KR200419529Y1 - Laser Diode Module - Google Patents

Abstract

The present invention relates to a laser diode module for the network configuration that can configure the network using a laser light, the spherical portion formed in one side shape of the sphere having a constant curvature and the disk shape to secure and fix the corner portion of the spherical portion A spherical lens which is integrally connected to the other side of the spherical portion, the spherical lens dispersing the laser light generated from the diode in a 360 ° direction; The spherical lens consisting of a cylindrical curved surface portion formed in one side of the cylindrical shape having a constant curvature and a cylindrical curved surface protection portion integrally connected to the other side of the cylindrical curved surface portion in a rectangular parallelepiped shape to protect and fix the corner portion of the cylindrical curved surface portion. Cylindrical lens for reducing the dispersion angle in either the horizontal or vertical direction of the laser beam passing through; And a lens housing for aligning the spherical lens and the cylindrical surface lens in front of the laser diode. The lens housing may be configured to include a light having an effective illuminance in a range effective for long-distance observation without generating an interference fringe. That provides a useful effect.

Laser, spherical lens, cylindrical lens,

Description

Laser diode module for flower construction {A LASER DIODE MODULE FOR MAKING VISIBLE AREA}

1 is a cross-sectional view showing a configuration according to an embodiment of the present invention,

2 is an exploded view of FIG. 1;

3 is a perspective view showing the configuration of a lens housing according to an embodiment of the present invention,

4 is a perspective view showing the configuration of a spherical lens according to an embodiment of the present invention,

5 is a perspective view showing the configuration of a cylindrical lens according to an embodiment of the present invention,

6 is an exemplary view showing the arrangement of the lens according to an embodiment of the present invention and the light traveling direction according to the arrangement.

<Description of Major Symbols in Drawing>

10: PCB housing 11: PCB

20: laser diode housing 21: laser diode

22: fixture 30: lens housing

31: spherical lens 31a: spherical portion

31b: spherical protection part 32: fixture

33: cylindrical surface lens 33a: cylindrical surface portion

33b: cylindrical surface protector 34: cylindrical surface lens shift hole

35 fastener 36 fastening bolt

37: protruding pin 38: guide rail

40: housing for positioning the cylindrical lens

41: spiral groove

50: rear cap 51: power line

60: front cap 61: transparent glass

The present invention relates to a laser diode module for a network configuration that can configure a network using a laser light, and more specifically by combining a lens housing for placing a spherical lens and a cylindrical lens in the conventional laser generation unit The present invention relates to a laser diode module for wire construction, in which a laser beam is dispersed to form a square-shaped network at a distance without interference.

In general, since the laser has a straightness, it does not diffuse much even when reaching a long distance to irradiate light in the point-shaped area. However, it is possible to generate a line laser light by dispersing the laser left and right or up and down using a lens, such a line laser light can be used to hold the horizontal or vertical in civil engineering or architectural fields.

The above-mentioned laser beam can be used to focus the laser having linearity in a line shape at a specific distance by using the cylinder lens and the aiming lens, and to change the line width by adjusting the distance between the aiming lens and the cylinder lens. do.

On the other hand, the light emitted from the laser module that generates the line laser light as described above can be utilized as illumination because the laser is distributed to a predetermined range in front and rear of the focal length, there is a possibility to use as a conventional laser light generation laser diode module In the case of using the illumination, since the collimation occurs on both sides of the aiming lens and the cylinder lens, an interference fringe is formed, which makes it difficult to identify an object located at a long distance.

The present invention devised to solve the above problems is to disperse the laser light in all directions with spherical lenses and reduce the dispersion angle in either the horizontal or vertical direction with the cylindrical surface lens. It is an object of the present invention to provide a laser diode module for a network configuration to be configured so that the laser can be used as illumination.

