KR101317407B1 - A mold die structure for F-theta lens - Google Patents

Abstract

The present invention relates to a mold structure for forming an f-theta lens, comprising: a mold structure for molding an F-theta lens for a laser scanning unit, comprising a plurality of ejection pins in the mold structure to be taken out of the mold; 6 temperature sensors are placed on each side of the upper mold to measure the uniform temperature change, while maintaining the high mold temperature uniformly with the two-stage cold water supply pipe, minimizing the shape error of the lens surface, resulting in optical performance of the lens. The present invention relates to a mold structure for molding an F-theta lens for a laser scanning unit, which is implemented to improve the efficiency.
The mold structure for forming the f-theta lens of the present invention for this purpose, an upper mold formed by penetrating the raw material inlet in the upper base body and forming a recessed upper guide portion with a lower surface of the upper base body and forming a recessed upper fixing core and; A lower mold forming a recessed lower guide part on an upper surface of the lower base body and forming a recessed lower main core; It consists of, the temperature measuring means for measuring the uniform temperature change of each of the lower mold and the upper mold by installing the six temperature sensors around each of the lower mold and the upper mold side disposed around the molded article; Cooling means for maintaining a high mold temperature uniformly by connecting to the cold water supply pipe for supplying cold water to each of the lower mold and the upper mold; An ejection means for installing 30 ejection pins around the eject plate existing in the lower mold to eject the molded product out of the mold according to the lifting and lowering operation of the eject plate after completion of molding; Further comprising:

Description

A mold die structure for F-theta lens

The present invention relates to a mold structure for forming an f-theta lens, and more particularly, to a mold structure for molding an f-theta lens for a laser scanning unit, which minimizes a shape error of a lens surface to improve optical performance of the lens. The present invention relates to a mold structure for molding an F-theta lens for a laser scanning unit.

In general, a laser scanning unit refers to a device that generates a laser beam according to an input signal and then forms the beam on a photosensitive drum. A latent image formed on a photosensitive drum is usually applied to a medium such as paper. It is used for laser printers, copiers, multifunction machines, and the like, which reproduce image images by transferring.

1 is a conceptual diagram schematically illustrating a configuration of a general laser scanning unit.

Referring to FIG. 1, a general laser scanning unit 30 includes a laser diode (Laserdiode) 11 for emitting a laser beam as a light source, and a collimator for making the laser beam emitted from the laser diode 11 into parallel light with respect to an optical axis. A lens (Collimator lens) 13, a cylindrical lens (15) for making parallel light through the collimator lens (13) into a linear light in a horizontal direction with respect to the sub-scanning direction, and a horizontal through the cylinder lens (15) Polygon mirror 23 for scanning linear light in a constant direction at a constant velocity, Scanning motor 25 for driving a polygon mirror 23 at constant speed, and a constant refractive index with respect to the optical axis F-theta lens 20 and F-theta which refract the constant velocity light reflected from the polygon mirror 23 in the main scanning direction and correct the aberration to focus on the scanning surface. An imaging reflector 18 for reflecting a laser beam through the lens 20 in a predetermined direction to form a latent image on the surface of the photosensitive drum 16 as an image forming surface, and a laser beam through the F-theta lens 20. A horizontal synchronous mirror 12 for reflecting the light in a horizontal direction, and a photo sensor 14 for receiving and synchronizing with the laser beam reflected from the horizontal synchronous mirror 12.

Among them, the F-theta lens 20 is mostly injection molded into a plastic such as optical resin in order to improve productivity and reduce cost.

In the case of the conventional F-theta lens 20, there is a problem due to an unbalanced difference in temperature in the mold structure by being molded in most cases.

When molding a molded product in the mold structure, it is necessary to maintain a high mold temperature uniformly, but one side of the mold has a high temperature, and it can be seen that the temperature gradually decreases toward the opposite side.

The F-theta lens 20 has a physical property to be molded according to the temperature of each part, and this physical property may cause optical defects, which is called double refraction.

This birefringence changes the refractive index and the direction of vibration of the light beam oscillating in a constant direction, making it impossible to form an image at a desired distance.

