JP5504189B2 - Lens meter - Google Patents

Description

  The present invention relates to a lens meter for marking a test lens.

  FIG. 7 is a diagram showing a conventional lens meter 101. In FIG. 7, a conventional lens meter 101 forms an image on a sensor with light passing through a measuring light source 102, a light projecting lens 103 for projecting light, and a lens 6 or a mask (not shown). An imaging lens 104 and an image sensor 105 that receives an image are provided. The conventional lens meter 101 includes a lens receiver 4 on which the test lens 6 is placed, a lens pressing unit 121 that presses the test lens 6 in the direction of the lens receiver 4, and a mark on the test lens 6. And a marking unit 131 for performing the above. The lens holding unit 121 and the mark point unit 131 are held so as to be vertically movable by the lift arms 111 and 112, respectively. Therefore, when holding the test lens 6, only the lens pressing unit 121 is lowered toward the test lens 6 by lowering the elevating arm 111, and the test is performed by the lens receiver 4 and the lens pressing unit 121. The lens 6 is held. When performing the marking, the marking point unit 131 is rotated until the tip of the marking point pen faces the testing lens 6, and the lifting arm 112 is further lowered to lower the testing lens 6. Mark the mark. Such a conventional lens meter 101 is described in Patent Document 1, for example.

JP 2003-83845 A

  However, in the conventional lens meter 101 shown in FIG. 7, if the lens holding unit 121 and the marking unit 131 are moved up and down by the lifting arms 111 and 112, respectively, there is a problem that the configuration of the apparatus becomes complicated accordingly. It was.

  The present invention has been made to solve the above problems, and an object thereof is to provide a lens meter having a simple configuration.

To achieve the above object, a lens meter according to the present invention includes a lens receiver on which a test lens is placed, a lens pressing unit having a lens pressing pin capable of pressing the test lens in the direction of the lens receiver, A marking point unit having a marking point pen that can be marked on the lens, and a lifting and lowering arm that holds the lens pressing unit and the marking point unit and is vertically movable. The marking point pen rotates between a retracted position retracted from the test lens placed on the lens receiver and a mark preparation position spaced upward from the mark point position for marking the test lens. The marking point unit is moved between the marking point preparation position and the marking point position by raising and lowering the lifting arm.
With such a configuration, both the lens pressing unit and the marking unit can be held by a single lifting arm, and a lens meter having a simple configuration can be realized. In addition, when the lens pressing unit is pressing the lens to be tested, the marking point unit can be turned from the retracted position to the mark preparing position, and the lifting arm is lowered to mark the test lens. become able to.

Further, in the lens meter according to the present invention, the lens pressing pin is arranged so that a gap is generated between the tip of the marking pen and the test lens when the marking unit is in the mark preparation position. It may be biased in the direction.
With such a configuration, when the mark point unit is rotated from the retracted position to the mark point preparation position, it is possible to prevent the tip of the mark point pen from hitting the lens to be tested and to perform an appropriate mark point. Will be able to.

  According to the lens meter according to the present invention, the configuration of the lens meter that marks the test lens can be simplified.

The figure which shows the external appearance of the lens meter by Embodiment 1 of this invention. The figure which shows the part of the lens holding | maintenance unit in the embodiment The figure for demonstrating the raising / lowering mechanism of the raising / lowering arm in the same embodiment The figure which shows the internal structure of the lens holding | maintenance unit and mark point unit in the embodiment The figure for demonstrating the height of the front-end | tip of the pen for mark points in the embodiment The figure for demonstrating rotation and the marking operation of the marking unit in the embodiment A diagram showing a conventional lens meter

  Hereinafter, a lens meter according to the present invention will be described using embodiments. Note that, in the following embodiments, the components given the same reference numerals are the same or equivalent, and repetitive description may be omitted.

(Embodiment 1)
A lens meter according to Embodiment 1 of the present invention will be described with reference to the drawings. The lens meter according to the present embodiment is configured to hold a lens holding unit that holds the lens to be examined and a marking unit that can be marked on the lens to be examined by a single lifting arm.

