JP2009135514A - Wafer detection sensor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To solve the problem that employing a narrow-visibility type transmission sensor, a conventional wafer detection sensor projects a narrow light beam, thus requiring the adjustment of an optical axis and installment of an optical axis adjustment mechanism each at a light projection unit and a light reception unit. <P>SOLUTION: In the wafer detection sensor, a wafer 22 interrupts a light beam, and the light beam interruption is detected by the light receiving side, thus the presence of the wafer is detected. The wafer detection sensor includes: a sensor unit 1 having the light projection unit for projecting a light beam to form a projected light beam F1, and a light reception unit for receiving a received light beam F-1 as a light from a detection region; and a right-angled prism 2 for reflecting the projected light beam F1 as an incident light to form the received light beam F-1 and for changing the position of an optical axis along which the projected light beam F1 travels and the position of an optical axis along which the received light beam F-1 travels, wherein the projected light beam F1 is used for the light beam for detecting the presence of the wafer 22. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a wafer detection sensor.

  When detecting the presence / absence of a wafer in the wafer cassette, the detection is often performed by attaching a sensor on the wafer transfer arm.

  As a wafer detection sensor as a detection means, a narrow-field type (those with a small beam diameter of a light projection beam) is often used. The reason why this narrow-field type is used is to detect the wafer as the detected object without being affected by the reflected light of other wafers located above and below the wafer as the detected object in the wafer cassette. .

  That is, as shown in FIG. 11, the transmissive sensor 40 includes a light projecting unit 41 and a light receiving unit 42, and the light projecting unit 41 is held by an arm 43 as a holding body. It is held by an arm 44 as a holding body, and is relatively heeled at a predetermined interval. The light projecting beam F projected from the light projecting unit 41 is received by the light receiving unit 42.

  A plurality of wafers 45 are accommodated in a wafer cassette (not shown) so as to be able to enter and exit at a predetermined interval in the vertical direction, and the transmissive sensor 40 moves in the vertical direction at the entrance / exit of the wafer cassette. It is mounted on a movable body (not shown).

  Therefore, when the moving body moves downward, the transmission type sensor 40 moves downward at the entrance / exit of the wafer cassette.

  Due to the downward movement of the transmissive sensor 40, the end face 45A of the wafer 45 blocks the projection beam F from the side and cannot be received by the light receiving unit 42. For this reason, in the amplifier unit (not shown), the detection body It is determined that there is (wafer 45).

  However, since the above-described conventional wafer detection sensor uses a narrow-field-type transmissive sensor, the beam diameter of the projected beam F is reduced, and the optical axis needs to be adjusted. There is a problem that an optical axis adjustment mechanism must be provided at each of the two positions 42.

  On the other hand, if a reflective sensor of a type that receives light reflected from the wafer 45 by simply irradiating the wafer 45 with light from the light projecting unit is used instead of a regression type, the optical axis adjusting mechanism is used. However, there is a problem that the wafer 45 cannot be stably detected because there is a wafer having a low reflectivity depending on the surface state of the wafer 45 and a wafer 45 that absorbs a specific wavelength.

  The present invention has been made paying attention to the above-mentioned problems. The object of the present invention is to be able to reliably detect the wafer, and the optical axis adjustment mechanisms on both the light projecting and receiving sides are unnecessary, and the adjustment is made. To provide a regression type wafer detection sensor capable of reducing time.

  In order to achieve the above object, a wafer detection sensor according to the present invention is a wafer detection sensor that detects the presence or absence of a wafer by blocking the light beam by the wafer and detecting the interruption of the light beam on the light receiving side. The sensor unit includes a light projecting unit that emits a light beam to form a light projecting beam, a light receiving unit that receives a light receiving beam that is light from the detection region, and the light projecting beam is reflected as incident light. And a reflector that changes the position of the optical axis that is the traveling direction of the projected beam and the optical axis that is the traveling direction of the received beam, and projects the light beam that detects the presence or absence of the wafer It uses a beam.