In order to achieve the above object, the laser diode module for a flower arrangement according to an embodiment of the present invention includes a constant voltage supply unit, a laser generating diode, and a diode fixing means, for utilizing a laser as illumination. It consists of a spherical portion formed in one side of the sphere having a constant curvature and a spherical protective portion integrally connected to the other side of the spherical portion in the shape of a disc to protect and fix the corner portion of the spherical portion, 360 degrees laser light generated from the diode A spherical lens dispersed in the ° direction; The spherical lens consisting of a cylindrical curved surface portion formed in one side of the cylindrical shape having a constant curvature and a cylindrical curved surface protection portion integrally connected to the other side of the cylindrical curved surface portion in a rectangular parallelepiped shape to protect and fix the corner portion of the cylindrical curved surface portion. Cylindrical lens for reducing the dispersion angle in either the horizontal or vertical direction of the laser beam passing through; And a lens housing for aligning the spherical lens and the cylindrical lens in front of the laser diode.

In addition, a guide rail is formed on one side of the lens housing; A cylindrical surface lens moving hole coupled to the cylindrical surface lens and having a protruding pin coupled to one side thereof and moved between the guide rails of the lens housing; And a cylindrical surface lens position adjusting housing having a spiral groove formed therein so as to correspond to the protruding pins of the cylindrical surface lens moving hole, thereby allowing the cylindrical surface lens to move forward and backward by rotating the housing for positioning the cylindrical surface lens. It is desirable to be able to adjust the dispersion angle of the laser light.

On the other hand, it is possible to vary the output of the power supplied to the laser diode may be able to adjust the illuminance of the wire.

Hereinafter, with reference to the accompanying drawings will be described in more detail the configuration and operation principle of the subject innovation.

1 is a cross-sectional view showing a configuration according to an embodiment of the present invention, a spherical lens 31 and a cylinder in a conventional laser diode 21 module including a laser diode 21 and a PCB 11 as a constant voltage supply device. It illustrates a state in which the surface lens 33 is coupled.

In the drawing, the laser diode 21 is coupled to the laser diode housing 20 by the fixture 22, the PCB 11 for supplying a constant voltage and the PCB housing 10 for protecting the PCB 11, and Although the laser generating unit consisting of a rear cap 50, etc. for discharging the power line 51 is illustrated, this configuration has been widely used in the prior art, it is apparent that various modifications are possible.

The core technology of the present invention is in the spherical lens 31, the cylindrical lens 33 and other accessories coupled to the front of the laser generating portion and will be described in detail below with reference to the drawings the characteristic structure of the present invention do.

In general, the laser diode 21 generates a laser light of a rectangular shape having a horizontal to vertical ratio of about 1: 3 to about 5. In order to make the rectangular laser light into a dot form, the optical fiber passes through the optical fiber, and the wave energy of the laser light decreases while passing through the optical fiber, so that the constant voltage supplied to the diode must be increased to transmit a long distance. When the optical fiber is used to transform the rectangular laser light into the point laser light, the energy loss is large, and in order to reach the same distance with the same illuminance, the rectangular laser light is used without using the optical fiber. Since the output should be higher than when used as it is, the power supply amount is also increased, so there is a problem that the operating time is reduced when using the battery, it is preferable to use the laser light of the rectangular shape as it is.

Figure 4 is a perspective view showing the configuration of the spherical lens 31 according to an embodiment of the present invention, illustrating a configuration consisting of the spherical portion 31a and the spherical protection portion 31b, which occurs in the laser diode 21 Light is refracted toward the set focal point while passing through the spherical lens 31, and is dispersed after passing through the focal point.

5 is a perspective view showing the configuration of the cylindrical surface lens 33 according to an embodiment of the present invention, illustrating a configuration consisting of a cylindrical surface portion 33a and a cylindrical surface protection portion 33b, the spherical lens 31 When the light dispersed through the foci passes through the cylindrical lens 33, the dispersion angle decreases in the curved direction, and the dispersion angle decreases in the direction perpendicular to the curved surface. Is passed without.