  FIG. 1 is an external view of a lens meter 1 according to this embodiment. The lens meter 1 according to the present embodiment includes a light projecting unit 2, a light receiving unit 3, a lens receiver 4 on which a test lens 6 is placed, a monitor 5, and an elevating and lowering arrangement that is vertically movable. The arm 11 includes a lens pressing unit 21 and a marking unit 31 held by the elevating arm 11. The test lens 6 may be, for example, an unprocessed lens or a frame processed lens. Moreover, in FIG. 1, only the characteristic component of the lens meter 1 by this Embodiment is shown. Therefore, it goes without saying that the lens meter 1 may include other components. For example, the lens meter 1 may include a storage unit that stores the value of the optical characteristic of the optical center of the lens 6 to be tested, a printer that prints the value of the optical characteristic, and the like.

  The light projecting unit 2 projects the measurement light emitted from the measurement light source onto the lens 6 to be tested placed on the lens receiver 4. The light projecting unit 2 may include, for example, a light source for measurement light and a light projection lens that projects diffused light emitted from the light source into parallel measurement light and projects it onto the lens 6 to be examined. The measurement light passes through the test lens 6 and the like and is received by the light receiving unit 3. The light receiving unit 3 acquires data corresponding to the received measurement light. The light receiving unit 3 includes, for example, a pattern mask through which the measurement light that has passed through the test lens 6 passes, an imaging lens that forms an image of the light that has passed through the pattern mask on the imaging sensor, and an image that has been formed. You may provide the imaging sensor for converting into an electrical signal and producing | generating image data. In addition, the lens meter 1 may have an optical characteristic calculation unit (not shown) that calculates the optical characteristic of the lens 6 to be measured using the received light image of the measurement light received by the light receiving unit 3. The received light image may be, for example, a received light image of a pattern mask. The optical characteristic calculated by the optical characteristic calculation unit may be, for example, spherical power, cylindrical power (column surface power), prism value, or any two or more of them. It may be. In addition, the optical characteristics may include an axial angle (astigmatic axis angle). Note that a method for obtaining the optical characteristics of the lens 6 to be measured using the measurement light is already known, and the description thereof is omitted. Needless to say, the optical characteristics of the lens 6 to be examined may be acquired by a method other than the above description. The optical characteristics thus acquired may be displayed on the monitor 5, for example. Further, the status of alignment of the lens 6 to be examined may be displayed on the monitor 5.

  2 is an enlarged view of the range of the lens pressing unit 21 and the marking unit 31, FIG. 3 is a diagram for explaining the lifting mechanism of the lifting arm 11, and FIG. FIG. 3 is a diagram showing an internal structure of a marking point unit 31. FIG. 5 is a diagram for explaining the height of the marking point pen 32, and FIG. 6 is a diagram for explaining the rotation and the marking operation of the marking unit 31.

  As shown in FIG. 3, the elevating arm 11 is inserted through the slit 44 of the main body frame 41. An extending portion 11 a extending in parallel with the main body frame 41 is integrally formed on the back side of the lifting arm 11 (on the side opposite to the lens pressing unit 21). The extending portion 11 a is fixed to the lifting guide 43 with screws. The elevating guide 43 is provided so as to be slidable in the vertical direction with respect to the elevating rail 42 disposed in the vertical direction of the main body frame 41. It is assumed that the lifting guide 43 is provided so that it cannot move except in the vertical direction with respect to the lifting rail 42. Therefore, the lifting arm 11 that holds the lens pressing unit 21 and the marking unit 31 can be lifted and lowered only in the vertical direction indicated by the double-headed arrow in FIG. The elevating arm 11 or the elevating guide 43 may be provided with a mechanism (not shown) that temporarily holds the raised state of the elevating arm 11. The mechanism may be, for example, a latch mechanism. For example, the raising / lowering arm 11 may be held at the raised position by the latch mechanism, and the raising / lowering arm 11 may be slightly moved in the raising direction once again, so that the latch is released and the raising / lowering arm 11 can be lowered.