This is an inherent property of plastics molded at high temperatures, and it is difficult to produce this inherent property perfectly in optical analysis.

Due to such a difference in injection temperature, the F-theta lens 20 is sensitive to temperature, and thus a problem occurs because optical properties are changed even by a temperature of 0.1 degrees.

Therefore, there is a problem that adversely affects the performance of the optical scanning device.

In addition, by manufacturing the f-theta lens 20 discontinuously, there is a disadvantage in that productivity is low.

An object of the present invention for solving the problems according to the prior art, the mold structure for molding the F-theta lens for the laser scanning unit, a plurality of ejection pins to the mold structure to take out to remove the mold and the lower portion Six temperature sensors are placed on each side of the mold and the upper mold to measure uniform temperature changes while maintaining a high mold temperature with a cold water supply pipe with a two-stage structure to minimize the shape error of the lens surface. The present invention relates to a mold structure for molding an F-theta lens for a laser scanning unit implemented to improve optical performance.

In order to solve the above technical problem, the fpseta lens molding mold structure of the present invention includes a through hole in the upper base body, a recessed upper guide part formed on the lower surface of the upper base body, and a recessed upper fixed core. One upper mold; A lower mold having a recessed lower guide part on the upper surface of the lower base body and forming a recessed lower main core; It consists of, the temperature measuring means for measuring the uniform temperature change of each of the lower mold and the upper mold by installing the six temperature sensors around each of the lower mold and the upper mold side disposed around the molded article; Cooling means for maintaining a high mold temperature uniformly by connecting to the cold water supply pipe for supplying cold water to each of the lower mold and the upper mold; An ejection means for installing 30 ejection pins around the eject plate existing in the lower mold to eject the molded product out of the mold according to the lifting and lowering operation of the eject plate after completion of molding; Further comprising:

Preferably, the temperature measuring means, characterized in that it further comprises a temperature sensor in contact with each of the upper fixed core and the lower main core to directly measure the temperature to accurately determine the temperature distribution.

Preferably, the temperature sensor is characterized in that it further comprises that can withstand high temperatures of 150 degrees or more.

Preferably, the cooling means, characterized in that it further comprises a predetermined length in the form of a line along the molded article in a two-stage structure of the lower mold and the upper mold, respectively.

According to the present invention as described above, since the molding process is continuously performed by the F-theta lens molding apparatus, by adjusting the temperature of the section between the upper and lower molds by the convenience of the extraction means, grasping the real-time temperature and maintaining the uniform temperature By controlling the cooling rate, by reducing internal refractive index unevenness and poor molding, there is an effect that can greatly improve the optical performance and productivity of the F-theta lens.

In addition, when taking out the mold of the fexeta lens, 30 ejection pins may be installed to facilitate the extraction, thereby preventing deformation of the fexeta lens molded article and reducing the defective rate.

1 is a conceptual diagram schematically showing a configuration of a general laser scanning unit.
Figure 2 is a schematic diagram showing a structure of a mold for forming afceta lens according to the present invention.
Figure 3 is a view showing an upper mold showing the temperature measuring means of the die structure for forming the fexeta lens according to the present invention.
Figure 4 is a view showing a lower mold showing the temperature measuring means of the die structure for forming the fexeta lens according to the present invention.
Figure 5 is a view showing an upper mold showing the cooling means of the die structure for forming the afceta lens according to the present invention.
Figure 6 is a view showing a lower mold showing the cooling means and the eject pin of the mold structure for forming afceta lens according to the present invention.
Figure 7 is a view showing each means of the die structure for forming the afceta lens according to the present invention.

According to an aspect of the present invention,

An upper mold formed by penetrating a raw material inlet through the upper base body, forming a recessed upper guide part with a lower surface of the upper base body, and forming a recessed upper main core;

A lower mold having a recessed lower guide part on the upper surface of the lower base body and forming a recessed lower main core; Lt; / RTI >

Temperature measuring means for measuring a uniform temperature change of each of the lower mold and the upper mold by placing six temperature sensors around the molded article on each side of the lower mold and the upper mold;

Cooling means for maintaining a high mold temperature uniformly by connecting to the cold water supply pipe for supplying cold water to each of the lower mold and the upper mold;

An ejection means for installing 30 ejection pins around the eject plate existing in the lower mold to eject the molded product out of the mold according to the lifting and lowering operation of the eject plate after completion of molding; It was achieved by providing a die structure for forming the fexeta lens characterized in that it further comprises.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and the inventor should appropriately interpret the concepts of the terms appropriately It should be interpreted in accordance with the meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined.

