JPH0754865Y2 - Light intensity adjustment mechanism and lightwave rangefinder in lightwave rangefinder - Google Patents

Description

[Detailed Description of the Invention] [Industrial application] The present invention relates to an optical distance meter for distance measurement using a light wave, and in particular, to a light amount of reference light in an optical distance meter in which an optical fiber is arranged in an optical path for reference light. Regarding adjustment mechanism.

[Prior art]

As an optical distance meter in which an optical fiber is arranged in a reference optical circuit, there is JP-A-60-149985, which, as shown in FIG. 4, transmits a radiation-modulated light F emitted from a light emitting element 1 to an optical transmission system. 2 is used to divide into a distance measuring light F1 and a reference light F2, the reference light F2 is imaged on the light receiving element 4 via the optical fiber 3 and converted into an electric signal, while the distance measuring light F1 is converted into an objective lens 5 The reflected distance measuring light G from the reflector 6 is emitted toward the reflector 6 via
An image is formed on the light receiving element 4 by using the light receiving optical system 7, converted into an electric signal, and the distance is measured by the phase difference between the reflected distance measuring light G and the reference light F2. Further, a rotatable ND filter 8 is provided on the front surface of the light receiving element 4, and the reflected distance measuring light G
Also, the light quantity of the reference light F2 is reduced. Also,
The ND filter 8 is rotationally driven by a motor so that the light is properly focused when passing through the filter.

In addition, for general light intensity adjustment, prepare several filters with small apertures, gradually increase the number of filters placed on the optical path, and when these light amounts become appropriate, use these filters. There is a way to fix it.

Alternatively, there is also a method in which several kinds of filters having different aperture amounts are prepared, and one filter is replaced with another filter and arranged on the optical axis to fix a filter having an appropriate light amount.

[Problems to be solved by the invention]

As mentioned above, in adjusting the light quantity of the reference light of the light distance meter,
Although an ND filter or a simple filter is used, the ND filter has a problem in that it takes time and effort for the photo developing process in the manufacturing process and is inefficient.

Further, in the case of a simple filter, it is necessary to overlap or replace the filters as an adjustment for obtaining an appropriate amount of light, which causes a problem that the work is troublesome.

The present invention has been made in view of the above-mentioned problems of the prior art,
A first object of the invention is to provide a novel light amount adjusting mechanism which does not use any filter for adjusting the light amount of the reference light and which is easy to adjust the light amount.

A second object of the present invention is to provide an optical distance meter that allows easy adjustment of the light quantity of the reference light and easy assembly and adjustment of the light transmitting optical system.

[Means for Solving the Problems]

In order to achieve the above-mentioned object, in the light quantity adjusting mechanism of the reference light according to claim (1), a beam splitter provided in the light transmitting section causes an optical path from the light transmitting section to the light receiving section to be an optical path for reference light. An optical wave distance configured so that the reference light divided into two parts, the optical path for distance measuring light and the optical path for reference light, and the reference light divided by the beam splitter is guided to the optical fiber by the condenser lens. In the meter, there is provided a light quantity adjusting mechanism of the reference light in the light wave distance meter for adjusting the light quantity of the reference light by moving the end part of the optical fiber facing the condensing lens in the optical axis direction. The head of the above is integrally surrounded, and the cylindrical head is inserted into a cylindrical head engaging portion which has an inner diameter matching the outer diameter of the head and is relatively slidable in the axial direction and the circumferential direction, and the head engaging portion. Fixed on In the structure fixed by Flip, loosen the fixing screw, in which end face the optical fiber is to adjust the quantity of light by moving the head to a predetermined position deviated from the focal point of the condenser lens in the optical axis direction.

The lightwave distance meter according to claim (2) is a lightwave distance meter equipped with the light amount adjusting mechanism according to claim (1), wherein the beam splitter and the light emitted from a light emitting element are used for the beam splitter. A head engaging portion for connecting a head integrated to the end portion of the mixing optical fiber that leads to the optical fiber, and the optical path divided by the beam splitter to selectively appear and disappear to measure the reference optical path. A shutter for switching the optical path for distance light and a head engaging portion for connecting a head integrated to the end portion of the optical fiber forming the optical path for reference light are integrated as a light transmitting unit to provide a light wave distance. It can be separated from the main body.