  The lens holding unit 21 is held at the tip of the lifting arm 11 opposite to the extending portion 11a. That is, the lens pressing unit 21 is fixed to the tip of the lifting arm 11 with a screw. The lens pressing unit 21 is separated from the apparatus main body on the four lens pressing pins 22 projecting vertically downward, a supporting member 26 supporting the four lens pressing pins 22, and the upper surface side of the supporting member 26. And a lifting lever 23 projecting in the direction. The lens pressing pin 22 is provided so as to be movable back and forth with respect to the support member 26, and can press the lens 6 to be tested in the direction of the lens receiver 4. The fact that the lens pressing pin 22 can move forward and backward with respect to the support member 26 means that the tip of the lens pressing pin 22 can move in a direction away from the support member 26 or in the opposite direction. Further, as shown in FIG. 4, the lens pressing pin 22 is urged by a pin urging spring 24 vertically downward, that is, in the direction of the lens 6 to be examined. The lens pressing pin 22 may be biased by an elastic member other than the pin biasing spring 24, such as rubber. In the present embodiment, the case where the lens pressing unit 21 has four lens pressing pins 22 is described, but this need not be the case. The number of lens pressing pins 22 may be other than four. Further, as shown in FIG. 2, the apparatus main body side of the elevating lever 23 has a substantially U shape so as not to block the measurement light. In addition, a through hole (not shown) through which measurement light can pass is provided in the central portion of the support member 26 corresponding to the substantially U shape. When the marking unit 31 is rotated, the central marking pen 32 passes through the U-shape of the lift lever 23 and the through hole. The left and right ends of the support member 26 are provided with through holes 25 through which the marking pens 32 at both ends can pass when the marking unit 31 rotates.

  The marking unit 31 is also held at the tip of the lifting arm 11. In the present embodiment, the marking unit 31 is indirectly held at the tip of the lifting arm 11 via the lens pressing unit 21. The marking unit 31 includes a marking pen 32 that can mark the lens 6 to be tested, a pen holder 33 in which the marking pen 32 can be inserted and retracted, and a support 39 that supports the pen holder 33. And a marking point lever 34 that is provided at one end of the support portion 39 for rotating the marking point unit 31. In the present embodiment, the case where the marking unit 31 includes three marking pens 32 is described, but this need not be the case. The marking point pens 32 are usually arranged in a line evenly. The middle marking point pen 32 is used, for example, to perform a marking point indicating the optical center position of the lens 6 to be examined. The two marking point pens 32 on the left and right sides are used, for example, for marking points indicating the axial direction of cylindrical refractive power. Further, as shown in FIG. 4, the marking point pen 32 is urged by a pen urging spring 35 in the direction of the tip of the pen in the pen length direction (axial direction). That is, the marking point pen 32 is urged in the direction of the test lens 6 at the time of marking. The urging of the marking point pen 32 may be performed by an elastic member other than the pen urging spring 35, such as rubber. Further, the configuration for the marking point pen 32 to mark the lens 6 to be examined is not limited. For example, the marking point pen 32 may include an ink tank and a felt thin and soft marking point needle connected to the ink tank. Further, as shown in FIG. 5, the three marking point pens 32 may be arranged so as to substantially follow the curved shape of the marking point forming surface of the lens 6 to be examined. That is, among the three marking point pens 32, the center pen may be arranged at a position that is higher by the gap D (a position that is less