Therefore, the embodiments described in the present specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention, and not all of the technical ideas of the present invention are described. Therefore, It should be understood that various equivalents and modifications are possible.

Figure 2 is a schematic diagram showing a structure of a mold for forming afceta lens according to the present invention.

As shown, a mold structure for molding an F-theta lens for a laser scanning unit according to the present invention, comprising a plurality of eject pins 154 in the mold structure to take out the mold And 6 temperature sensors 130 are installed on the lower mold 120 and the upper mold 110, respectively, around the molded product to measure a uniform temperature change, and to maintain a high mold temperature with a cold water supply pipe 140 having a two-stage structure. It is implemented to improve the optical performance of the lens by minimizing the shape error of the lens surface by maintaining a uniform.

The mold for manufacturing the F-theta lens 102 is formed by penetrating the raw material inlet 114 in the upper base body 112 and having a recessed upper guide to the lower surface of the upper base body 112. The upper mold 110 is formed to form the portion 116, and formed the recessed upper fixing core 118.

And, the upper surface of the lower base body 122 is formed with a lower mold 120 having a recessed lower guide portion 1240, and formed a recessed lower main core 126.

The upper base body 112 has a curved upper surface so as to form a predetermined shape of the acetase lens 102 together with the filling of the raw material, and the image in the body of the mold for taking out the molded fseta lens 102 is completed. It comprises a main core 126 of the rectangular block structure mounted to be able to slide / down and a fixed core 118 matching it.

At this time, the main core 126 is contained while taking a significant place in the body of the lower mold 120.

The fixed core 118 is disposed in the upper mold 110 and the main core 126 is disposed in the lower mold 120, the upper surface of the lower mold 120 through matching with the main core 126 An ejection hole 156 having an eject pin 154 in charge of forming a body of the body is formed, and an upper surface of the main core 126 is disposed on the ejection hole 156, and the ejection hole 156 is formed. It is installed to move the upper and lower slides freely.

As shown in FIGS. 3 and 4 as the mold structure, the temperature measuring means using the temperature sensor 130 during the molding of the fexeta lens 102 has a uniform temperature on the lower mold 120 and the upper mold 110. Measure the change.

The temperature sensor 130 is installed in the upper mold 110 and the lower mold 120, each of the six temperature sensors 130 arranged around the molded article.

The temperature measuring means measures the temperature change by speaking the temperature sensor 130 around each of the main core 126 and the fixed core 118 forming a large surface area by a constant molding temperature maintained in the mold.

This is to determine the temperature distribution during injection molding by inserting the temperature sensor 130 of the fexeta lens 102 mold.

In addition, it is possible to grasp the optical characteristics of the fexeta lens 102 that is precisely molded after grasping the temperature distribution.

In this case, the fexeta lens 102 is sensitive to temperature, and thus the optical characteristics are changed even by a temperature of 0.1 degrees.

As such, the temperature measuring means accurately detects the temperature distribution by directly measuring the temperature by making the temperature sensor 130 contact each of the upper fixing core 118 and the lower main core 126.

That is, in order to determine the optical imaging ability of the fexeta lens 102, the temperature sensor 130 is directly contacted with the main core 126 and the fixed core 118 of the mold for forming the curved surface of the lens to measure the temperature directly. do.

Here, the measured temperature sensor 130 should be manufactured to withstand high temperatures of 150 degrees or more, and a total of 12 mold temperature sensors 130 are installed in each of the upper and lower molds 110 and 120 of the mold.

Thus, by checking the graph of the 12 mold temperature sensors 130 for each time it is possible to easily grasp the temperature change.

Therefore, in order to grasp the plastic properties of the temperature-sensitive F-theta lens 102 for the optical performance analysis, the temperature sensor 130 is installed in the mold to face the temperature change.