The spherical lens 31 and the cylindrical lens 33 is configured to form a curved surface on only one surface, which is intended to minimize the occurrence of interference fringes, and can further reduce the occurrence of interference through a coating process.

Figure 6 is an exemplary view showing the arrangement of the lens according to an embodiment of the present invention and the direction of light according to the arrangement, in (a) the laser beam that has been dispersed after passing the focal length through the spherical lens 31 The dispersion angle decreases in the direction forming the curved surface of the cylindrical surface lens 33, and (c) passes through the laser beam in a direction perpendicular to the curved surface direction without decreasing the dispersion angle. For example,

In addition, comparing (a) and (b), it can be seen that as the cylindrical lens 33 moves away from the spherical lens 31, the dispersion angle of the laser beam passing through the cylindrical lens 33 decreases. .

Summarizing the above points, a rectangular laser light having a horizontal to vertical ratio of about 1: 3 to 5 is largely dispersed in one direction while passing through the spherical lens 31 and the cylindrical lens 33, and the other It can be seen that the dispersion can be made smaller in the direction.

The present invention is to use this principle, the horizontal dispersion angle is larger than the vertical dispersion angle to form a square close to the square at a certain distance.

On the other hand, since the spherical lens 31 and the cylindrical lens 33 has a very small curvature, the edges are sharpened, and thus, the spherical lens 31 and the cylindrical lens 33 may be easily damaged by an impact. Therefore, in order to prevent the edges of the spherical portion 31a and the cylindrical curved surface portion 33a from being damaged, the spherical protective portion 31b and the cylindrical curved surface protecting portion 33b should be provided. In addition, the spherical protection part 31b and the cylindrical surface protection part 33b also serve to secure the lens more safely and easily.

In the above description, for the sake of understanding, each lens is composed of a combination of a spherical portion 31a and a spherical protective portion 31b, a cylindrical curved surface portion 33a and a cylindrical surface protective portion 33b. 31a, the cylindrical curved surface portion 33a and each of the protective portions 31b and 33b are not separately manufactured and combined, but may be formed by cutting a lens in a stage of manufacturing the lens.

At this time, even if the spherical lens 31 is used instead of the cylindrical surface lens 33, the dispersion angle can be reduced, but in this case, the initial shape of the laser beam having the horizontal to vertical ratio of 1: 3 to 5 and the two spherical lenses Considering the deformation while passing through (31), an oval-shaped network in the vertical direction is formed at a distant position where a flower is to be formed, and in the case of trying to capture the objects reflected on the flower through the camera, Many deviations occur, and consequently, unnecessary illumination of the light source causes a decrease in illuminance. In view of this point, increasing the output of the laser diode 21 is not preferable because the energy loss rate is unnecessarily increased.

As shown in FIG. 1, the spherical lens 31 and the cylindrical lens 33 are fixed to the lens housing and the cylindrical lens shift hole 34 by fasteners 32 and 35, respectively. In this case, when the cylindrical lens 33 is configured to be fixed without being moved, the cylindrical lens moving hole 34 is not required, and similarly to the fixing of the spherical lens 31, the cylindrical lens of the lens housing ( 33) The cylindrical surface lens 33 can be fixed at a predetermined position inside the fixing portion. (Not shown)

2 is a perspective view showing a lens housing 30 according to an embodiment of the present invention, and is composed of a spherical lens fixing portion 30a and a cylindrical lens fixing portion 30b, as illustrated in the figure, wherein In addition, the diameter of the spherical lens fixing portion (30a) is formed larger than the diameter of the cylindrical lens fixing portion (30b) for coupling with the laser generating unit, so that it can be fixed by the fastening bolt (36).

According to another embodiment of the present invention, the position of the cylindrical surface lens 33 can be adjusted to the front and rear, and at this time, one side of the cylindrical surface lens fixing part 30b of the lens housing 30 is shown in FIG. The guide rail 38 is formed as well.