projected by D) as shown in FIG. The gap D is a value that is appropriately determined according to the radius of curvature of the lens 6 to be examined, but may be approximately 3 mm, for example. Note that the configuration of such a marking unit 31 is disclosed in Patent Document 1 described above. Further, the marking unit 31 rotates around a rotation shaft 36 between a retracted position where the marking pen 32 is retracted from the lens 6 to be tested placed on the lens receiver 4 and a marking preparation position. It is provided as possible. The mark point preparation position is a position spaced upward from the mark point position where the mark point pen 32 marks the lens 6 to be examined. The rotation shaft 36 is provided on an end side of the support member 26 on the apparatus main body side. In the present embodiment, the marking unit 31 is provided so as to be rotatable with respect to the lens pressing unit 21. Since the lens pressing unit 21 is fixed to the lifting arm 11, the marking unit 31 can be rotated with respect to the lifting arm 11 as a result. In the retracted position, the length direction of the lens pressing pin 22 (usually the vertical direction and the optical axis direction of the light projecting unit 2 or the light receiving unit 3) does not match the length direction of the marking point pen 32. This is the position of the mark point unit 31 (not parallel), and is the position of the mark point unit 31 shown in FIGS. In FIG. 4, the marking unit 31 is biased in the direction of the retracted position by the torsion coil spring 37. Further, when the marking point unit 31 is in the retracted position, the end 38 a of the stopper projection 38 provided on the marking point unit 31 abuts the lens pressing unit 21, so that the marking point unit 31 exceeds that of the marking point unit 31. The rotation is restricted. The mark point preparation position is a position of the mark point unit 31 in which the length direction of the lens pressing pin 22 and the length direction of the mark point pen 32 are parallel to each other. This is the position where there is a gap between the tip. That is, the mark point preparation position is the position of the mark point unit 31 shown in FIG. When the mark point unit 31 is in the mark point preparation position, the lower surface of the support portion 39 of the mark point unit 31 and the upper surface of the support member 26 of the lens pressing unit 21 are brought into contact with each other. The above rotation is restricted. The position where the tip of the marking point pen 32 contacts the lens 6 to be examined is called a marking point position. That is, the position of the mark point unit 31 shown in FIG. 6B is the mark point preparation position, and the position of the mark point unit 31 shown in FIG. 6C is the mark point position. In addition, the position of the mark point unit 31 where the length direction of the lens pressing pin 22 and the length direction of the mark point pen 32 are parallel may be referred to as a mark point direction position. The mark point direction position is a concept including a mark point preparation position and a mark point position. The marking unit 31 moves between the marking point preparation position and the marking point position by raising and lowering the lifting arm 11. Further, the lens pressing pin 22 is provided so as to be able to advance and retreat with respect to the lens pressing unit 21 so that the marking point unit 31 can move in the vertical direction between the marking point preparation position and the marking point position. . When the mark point unit 31 is in the mark point preparation position, a gap is generated between the tip of the mark point pen 32 and the lens 6 to be examined. That is, it is assumed that the four lens pressing pins 22 are urged toward the test lens 6 so that the gap is generated. This is to prevent the tip of the marking point pen 32 from hitting the lens 6 to be tested before the marking point unit 31 is rotated to the marking point preparation position.