[Action]

When the fixing screw is loosened to release the fixing of the head with respect to the head engaging portion, the head can slide in the axial direction with respect to the head engaging portion. Therefore, when the head is moved in the optical axis direction, the distance between the focal point position of the reference light by the condenser lens and the end position of the optical fiber changes, and the irradiation area of the reference light on the end face of the optical fiber changes. Is larger than the effective light incident surface of
The amount of reference light that enters the optical fiber from the condenser lens changes (decreases).

Also, when the fixing screw is loosened, that is, when the head is inserted into the head engaging portion but not fixed, the head can freely slide in the circumferential direction with respect to the head engaging portion. No torsional stress is generated.

According to a second aspect of the present invention, the light transmitting optical system constituting member including the head engaging portion for connecting the head of the optical fiber, which is the reference light optical path constituting member, is integrated as a light transmitting unit, so that the light transmitting unit is formed. The unit can be adjusted separately from the main body of the optical rangefinder.

〔Example〕

 Next, an embodiment of the present invention will be described with reference to the drawings.

1 and 2 show an embodiment of the present invention. FIG. 1 is a cross-sectional view of a portion from a light-transmitting portion of a light-wave rangefinder to an optical path for reference light. Reference numeral 20 is a light amount adjusting mechanism for the reference light, and reference numeral 50 is a light receiving element for receiving the reference light and the distance measuring light. FIG. 2 is an explanatory diagram for explaining the adjustment of the light amount of the reference light.

In the light transmitting section 10, the light emitted from the light emitting element 11 is guided to the beam splitter 13 via the mixing optical fiber 12, and the light guided to the beam splitter 13 is divided into two orthogonal directions. There is. And the beam splitter
The light passing through 13 is guided to the light receiving element 50 via the optical path A for distance measuring light, while the light reflected on the surface of the beam splitter 13 is guided to the light receiving element 50 via the optical path B for reference light. The surface of the beam splitter 13 reflects the reflected light (reference light).
The coating process is set so that the amount of light is slightly higher than the optimum amount. Also, the optical axis C ₁ of the optical path A for distance measuring light
And the optical axis C ₂ of the optical path B for reference light are orthogonal to each other, and the optical axes C ₁ and C ₂
A shutter 15 that is swingable around a fulcrum 14 is provided at the position where the beam splitter is attached. The optical paths A and B are selectively switched by swinging the shutter 15.

Reference numeral 21 is a casing of the light-wave rangefinder.
A lens barrel 22, which is a head engaging portion to which a head 26 described later can be engaged, is screwed into the lens barrel, and the axis of the lens barrel 22 coincides with the optical axis C ₂ . A condenser lens 23 is fixed at a predetermined position in the lens barrel 22 by a lens presser 24, and the optical axis of the condenser lens 23 coincides with the axis of the lens barrel 22. And the beam splitter
The light reflected on the surface of 13 is condensed by the condenser lens 23 and guided to the light receiving element 50 via the optical fiber 25. It should be noted that in the figure, the symbol D indicates the focal point of the collective lens 23.

Reference numeral 26 is a hollow cylindrical head that surrounds and integrates the end portion of the optical fiber 25, and has an optical fiber insertion hole 26b formed along the axis of the head. Then, the optical fiber 25 is inserted into the hole 26b, and the optical fiber end face 25a and the head end face 26a are flush with each other, and the head 26 and the optical fiber 2
5 and 5 are integrated by an adhesive. Further, the outer diameter of the head 26 matches the inner diameter of the lens barrel 22, and the head 26 inserted in the lens barrel 22 can slide along the inner wall of the lens barrel 22 in the optical axis C ₂ direction and the circumferential direction. Can, therefore, optical fiber
When 25 is twisted, the head 26 is rotated about the optical axis C ₂ to some extent, so that there is no problem that an unexpected twisting stress is generated in the optical fiber 25 during the adjustment and the optical fiber 25 is damaged. Further, even if the head 26 is slid with respect to the lens barrel 22, the axis of the end portion of the optical fiber does not deviate from the optical axis C ₂ .