  The sensor unit may be an amplifier built-in type, or the sensor unit is an optical fiber type connected to the amplifier unit by an optical fiber, and the light emitted from the light projecting element of the amplifier unit is transmitted by the light emitting side optical fiber. And you may make it radiate | emit to a reflector side as a light projection beam in a sensor part. The reflector that changes the optical axis of the light projecting beam and the optical axis of the light receiving beam is preferably a right-angle prism. The reflector may have a configuration in which two mirrors are arranged at a right angle, or the reflector may be a single mirror that changes the optical axis.

  The sensor unit is a regressive reflection type sensor unit that emits a light projecting beam from the light projecting unit and receives reflected light (light receiving beam) of the light projecting beam at the light receiving unit. In addition, the right-angle prism means that incident light is incident from (the inclined surface portion of the right-angle prism) and has a high reflectivity surface, for example, a mirror surface (one surface portion forming the right angle portion of the right-angle prism), and a high reflectivity. The light is reflected a total of twice by a surface, for example, a mirror surface (the other surface portion forming the right angle portion of the right angle prism), and the reflected light is emitted in parallel to the incident light. The built-in amplifier type is a case where the sensor unit has a built-in amplifier unit, and the optical fiber type is a case where the sensor unit is connected to the amplifier unit by an optical fiber.

  The amplifier unit includes a light projecting circuit for the light projecting element, an amplifier circuit for amplifying the light receiving signal supplied from the light receiving element, a pulse generating unit for generating a pulse in the light projecting circuit, and a light receiving signal amplified by the amplifier circuit. An output circuit that outputs a detection signal to, for example, an external output device when the comparison determination unit of the operation circuit determines that there is a detection object, and a display unit. And a power input unit.

  With this configuration, since the projection beam is close to the projection unit, the diffraction spread is still small, so that the projection beam is not so wide and the beam diameter is small. On the other hand, since the received light beam is separated from the light projecting portion, the diffraction spread is large and the light beam is widened and the beam diameter is large. When a wafer is detected with a light receiving beam in which the light beam is spread, there is reflection from other wafers located above and below the wafer that is the detection target, which adversely affects the detection of the wafer. Therefore, it is a good idea to detect the wafer with a projection beam having a small beam diameter.

  In this way, by using a projection beam with a small diffraction spread for wafer detection, the influence of other wafers positioned above and below the wafer to be detected due to the spread of the received beam after reflection by the reflector can be reduced. Thus, the detection of the wafer becomes stable, and the presence or absence of the wafer in the wafer cassette can be detected.

  In addition, when the edge of the wafer blocks the projected beam, the projected beam is reflected on the surface of the edge of the wafer, but the end surface of the wafer is not necessarily flat, that is, the end surface of the wafer in the wafer thickness direction is The shape is not limited to a straight shape and has a curvature, and the film material at the time of film formation also wraps around the end surface, so the reflectance is not necessarily high. Therefore, even when the projected beam hits the end surface of the wafer, the amount of light returning to the light receiving side is much smaller, and malfunction is difficult.

  In addition, when a right-angle prism is used as a reflector, the right-angle prism has a high dimensional accuracy. Therefore, it is basically necessary to adjust only the sensor section, which is necessary for a conventional narrow-field-type transmissive wafer detection sensor. Therefore, the adjustment of the optical axis on both the light emitting side and the light receiving side is unnecessary, and the adjustment time can be reduced.

  Further, the wafer detection sensor according to the present invention is configured such that, in the above-described wafer detection sensor according to the present invention, the sensor unit and the reflector are relatively inclined with a predetermined interval.

  With such a configuration, since only one wiring, that is, only the sensor portion is required, the wafer detection sensor can be easily attached, and the number of wiring steps can be reduced.

  Further, the wafer detection sensor according to the present invention is the above-described wafer detection sensor according to the present invention, wherein the light projecting / receiving side refracts the light projecting beam from the sensor unit toward the reflector side and is reflected from the reflector. A sensor-side prism that makes the light-receiving beam incident on the light-receiving portion of the sensor portion is included. The reflector is preferably a right angle prism.