  Next, the operation of attaching a mark with the lens meter 1 according to the present embodiment will be described. A user (examiner) places the test lens 6 on the lens receiver 4 with the lens holding unit 21 and the like raised. Then, while holding the elevating lever 23, the lens pressing unit 21 and the like are lowered toward the test lens 6. The lens holding unit 21 and the like are lowered by its own weight. Then, as shown in FIG. 6A, the lowering of the lens pressing unit 21 and the like stops in a state where the test lens 6 is held so as to be sandwiched between the lens receiver 4 and the lens pressing pin 22. Thus, in the state where the lens 6 is held by the lens holding unit 21 and the lens receiver 4, the downward force due to the load of the lens holding unit 21 and the like and the lens pressing that comes into contact with the surface of the lens 6. The biasing force of the pin biasing spring 24 against the pin 22 is balanced. Therefore, in this state, the lens pressing pin 22 sinks slightly toward the support member 26 as compared with a state where the lens 6 to be tested is not held as shown in FIG. Let G be the depth of this subduction. In this state, the marking unit 31 is in the retracted position rotated by the urging force of the torsion coil spring 37 until the end 38 a of the stopper projection 38 contacts the lens pressing unit 21.

  Thereafter, the user moves the lens 6 to be examined while viewing the display on the monitor 5 to perform alignment or the like. When the alignment is completed, the user presses the marking lever 34 of the marking unit 31 in the direction of the arrow in FIG. Then, the marking unit 31 rotates about the rotation shaft 36 against the urging force of the torsion coil spring 37. Then, as shown in FIG. 6B, the mark unit 31 rotates to the mark preparation position until the lower surface side of the mark unit 31 contacts the upper surface side of the lens pressing unit 21. When the marking point unit 31 is rotated to the marking point preparation position, as shown in FIG. 6B, the tip of the marking point pen 32 (tip of the marking point needle) and the marking point are moved. As described above, the lens pressing pin 22 is biased in the direction of the test lens 6 so that a gap is generated between the test lens 6 and the test lens 6. By doing so, in the middle of the point marking unit 31 being rotated to the mark preparation position, the tip of the mark point pen 32 hits the test lens 6 and marks the test lens 6 at an undesired position. Can be prevented. Here, the case where the mark point unit 31 is rotated to the mark point preparation position is a case where the mark point unit 31 is only rotated to the mark point preparation position. It may be a case where the descent toward the analyzing lens 6 has not been clearly performed yet.

  After that, when the user moves the elevating arm 11 toward the test lens 6 by pressing the mark point lever 34 in the direction of the arrow shown in FIG. 6C, the lens pressing pin 22 resists the urging force. The tip of the three marking point pens 32 comes into contact with the surface of the lens 6 to be examined. The test lens 6 is marked with three mark marks. The position of the marking point unit 31 at this time is the marking point position. Therefore, when the mark unit 31 is rotated to the mark preparation position and the elevating arm 11 is lowered toward the lens 6 to be examined, the tip of the mark pen 32 and the tip of the lens pressing pin 22 are moved. It is assumed that the lens pressing pin 22 is biased in the direction of the lens to be tested so that the height can be substantially the same. Since the elevating arm 11 is lowered by H from the mark point preparation position of FIG. 6B to the mark point position of FIG. 6C, the lens pressing pin 22 is moved from the state of FIG. Further, it is configured to be able to sink at least by H. That is, when the marking is performed, the lens pressing pin 22 sinks further toward the support member 26 than in the state of FIG. Therefore, the lens pressing pin 22 has a marking point pen 32 with respect to the pen holder 33 to G + H, which is obtained by adding the depth of depression G when holding the lens 6 to be tested and the depth of depression H at the time of marking. Thus, it is configured to be capable of moving back and forth (movable) in the vertical direction by a length (stroke) that takes into account the depth of sinking and the overall play. In addition, when attaching a mark mark like FIG.6 (c), the lens holding | suppressing unit 21 will sink toward the test lens 6, and the force which fixes the test lens 6 will become strong so much. Therefore, it is possible to effectively prevent the test lens 6 from shifting at the time of marking. Further, from the mark point preparation position in FIG. 6B to the mark point position in FIG. 6C, the mark point unit 31 is manually moved toward the lens 6 while resisting the urging force of the lens pressing pin 22. Because of the movement, the impact when the tip of the marking point pen 32 comes into contact with the surface of the test lens 6 can be reduced, and the test lens 6 can be prevented from being damaged at the time of marking.

  When the user releases the downward force on the marking point lever 34 after the marking point is attached in this manner, the lifting arm 11 returns to the position of FIG. 6B by the urging force of the pin urging spring 24. . Furthermore, when the user releases the mark point lever 34, the mark point unit 31 returns to the retracted position shown in FIG. 6A due to the biasing force of the torsion coil spring 37.

  The biasing force of the torsion coil spring 37 that biases the mark unit 31 in the direction of the retracted position is weaker than the biasing force of the pin biasing spring 24 that biases the lens pressing pin 22 in the direction of the lens 6 to be examined. And Otherwise, when the mark point unit 31 is rotated, the lens pressing unit 21 is lowered toward the lens 6 to be examined.

  As described above, according to the lens meter 1 of the present embodiment, both the lens pressing unit 21 and the marking unit 31 can be supported by the single lifting arm 11. Therefore, unlike the conventional lens meter 101, it is not necessary to provide the lifting arms 111 and 112 with respect to the lens pressing unit 121 and the marking unit 131, and the configuration can be simplified. As a result, the number of parts of the lens meter 1 can be reduced, and the cost can be reduced.