Reference numeral 28 is a set screw provided on the lens barrel 22, and the head 26
Can be fixed to the lens barrel 22 at any position. Reference numeral 29 is a spring washer for preventing the set screw 28 from loosening.

In this way, a condenser lens fixed at a predetermined position on the optical axis C _2.
23, a head 26 that is an optical fiber connecting end that is slidable in the lens barrel 22 along the optical axis C ₂ , and a set screw 28 that fixes the head 26 at a predetermined position constitute the light amount adjustment mechanism 20. ing.

Next, the adjustment of the light amount of the reference light will be described.

FIG. 1 shows the end face of the head 26, in other words, the end face of the optical fiber.
25a is in the position of the condensing point D, and the reference light guided from the condensing lens 23 at this time is the most efficient optical fiber.
The light amount of the reference light guided to the light receiving element 50 is maximum at a position where it can be incident on 25. When the head end face is moved to, for example, the position a or the position c shown in FIG. 1, the irradiation area of the reference light on the optical fiber end face 25a gradually expands in a circular shape from the point, and the optical fiber which is the effective incident surface of the light beam. It is larger than the area of the end face 25a. Therefore, the ratio of the reference light incident on the end face 25a of the optical fiber, that is, the amount of light is reduced. FIG. 2 shows that the head 26 is moved in a direction away from the condenser lens 23 so that the end face of the optical fiber which is an effective incident surface of light.
It shows a state in which the irradiation area of the reference light on the end face of the optical fiber is larger than the area of 25a.

In this way, by shifting the position of the head end surface from the condensing point D in the front-back direction of the optical axis C ₂ , the light amount of the reference light incident on the optical fiber end surface 25a from the condensing lens 23 is adjusted in the direction of decreasing from the maximum value. be able to. In the present embodiment, the reference light is set to be slightly larger than the optimum light amount when the head end surface is at the focal point D position.
The head 26 is moved to adjust the light amount so that the reference light amount becomes the optimum light amount. When the light amount adjustment is completed, the set screw 28 is used to fix the head 26 to the lens barrel 22, so that the light amount of the reference light incident on the optical fiber end face 25a from the condenser lens 23 is an optimum constant value. Can be kept at

As described above, according to the light amount adjusting mechanism of the reference light of this embodiment, since the ND filter is not used at all, there is no trouble in manufacturing the ND filter.

Further, since the light amount can be easily adjusted only by changing the distance between the condenser lens 23 and the head 26, compared to the conventional light amount adjustment using a filter for the purpose of dimming, the troublesomeness of filter replacement and superposition is required. In addition, the light amount adjustment mechanism is simple and compact.

Although the head 26 is fixed to the lens barrel 22 by using the set screw 28 and the spring washer 29 in the above-described embodiment, the head 26 may be fixed by adhesion or another method.

Now, the feature of the light quantity adjusting mechanism of the present invention is that the distance between the condensing point D and the head 26 is changed so that the condensing lens 23 to the end face of the optical fiber can be changed as described with reference to FIGS.
The purpose is to adjust the amount of reference light incident on 25a. Since means for changing the distance between the condensing point D and the head 26 can be considered in addition to the above-mentioned embodiment, another embodiment will be described next.

Once again, focusing on the optical path B for reference light and the optical members forming this optical path in FIG. 1, let us consider the positions of the collective lens 23 and the head 26 on the optical axis C ₂ .

In the embodiment described above, the condenser lens 23 is used as the body casing 21.
The head 26 is fixed to the casing 21, and the head 26 is moved to the optical axis C ₂ direction to adjust the light amount. As a second embodiment, the head 26 is fixed to the casing 21, and the condenser lens 23 is fixed to the optical axis C ₂ direction. It is conceivable to have a structure in which the light amount is adjusted by moving to.