  With this configuration, depending on the shape and arrangement of the prisms, wafer detection can be performed by using two or more prisms, and the sensor unit can also be detected from a location that is separated by some distance. In addition, since the sensor side holding body is arranged with only the sensor side prism (right angle prism) on the front side, the thickness of the sensor side holding body can be reduced, for example, for wafer detection. This is advantageous when the sensor is mounted on a robot.

  As described above, according to the wafer detection sensor of the present invention, the projection beam having a small diffraction spread is used for the detection of the wafer, so that the detection target is the detection target due to the spread of the received light beam after the reflector reflection. The influence of other wafers positioned above and below the wafer can be reduced, the detection of the wafer becomes stable, and the presence or absence of the wafer in the wafer cassette can be detected.

1 is a schematic configuration explanatory view of a wafer detection sensor (embodiment 1 for implementation) according to the present invention. FIG. It is structure explanatory drawing of the amplifier part used for the same sensor for wafer detection (embodiment 1 for implementation). It is explanatory drawing of the right-angle prism as a reflector used for the sensor for this wafer detection (form 1 for implementing). It is explanatory drawing of the detection method of the wafer accommodated in the wafer cassette. It is a schematic structure explanatory drawing of the sensor for wafer detection (embodiment 2 for carrying out) concerning the present invention. It is structure explanatory drawing of the same sensor for wafer detection (embodiment 2 for implementation). It is structure explanatory drawing of the amplifier part used for the same sensor for wafer detection (form 2 for implementing). FIG. 4 is a schematic configuration explanatory diagram of a wafer detection sensor (Embodiment 3 for implementation) according to the present invention. It is explanatory drawing of the sensor side prism used for the sensor for this wafer detection (form 3 for implementing). It is explanatory drawing of the reflector which combined two mirrors. It is a schematic structure explanatory drawing of the conventional wafer detection sensor.

  Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings.

  A first embodiment for carrying out a wafer detection sensor according to the present invention is shown in FIGS.

  The wafer detection sensor 30 according to the present invention includes a retroreflective sensor unit 1 having an optical system with a narrow field of view (a light beam of a light projection beam is small) for both projection and reception, and a high dimensional accuracy used as a reflector. It is composed of a right angle prism 2. The sensor unit 1 includes a light projecting unit that emits a light beam to form a light projecting beam, and a light receiving unit that receives a light receiving beam that is light from the detection region.

  That is, the sensor unit 1 is a built-in amplifier type and is held by the sensor side holding body 13A. On one side of the sensor body 1A of the sensor unit 1, a light projecting port part 3 that is a light projecting part and a light receiving port part 4 that is a light receiving part are provided apart from each other by a predetermined distance in the axial direction of the sensor main body 1A. is there. A light projecting element 14 is disposed in the light projecting port portion 3, and a light receiving element 16 is disposed in the light receiving port portion 4.

  In the amplifier unit 25, as shown in FIG. 2, the light projecting circuit 15 of the light projecting element 14, the amplifier circuit 17 for amplifying the light receiving signal supplied from the light receiving element 16, and the light projecting circuit 15 are pulsed. An arithmetic circuit 18 having a pulse generator (not shown) to be generated and a comparison / determination unit (not shown) for comparing and determining the received light signal amplified by the amplifier circuit 17, and a detection object in the comparison / determination unit of the arithmetic circuit 18 When it is determined that there is an output, the output unit 19 outputs a detection signal to, for example, an external output device (not shown), a display unit 20, and a power input unit 21.

  Further, the right-angle prism 2 used as the reflector is held by the reflector-side holding body 13B. In this right-angle prism 2, as shown in FIG. 3, incident light a enters from the B surface (the slope portion of the right-angle prism 2), and forms a highly reflective A surface (for example, a right-angle portion of the right-angle prism 2) that is a mirror surface. One surface portion) and a highly reflective C surface, for example, a mirror surface (the other surface portion forming the right angle portion of the right-angle prism 2) is reflected twice in total, and this reflected light b is parallel to the incident light a. Is emitted.