  In the case of the conventional lens meter 101 shown in FIG. 7, since the marking unit 131 moves up and down separately from the lens pressing unit 121, the tip of the marking unit 131 is positioned at the lens to be tested when marking is performed. Therefore, two steps of operation, that is, an operation of rotating the mark unit 131 so as to be opposed to the position 6 and an operation of lowering the mark point unit 131 are necessary. On the other hand, in the present embodiment, since the descent of the marking unit 31 is about H in FIG. 6C, the operation for performing the marking is almost completed by the operation of rotating the marking unit 31. Thus, the operation for performing the marking is simplified. Therefore, the operability of the operation for performing the marking is improved.

  The configuration of the lens meter 1 according to the present embodiment is an example, and if the lens pressing unit 21 and the marking unit 31 are held directly or indirectly by the single lifting arm 11, It goes without saying that other configurations may be used. For example, although the case where the marking unit 31 is provided in the lens pressing unit 21 has been described in the present embodiment, the marking unit 31 may be provided directly on the lifting arm 11 instead. That is, the marking unit 31 may be provided so as to be directly rotatable with respect to the lifting arm 11.

In the present embodiment, the case where the mark point preparation position and the mark point position are different from each other has been described, but this need not be the case. The mark point preparation position and the mark point position may be the same. In this case, the mark point direction position becomes the mark point position. That is, the operation of the mark point is completed only by the operation of rotating the mark point unit 31 from the retracted position to the mark point direction position (mark point position). In this case, for example, all the test lenses 6 to be marked have the same curvature, and the length H in FIG. 6C is “0” with respect to the test lenses 6. As such, the degree of protrusion of the lens pressing pin 22 may be adjusted. Further, in this case, the lens pressing pin 22 may not be movable forward and backward with respect to the support member 26 but may be fixed.
As described above, the lens meter is capable of marking the lens to be tested, the lens holder on which the lens to be tested is placed, the lens pressing unit having the lens pressing pin capable of pressing the lens to be tested in the direction of the lens receiver. A marking point unit having a marking point pen, and a lifting and lowering arm that holds the lens pressing unit and the marking point unit and is vertically movable. The marking point unit is placed on a lens receiver. It may be provided so as to be able to rotate between a retracted position retracted from the test lens and a mark point direction position in which the mark point pen makes a mark on the test lens. The lens pressing pin is located at the mark point preparation position where the mark point unit is a position in the mark point direction and a gap exists between the lens to be tested and the tip of the mark point pen. The marking point unit is biased in the direction of the test lens so that the gap is generated, and the marking point unit is located between the marking point preparation position and the marking point position where the tip of the marking point pen contacts the testing lens. It may be provided so that it can move forward and backward so that it can move. Alternatively, the mark point preparation position and the mark point position may be the same, and the mark point direction position may be the mark point position.

  Further, the present invention is not limited to the above-described embodiment, and various modifications are possible, and it goes without saying that these are also included in the scope of the present invention.

  As described above, according to the lens meter of the present invention, an effect that a simple configuration can be obtained is obtained, and the lens meter is useful as a lens meter for marking a test lens.

DESCRIPTION OF SYMBOLS 1 Lens meter 4 Lens holder 6 Test lens 11 Lifting arm 21 Lens holding unit 22 Lens pressing pin 23 Lifting lever 24 Pin biasing spring 26 Support member 31 Marking unit 32 Marking pen 33 Pen holder 34 Marking lever 35 With pen Force spring 37 Torsion coil spring 39 Support section

Claims (2)

A lens receiver on which the test lens is placed;
A lens pressing unit having a lens pressing pin capable of pressing the test lens in the direction of the lens receiver;
A marking unit having a marking pen capable of marking on the test lens;
An elevating arm that holds the lens pressing unit and the mark point unit and is arranged so as to be vertically movable;
The marking unit includes a retracted position in which the marking pen is retracted from a test lens placed on the lens receiver, and a marking point that is spaced upward from a marking position for marking the test lens. It is provided so as to be rotatable between the preparation position and
The said mark point unit is a lens meter which moves between the said mark point preparation position and the said mark point position by raising / lowering of the said raising / lowering arm. The lens pressing pin is attached to the direction of the test lens so that a gap is formed between the tip of the mark point pen and the test lens when the mark unit is at the mark preparation position. The lens meter according to claim 1, wherein the lens meter is biased.

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