In this way, the temperature of the mold is grasped, and the mold temperature is kept uniform using cooling means.

5 and 6, the cooling means is connected to the cold water supply pipe 140 for supplying cold water to each of the upper mold 110 and the lower mold 120 to maintain a high mold temperature uniformly.

The cooling means has a predetermined length in the form of a line along the molded article in a two-stage structure of the lower mold 120 and the upper mold 110, respectively.

As described above, the upper mold 110 is preheated to a uniform temperature before the molten resin is administered, and the molten resin is maintained by the cooling means while the molten resin is flowed to maintain the overall uniform temperature, and the temperature is measured while the molten resin is molded. Through the temperature sensor 130 of the number continuously to determine whether the temperature is maintained uniformly throughout.

Meanwhile, as shown in FIGS. 6 and 7, the ejection means existing in the lower mold 120 serves as a ejection means for smoothly ejecting the ftheta lens 102 from the mold after the fceta lens 102 is formed. Thirty eject pins 154 are installed around the plate 152 to take out the molded product out of the mold according to the lifting and lowering operation of the eject plate 152 after the molding is completed.

The mold extracting means of the ftheta lens 102 is formed of a mold divided into an upper mold 110 and a lower mold 120. After molding, the upper mold 110 and the lower mold 120 are separately taken out. Is done.

Accordingly, when the eject plate 152 made as described above is moved upward, the ejection operation is performed by the eject pin 154.

That is, when the molding is completed, the upper mold 110 is moved upward to open the lower mold 120 and at the same time the ejection pin 154 of the ejection plate 152 is formed in the ejection hole 156 Through the fixed core 118 is pushed upward.

In this way, the fixing core 118 is moved upward to expose the lower mold 120 to the outside to facilitate the ejection of the molded product of the fexeta lens 102.

When the mold of the fexeta lens 102 is taken out, thirty eject pins 154 are installed to facilitate taking out the mold, thereby preventing deformation of the molded article of the fseta 102 and reducing the defective rate.

By this operation, the effect of not damaging the fexeta lens 102 is generated by the basic structure in which the molded product of the fexeta lens 102 does not work without excessive force.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. Various modifications and variations are possible within the scope of the appended claims.

102: f theta lens 110: upper mold
112: upper base body 114: raw material inlet
116: the upper guide portion 118: fixed core
120: lower mold 122: lower mold body
124: bottom guide 126: main core
130: temperature sensor 140: cooling supply pipe
152: eject plate 154: eject pin
156: ejection hall

Claims (4)

In the die for forming the f-theta lens,
An upper mold formed by penetrating a raw material inlet in the upper base body, forming a recessed upper guide part with a lower surface of the upper base body, and forming a recessed upper fixing core;
A lower mold having a recessed lower guide part on the upper surface of the lower base body and forming a recessed lower main core; Lt; / RTI >
In order to measure the temperature change of the lower main core and the upper fixed core, and to determine the temperature distribution inside the mold during injection molding, a total of 12 units are installed around the lower main core and the upper fixed core, respectively, each of which has a total temperature of 12 hours. Temperature measuring means for checking the change and checking the optical characteristics of the fexeta lens which is installed to be in contact with the lower main core and the upper fixed core so as to directly measure the temperature change in the mold and directly measure the temperature;
Cooling means for forming a two-stage structure formed with a line-shaped cold water supply pipe formed along the molded product of the lower mold and the upper mold, the cold water is supplied to the cold water supply pipe to maintain a uniform temperature of the mold;
An ejection plate existing in the lower mold to separate the upper mold and the lower mold, 30 eject pins installed around the eject plate, and an ejection formed in the lower mold so that 30 eject pins can move up and down. Take out means for forming a hole, the eject plate is moved together with the upper mold to move upward when the molding is completed, and the eject pin is moved up and down along the ejection hole to move the upper fixing core to the upper side to take out the fexeta lens ;
Mold structure for forming the fexeta lens, characterized in that it comprises a.
delete The method of claim 1,
The temperature sensor is capable of withstanding high temperatures of 150 degrees or more.
delete

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