Further, as a third embodiment, the condenser lens 23 and the head 26
It is also conceivable that each of them is separately moved in the optical axis C ₂ direction to adjust the light amount.

FIG. 3 shows another embodiment of the present invention and is a sectional view of a lightwave rangefinder.

In this figure, the light emitted from a light emitting diode 11 which is a light emitting element is guided to a beam splitter 13 while being mixed by an optical fiber 12 for mixing, and this beam splitter 13 separates the light into two directions orthogonal to the distance measuring light and the reference light. It is supposed to be done. Reference numeral 60 is a second beam splitter, and reference numeral 70 is an objective lens. The shutter 15 is
It is swung by a power source such as a motor or solenoid (not shown). Further, heads 26A and 26B, which are the connecting portions to the body casing 21, are bonded to the ends of the mixing optical fiber 12 and the reference optical fiber 25 on the beam splitter side so that the end faces are in the same state as the optical fibers 12 and 25. Are integrated by.

Reference numeral 31 denotes a frame body that is mechanically fastened to the body casing 21 of the lightwave rangefinder by screws or the like, and is detachable from the body casing 21. A beam splitter 13, a condenser lens 23, and a shutter 15 are assembled to the frame body 31 and integrated as a light transmitting unit 10A. The frame 31, the optical fiber head 26A for mixing, an engaging portion 31a into which the optical fiber head 26B for reference light can be respectively inserted and connected,
Engaging portions 31b are formed so as to project, and each engaging portion 31b
The optical fibers 12 and 25 can be easily attached and detached by inserting and removing the heads 26A and 26B into and from the engaging portion 31b. Reference numeral 28 is a set screw screwed to the head engaging portions 31a, 31b, reference numeral 29 is a spring washer for preventing the set screw 28 from loosening, and the outer diameter of the heads 26A, 26B and the head engaging portions 31a, 31b. The inner diameters match each other, and the heads 26A and 26B are connected to the head engaging portion 31.
It can be inserted and fixed in a and 31b respectively. An opening 34 is formed in the frame body 31 so as not to block the optical path A for distance measuring light.

As described above, the beam splitter 13, the shutter 15, the condenser lens 23, and the engaging portions 31a and 31b are provided in the frame body 31 in the light transmitting unit 1.
The structure is integrated as 0A, and the optical member is assembled and integrated in the frame body 31 at a place easy to work, and the light transmitting unit 10
Since it can be assembled into the body casing 21 as A, the light wave range finder can be easily assembled.

Further, since the light transmitting unit 10A can be separated from the body casing 21, it is possible to manufacture and adjust the light transmitting unit alone.
Workability is better than when each optical member is directly assembled to the body casing 21.

In addition, when it is desired to replace the optical members and the like in the light transmitting unit 10A, the light transmitting unit 10 is removed from the body casing 21.
A can be removed for processing work, and the transmitter unit 10A
Can be dealt with efficiently, such as by replacing.

Furthermore, if it is a simple improvement of the lightwave rangefinder, the light-transmitting unit and the lightwave rangefinder excluding the light-transmitting unit can be separately modified and combined, without redesigning the entire lightwave rangefinder, There is also an advantage that it can be improved easily.

Incidentally, in the above-mentioned embodiment, the optical fiber head 26A, 26B
Although the set screw 28 is used to fix the engaging portion 31a, 31b to the engaging portion 31a, 31b, a female screw is formed on the inner circumference of the engaging portion 31a, 31b, and the head 26
Alternatively, a male screw may be formed on the outer circumference of A, 26B and the male screw may be directly screwed to fix the male screw.

If necessary, a lens is provided on the optical path of the light from the mixing optical fiber head engaging portion 31a to the beam splitter 13, or a lens is provided at the opening 34 through which the optical path A for distance measuring light passes. Etc. are possible.