  The sensor unit 1 and the right-angle prism 2 are opposed to each other at a predetermined interval, and the projection beam F projected from the projection port 3 is incident on the right-angle prism 2 as incident light a from the B surface. The incident light is reflected twice by the A and C planes in total, and this reflected light b is emitted in parallel to the incident light a, so that it enters the light receiving aperture 4 as a light receiving beam F-1.

  The wafer detection sensor 30 and the wafer 22 are arranged as shown in FIGS. That is, the plurality of wafers 22 are accommodated in the wafer cassette 23 so as to be able to be taken in and out at predetermined intervals in the vertical direction.

  The wafer detection sensor 30 is mounted on a movable body (not shown) that can move in the vertical direction at the entrance / exit 24 of the wafer cassette 23.

  In this case, the wafer detection sensor 30 is a narrow field type, and the beam diameter of the projection beam F is small (the diffraction spread is small), and the received beam F-1 is smaller than the projection beam F. Since the beam diameter is wide, the projection beam F is used for detecting the wafer 22.

  Since the light projection beam F is close to the light projecting portion, the diffraction spread is still small, so that it does not spread so much and the beam diameter is small. On the other hand, since the light receiving beam F-1 is separated from the light projecting portion, the diffraction spread is large, the light beam is widened, and the beam diameter is large. When the wafer 22 is detected by the received light beam F-1 in which the light beam is spread, there is a reflection from other wafers 22 located above and below the wafer 22 that is the detection target, and the detection of the wafer 22 is adversely affected. . Therefore, it is advantageous to detect the wafer 22 with the projection beam F having a small beam diameter.

  Next, detection of the wafer 22 by the wafer detection sensor 30 configured as described above will be described.

  When the power is turned on in the amplifier unit 25, the pulse generating unit of the arithmetic circuit 18 activates the light projecting circuit 15 to generate a pulse, and based on this pulse, the light projecting element 14 is turned on to generate light. This light becomes a light projection beam F in the sensor unit 1 and is emitted from the light projection port 3 to the right-angle prism 2 side.

  The light projection beam F emitted from the light projection port 3 is incident from the B surface as incident light a in the right-angle prism 2 and is reflected a total of two times on the A surface and the C surface, and this reflected light b becomes incident light a. The light is emitted in parallel and enters the light receiving opening 4 as a light receiving beam F-1.

  The light receiving beam F-1 is received by the light receiving element 16. The light receiving element 16 photoelectrically converts the light received and outputs it as a light receiving signal. The light receiving signal is amplified by the amplifier circuit 17 and sent to the arithmetic circuit 18.

  Since the wafer detection sensor 30 is mounted on a movable body that can move in the vertical direction at the entrance / exit 24 of the wafer cassette 23, the wafer detection sensor 30 is moved as shown in FIG. Move downward as indicated by the arrow.

  Due to the downward movement of the wafer detection sensor 30, the end face 22A of the wafer 22 blocks the projection beam F from the side. For this reason, the received light beam F-1 is not generated, and the comparison / determination unit of the arithmetic circuit 18 determines that there is a detection body (wafer 22), and a detection signal is sent to the output unit 19, and the display unit 20 In, the detection state of the detection body (wafer 22) is displayed.

  As described above, since the positional relationship between the wafer detection sensor 30 and the wafer 22 is arranged as shown in FIG. 1, the projection beam F having a small beam diameter is used for the detection of the wafer 22. The influence of the other wafers 22 positioned above and below the wafer 22 that is the detection target due to the spread of the received light beam F-1 after being reflected by the prism 2 can be reduced. For this reason, the detection of the wafer 22 becomes stable, and the presence or absence of the wafer 22 in the wafer cassette 23 can be detected without impairing the detection performance of the narrow view type.