In addition, the outer diameter of the cylindrical surface lens movement hole 34 should be slightly smaller than the inner diameter of the cylindrical surface lens fixing portion 30b, and the cylindrical surface lens movement opening 34 is inserted into the cylindrical surface lens fixing portion 30b. Protruding pin 37 is coupled through the guide rail 38 in the cylindrical surface lens 33 itself is configured to be able to move forward and backward without rotation.

On the other hand, on the inner surface of the cylindrical lens position adjusting housing 40, a spiral groove 41 is formed to correspond to the protruding pin 37 of the cylindrical lens lens moving hole 34, the housing 40 for adjusting the cylindrical lens position The cylindrical surface lens 33 can be moved to the front and rear by rotating.

In addition, at one end of the cylindrical lens position adjusting housing 40 and the lens housing 30 is provided with a front cap 60 including a transmissive glass 61 that transmits laser light, and foreign matter is introduced into the lens housing. It is possible to prevent the input, and to ensure that the cylindrical lens position adjustment housing 40 is fixed.

On the other hand, the variation of the dispersion degree also affects the illuminance. In a state in which the amount of light of the light source is constant, the greater the degree of dispersion, the lower the illuminance of the wire, and the smaller the degree of dispersion, the higher the illuminance. In addition, when the area to be observed is close, the variance becomes less, and as the distance to be observed increases, the variance becomes more and the illuminance becomes lower. At this time, the light amount of the light source can be adjusted by varying the output of the laser diode 21, the output of the diode can be implemented using a variable resistor or the like.

By adjusting the dispersion and the amount of light as described above, it is possible to obtain a flower having the illuminance necessary for observation regardless of near or far distance.

The contents described in the drawings and the specification are exemplary descriptions of the present invention, which are merely used for the purpose of describing the present invention and are not intended to limit the scope of the present invention as defined in the claims or claims. Therefore, those skilled in the art will understand that various modifications and equivalent other embodiments are possible from this. Therefore, the true technical protection scope of the present invention should be defined by the technical spirit of the claims.

The laser diode module for a network configuration according to the present invention configured as described above provides a useful effect of constructing a network of illuminance effective in a range effective for observation from a distance without generating an interference fringe.

In addition, the amount of light of the light source can be varied, and the distance between the spherical lens and the cylindrical surface lens can be adjusted, thereby providing a useful effect of optimizing illumination of the illumination at the corresponding distance regardless of a short distance or a long distance. do.

In addition, since the rectangular laser is used as it is without passing through the optical fiber, energy efficiency is high.

Claims (3)

In order to utilize the laser as an illumination having a constant voltage supply, a laser generating diode and a diode fixing means, It consists of a spherical portion formed in one side of the sphere having a constant curvature and a spherical protective portion integrally connected to the other side of the spherical portion in the shape of a disc to protect and fix the corner portion of the spherical portion, 360 degrees laser light generated from the diode A spherical lens dispersed in the ° direction; The spherical lens consisting of a cylindrical curved surface portion formed in one side of the cylindrical shape having a constant curvature and a cylindrical curved surface protection portion integrally connected to the other side of the cylindrical curved surface portion in a rectangular parallelepiped shape to protect and fix the corner portion of the cylindrical curved surface portion. Cylindrical lens for reducing the dispersion angle in either the horizontal or vertical direction of the laser beam passing through; A lens housing for aligning the spherical lens and the cylindrical lens in front of the laser diode; A laser diode module for a network configuration comprising a. The method of claim 1, A guide rail is formed at one side of the lens housing; A cylindrical surface lens moving hole coupled to the cylindrical surface lens and having a protruding pin coupled to one side thereof and moved between the guide rails of the lens housing; A cylindrical lens position adjusting housing having a spiral groove formed therein to correspond to the protruding pin of the cylindrical lens moving hole; And rotating the cylindrical lens lens position adjusting housing to move the cylindrical lens front and rear to adjust a dispersion angle of the laser beam. The laser generating diode module of claim 1 or 2, wherein the output of the power supplied to the laser diode can be varied.

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