light enters the opposing optical fiber. The light emission intensity of the light emitting diode has an angle dependence and is incident on the optical fiber at any angle. On the other hand, in the optical fiber, light incident at an angle smaller than the incident angle i corresponding to the numerical aperture (NA) defined by NA = n1 × sin (i) (n1 is the refractive index of the medium into which light is incident) It is transmitted through the optical fiber and efficiently emitted from the end face opposite to the incident side.

However, the light incident at an incident angle i or more does not propagate through the fiber but propagates across the fiber. A light absorber layer is formed on the outermost circumference of the optical fiber, and the light transmitted across the optical fiber is absorbed and attenuated here and does not penetrate the optical fiber array substrate.
Therefore, the light emitted from the light emitting diode array chip mounted face down on the first main surface of the optical fiber array substrate is completely reflected in the single optical fiber for the light having the incident angle i or less. While being efficiently transmitted, the light is emitted from the second main surface of the optical fiber array substrate. Light having an incident angle i or more is absorbed by the light absorber layer of the optical fiber and therefore does not reach the electrophotographic photosensitive member through the optical fiber.

Next, a method of manufacturing the optical print head having the above structure will be specifically described with reference to FIG.
First, a light emitting diode 17 and an electrode 18 are formed on a single crystal III-V group semiconductor substrate (wafer) using a semiconductor process.
Make something with. If necessary, a metal protrusion 19 is formed on the electrode 18. Further, in this embodiment, the emission wavelength 66
12 dot light emitting diodes of 0 nm and 740 nm
/ Mm is used. The electrodes 18 and the metal protrusions 19 may be formed by plating gold, indium, solder, or the like, or re-selecting a gold wire or the like by making it spherical with heat energy and ultrasonic energy and then fusion-bonding. In this embodiment, a metal protrusion having a protrusion of several μm to 30 μm is formed by fusing a gold wire of about 25 μm in a spherical shape. This wafer is cut by a high precision dicing technique to make a light emitting diode array chip 14.

Next, FIG. 2 (a) in which the light emitting diode array chips are arranged and arranged in a straight line. Although only three chips are arranged here as an example, it is usually preferable to arrange the number of chips corresponding to the optical recording width of the optical print head. Further, it is possible to arrange a larger number of light emitting diode array chips, or simultaneously arrange two or more rows of light emitting diode arrays two-dimensionally to improve productivity.

Next, the arrayed light emitting diode array chips are covered with the first light-transmissive insulating resin 15 so as to wrap them, and the light emitting diode array chips are embedded.
(B). Next, the first translucent insulating resin is sufficiently cured by ultraviolet rays 22 emitted from the ultraviolet lamp 21.
(C). As the first translucent insulating resin, an acrylate-based ultraviolet curable resin was used, but a thermosetting resin or
An ultraviolet / heat combined type resin may be used. However, since the resin usually has a large thermal expansion, the joint between the light emitting diode array chips tends to be opened when the thermosetting resin is used, and particularly when the high resolution optical print head is manufactured, the ultraviolet curing resin is used. Better. Next, the electrode portion 18 of the light emitting diode array chip or the surface on which the metal protrusion 19 is formed is polished to obtain the electrode portion 18.
Alternatively, the process continues until the metal protrusion 19 contacts the free space. Since the polishing surface 23 is a surface on which the light of the light emitting diode is radiated, the polishing surface 23 is optically polished to be a mirror surface.
(D).

Next, a circuit conductor is formed on the polished surface 23 of the first translucent insulating resin 15 where the electrode portion or the metal projection is exposed by polishing by using a thick film printing technique or vapor deposition and photoetching technique. The layer 13 is formed in FIG.

Next, an optical fiber array substrate is prepared. The optical fiber array substrate is first made of a conventional one. That is, the optical fiber array substrate shown in FIGS. 6A, 6B, and 6C is formed by an optical fiber 63 having a core diameter of 10 to 25 μm (here, 20 μm) and a numerical aperture NA = 0.57. . Each core 64 is covered with a clad 65 having a thickness of about 2 μm and a light absorber layer 66 having a thickness of about 2 μm. A plurality of such optical fibers are combined to form an optical fiber bundle 62. Next, the optical fiber bundles 62 are arranged so as to be sandwiched by being stacked in three rows between the base glass 61 having a characteristic substantially equal to the thermal expansion coefficient of the optical fiber, and are pressed by heating and melted to be integrated. . Therefore, the optical fiber bundle, which was initially circular, is deformed and exhibits a pentagonal or hexagonal shape. Thereafter, the optical fiber array substrate is manufactured by cutting it out to an appropriate thickness and polishing the surface where the end face of the optical fiber is exposed to be an optically mirror surface.