[Effect of device]

As is clear from the above description, according to the light amount adjusting mechanism of claim (1), the light amount of the reference light optical path can be adjusted without using the ND filter or the simple filter at all. The troublesomeness and the troublesomeness of adjusting the light amount by simply using a filter are eliminated.

In addition, the light amount can be easily adjusted, the adjusting mechanism is simple and compact, and the manufacturing cost can be reduced as compared with the conventional technique using the ND filter or a simple filter.

Further, the light quantity adjusting mechanism is mainly composed of a head integrated with the end of the optical fiber, a head engaging portion through which the head is inserted, and a fixing screw for fixing the head to the head engaging portion. The simple and compact structure also leads to miniaturization of the optical distance meter.

Further, since the head can freely slide in the circumferential direction with respect to the head engaging portion, there is no problem that the optical fiber is damaged by the torsional stress.

Further, according to the lightwave distance meter of claim (2), since the light-transmitting optical system constituent member is integrated as a light-transmitting unit and can be separated from the lightwave distance meter main body, workability of manufacturing, adjustment and repair is good, and design Easy to improve.

[Brief description of drawings]

FIG. 1 is a cross-sectional view of a light quantity adjusting mechanism of reference light of a light distance meter,
FIG. 2 is a sectional view for explaining the movement of the light quantity adjusting mechanism, FIG. 3 is an overall constitutional view showing a part of a light wave rangefinder according to another embodiment of the present invention in section, and FIG. 4 is an optical path for reference light. It is a schematic diagram of the conventional light-wave distance meter which used the optical fiber for the. 10 ... Light sending unit, 10A ... Light sending unit, 11 ... Light emitting diode as light emitting element, 12 ... Light source optical fiber for sending light, 13 ... Beam splitter, 15 ... Shutter, 20 ...
Reference light intensity adjustment mechanism, 21 …… Airframe casing, 23 ……
Condenser lens, 25 …… Reference light optical fiber, 25a …… Optical fiber end face, 26,26A, 26B …… Head, 28 …… Set screw,
31 ... Frame, 31a ... Mixing optical fiber head engaging portion, 31b ... Reference light optical fiber head engaging portion, 50 ...
… Light receiving element, which is a light receiving part, A ... Optical path for distance measuring light, B ...
Optical path for reference light, C ₂ ... Optical axis of optical path for reference light.

Claims (2)

[Scope of utility model registration request] 1. A beam splitter provided in the light transmitting section divides an optical path from the light transmitting section to the light receiving section into a reference light optical path and a distance measuring light optical path, and an optical fiber is provided in the reference light optical path. In an optical distance meter configured so that reference light split by a beam splitter is guided to an optical fiber by a condenser lens, the end of the optical fiber facing the condenser lens is moved in the optical axis direction. A light quantity adjusting mechanism of the reference light in the light wave distance meter for adjusting the light quantity of the reference light, wherein the end of the optical fiber is integrally surrounded by a cylindrical head. A structure, which has an inner diameter that matches the outer diameter, is inserted through a cylindrical head engaging portion that is relatively slidable in the axial direction and the circumferential direction, and is fixed by a fixing screw screwed to the head engaging portion, Loosen the fixing screw, Reference light quantity adjusting mechanism of the optical distance meter fiber end faces and adjusts the amount of light by moving the head to a predetermined position deviated from the focal point of the condenser lens in the optical axis direction. 2. A lightwave rangefinder equipped with the light quantity adjusting mechanism according to claim 1, wherein said beam splitter and an end portion of a mixing optical fiber for guiding light emitted from a light emitting element to said beam splitter. A head engaging portion for connecting a head integrated with the shutter, and a shutter for selectively projecting and retracting in each of the two optical paths divided by the beam splitter to switch between the reference optical path and the distance measuring optical path. , A head engaging portion for connecting a head integrated to an end portion of an optical fiber forming an optical path for reference light is integrated as a light transmitting unit to be separated from the main body of the optical distance meter A lightwave rangefinder characterized by being formed.