Next, a predetermined amount of acrylate-based second light-transmissive insulating resin 16 is applied to this optical fiber array substrate by a stamping method, a screen printing method, or the like, and the light-emitting diode array chip 14 is firstly applied thereon. Of the optical fiber 12 of the optical fiber array substrate, the composite body which is embedded in the translucent insulating resin and is connected to the circuit conductor layer 13 by the electrode portion or the metal projection portion exposed on the polishing surface 23.
FIG. 2 (f) in which the face is arranged so as to face the exposed surface. This second translucent insulating resin is
Although it may be different from the translucent insulating resin, it is necessary to select those having a refractive index close to each other so as not to form an optical interface. In this embodiment, the same first transparent insulating resin and the second transparent insulating resin are used.

After that, the second translucent insulating resin 16 is irradiated with the ultraviolet rays 22 from the ultraviolet lamp 21 through the base glass 11 and the optical fiber 12, and is cured to complete the mounting (FIG. 2 (g)).

In the thus obtained optical print head, when the recording medium is illuminated by using the same light emitting diode as in the conventional optical print head using the SELFOC lens array, an optical signal of about 1.4 times is obtained. Was obtained.

With the above-described structure and manufacturing method,
Light emitting diode array chip does not hit the adjacent chip during the manufacturing process or mounts on top of the chip to damage the chip and reduce the yield, improving productivity, cheap and good light I was able to get a printhead.

In this embodiment, only the light emitting diode arrays are collectively arranged and the wiring is performed after the resin is hardened. However, the integrated circuit for driving the light emitting diode array chips is arranged and cured simultaneously with the light emitting diode array chips.
Wiring is possible and productivity can be further improved.

[0030]

According to the optical print head of the present embodiment, a plurality of electrodes are linearly embedded so that only the electrodes or the metal projections formed on the electrodes are in contact with the interface of the first light-transmissive insulating resin. A light emitting diode array chip, a plurality of circuit conductor layers formed on the surface of the translucent insulating resin so as to be connected to the electrode portions or the metal protrusions, and a plurality of optical fibers in the thickness direction of the base glass. In an optical print head having an optical fiber array substrate embedded by penetrating through the optical fiber array substrate, an end face of an optical fiber of the optical fiber array substrate is exposed by exposing the first translucent insulating resin in which the light emitting diode array chip is embedded. An optical print head arranged face down so that the light emitting diode is opposed to the main surface with a second translucent insulating resin interposed therebetween,
The manufacturing method includes a step of linearly arranging a light emitting diode array chip having a plurality of light emitting diodes formed in a linear shape, a step of sealing the arranged light emitting diode array chips with a first light-transmissive insulating resin, The light emitting diode of the light emitting diode array chip is formed such that the step of curing the first transparent insulating resin and the electrode portion of the light emitting diode array chip or the metal projection portion formed on the electrode are in contact with the free space. Polishing step parallel to the chip surface, the step of forming a circuit conductor layer on the surface of the electrode or the metal projection on the electrode exposed in the free space, and the first transparent layer on which the circuit conductor layer is formed. A light-emitting diode array chip coated with a light-insulating resin is embedded in an optical fiber array substrate with multiple optical fibers penetrating in the thickness direction of the base glass. A step of applying a second transparent insulating resin at a predetermined position on the main surface where the end face of the optical fiber is exposed and then arranging it face down, and a step of curing the second transparent insulating resin. By providing the light emitting diode array chip, it is not necessary to arrange the light emitting diode array chips one by one while aligning them at a predetermined position on the optical fiber array substrate. Further, by moving the next chip to the vicinity of the already mounted chip, The present invention provides an optical print head with high productivity, which does not deteriorate the performance or the process yield drastically by riding on the chip of, or hitting and cracking.

Further, the optical print head manufactured in this manner can transmit the image information of an arbitrary wavelength, which is incident on the optical fiber at a large angle, to the electrophotographic photosensitive member without transmitting it.
It enables high-quality image transmission, has a relatively deep depth of focus, and has excellent resolution. Further, it is possible to provide an optical print head which is less susceptible to image deterioration due to static electricity due to friction or scratches due to abrasion, has a simple manufacturing process, and is inexpensive.

[Brief description of drawings]

FIG. 1A is a perspective view of an optical print head according to a first embodiment of the present invention, and FIG. 1B is a sectional structural view of an optical print head according to a first embodiment of the present invention in a light emitting diode array chip array direction. FIG. 3C is a sectional structural view of the optical print head according to the first embodiment of the present invention in a direction perpendicular to the light emitting diode array chip arrangement.

2A is a manufacturing process diagram of an optical print head according to a first embodiment of the present invention, FIG. 2B is a manufacturing process diagram of an optical print head according to a first embodiment of the present invention, and FIG. (D) is a manufacturing process diagram of the optical print head according to the first embodiment of the present invention. (E) is an optical printing head according to the first embodiment of the present invention. (F) is a manufacturing process diagram of the optical print head according to the first embodiment of the present invention. (G) is a manufacturing process diagram of the optical print head according to the first embodiment of the present invention.

FIG. 3A is a cross-sectional structural view of a conventional optical print head in a light emitting diode array chip array direction, and FIG. 3B is a cross-sectional structural view of a conventional optical print head in a direction vertical to a light emitting diode array chip array

FIG. 4 is an enlarged cross-sectional view of a conventional optical print head unit.

5 (a) is a manufacturing process diagram of a conventional optical print head (b ₁₎ a manufacturing process diagram of a conventional optical print head (b ₂₎ the manufacturing process diagrams of a conventional optical print head (c) conventional Manufacturing process diagram of optical print head

6A is a perspective view of a conventional optical fiber array substrate, FIG. 6B is an enlarged view of a conventional optical fiber array substrate, and FIG. 6C is a cross-sectional view of a conventional optical fiber.

[Explanation of symbols]

 11 Base Glass 12 Optical Fiber 13 Circuit Conductor Layer 14 Light Emitting Diode Array Chip 15 First Transparent Insulating Resin 16 Second Transparent Insulating Resin 17 Light Emitting Diode 18 Electrode 19 Metal Protrusion 21 UV Lamp 22 UV 23 Polishing Surface 31 Base Glass 32 Optical Fiber 33 Circuit Conductor Layer 34 Light Emitting Diode Array Chip 35 Light Emitting Diode 36 Electrode Part 37 Translucent Insulating Resin 38 Metal Protrusion 41 Chassis 42 Electrophotographic Photosensitive Body 43 Light Incident at Angle of 44 NA or Less Light incident at the above angles 51 Collet 52 Ultraviolet lamp 53 Ultraviolet 61 Base glass 62 Optical fiber bundle 63 Optical fiber 64 Core 65 Cladding 66 Optical absorber layer

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁵ Identification code Office reference number FI technical display location H04N 1/036 A 8721-5C

Claims (2)

[Claims] 1. A plurality of light emitting diode array chips embedded linearly so that only electrodes or metal projections formed on the electrodes are in contact with the interface of the first translucent insulating resin, and the electrode parts. Alternatively, a plurality of circuit conductor layers formed on the surface of the translucent insulating resin so as to be connected to the metal protrusions, and an optical fiber array substrate in which a plurality of optical fibers are penetrated in the thickness direction of the base glass and embedded. And a second light-transmitting insulating resin, in which the light-emitting diode array chip is embedded, on the main surface of the optical fiber array substrate where the end face of the optical fiber is exposed. An optical print head arranged face down such that the light emitting diodes are opposed to each other with a conductive insulating resin interposed therebetween. 2. A step of linearly arranging light emitting diode array chips having a plurality of light emitting diodes formed in a linear shape, and a step of sealing the arranged light emitting diode array chips with a first light-transmissive insulating resin. The light emitting diode of the light emitting diode array chip is formed such that the step of curing the first transparent insulating resin and the electrode portion of the light emitting diode array chip or the metal projection portion formed on the electrode are in contact with the free space. Polishing step parallel to the chip surface, the step of forming a circuit conductor layer on the polishing surface where the electrode or the metal protrusion on the electrode is exposed in the free space, and the first step of forming the circuit conductor layer. A light-emitting diode array chip coated with a translucent insulating resin is embedded in an optical fiber array substrate with multiple optical fibers penetrating in the thickness direction of the base glass. A step of applying a second transparent insulating resin at a predetermined position on the main surface where the end face of the optical fiber is exposed and then arranging it face down, and a step of curing the second transparent insulating resin. A method for manufacturing the provided optical print head.