  Further, when the end face 22A of the wafer 22 blocks the projection beam F, the projection beam F is reflected on the surface of the end face 22A of the wafer 22, but the end face 22A of the wafer 22 is not necessarily flat, that is, the wafer thickness. In the direction, the end surface 22A of the wafer 22 is not necessarily a straight shape but has a curvature, and since the film material at the time of film formation also wraps around the end surface 22A, the reflectance is not necessarily high. Therefore, even when the projected beam F hits the end face 22A of the wafer 22, the amount of light returning to the light receiving side is much smaller, and this prevents the sensor unit 1 from malfunctioning.

  Further, since the sensor 30 for wafer detection has a configuration in which the sensor unit 1 and the right-angle prism 2 are inclined relative to each other at a predetermined interval, only one of the wirings, that is, the sensor unit 1 is necessary. The sensor 30 can be easily attached and wiring man-hours can be reduced. Moreover, since the dimensional accuracy of the right-angle prism 2 is high, adjustment of only the sensor unit 1 is basically required, and the light projecting and receiving sides required for the conventional narrow-field transmissive type wafer detection sensor are required. Both optical axis adjustments are unnecessary, and the optical axis adjustment time is shortened.

  A second embodiment for implementing the wafer detection sensor according to the present invention is shown in FIGS.

  The wafer detection sensor 30 according to the present invention includes a retroreflective sensor unit 1 having an optical system with a narrow field of view (one with a small beam diameter of the projected beam) for both projection and reception, and a dimensional accuracy used as a reflector. It is composed of a high-angle prism 2.

  That is, the sensor unit 1 is an optical fiber type connected to the amplifier unit 25-1 by an optical fiber, and is held by the sensor side holding body 13A. That is, as shown in FIG. 6, in the sensor body 1A of the sensor unit 1, a light projecting side optical fiber insertion hole 3A and a light receiving side optical fiber insertion hole 4A are formed in parallel along the axial direction. A light projecting port portion 3 and a light receiving port portion 4 are provided on one side surface of the sensor main body 1A along a direction perpendicular to the axial direction of the sensor main body 1A. The light receiving port 4 is orthogonal to the light receiving side optical fiber insertion hole 4A.

  Further, a light projection side mirror 6 is mounted on the orthogonal portion 5 between the light projection port portion 3 and the light projection side optical fiber insertion hole portion 3A, and the orthogonal portion between the light reception port portion 4 and the light reception side optical fiber insertion hole portion 4A. 7, a light receiving side mirror 8 is mounted.

  The light projecting side optical fiber insertion hole 3A has a light projecting side optical fiber 10 having a light projecting lens 9 inserted at the tip, and the light receiving side optical fiber insertion hole 4A has a light receiving lens 11 at the front end. A light receiving side optical fiber 12 is inserted.

  The projecting and receiving optical fibers 10 and 12 are connected to an amplifier unit 25-1 shown in FIG. The amplifier unit 25-1 receives light emitted from the light projecting element (light emitting element) 14 that makes light incident on the light projecting side optical fiber 10, the light projecting circuit 15 of the light projecting element 14, and the light receiving side optical fiber 12. A light receiving element 16 that receives and photoelectrically converts light, an amplifier circuit 17 that amplifies a light reception signal supplied from the light receiving element 16, a pulse generator (not shown) that generates a pulse in the light projecting circuit 15, and an amplifier circuit 17. When the arithmetic circuit 18 having a comparison / determination unit (not shown) that compares and determines the amplified light reception signal and the comparison / determination unit of the arithmetic circuit 18 determine that there is a detection object, the detection signal is, for example, It has the output part 19, the display part 20, and the power supply input part 21 which output to an external output apparatus (not shown).

  Further, the right-angle prism 2 used as the reflector is held by the reflector-side holding body 13B. In this right-angle prism 2, the incident light a is incident from the B surface, reflected by the A surface and the C surface twice in total, and the reflected light b is emitted in parallel to the incident light a.

  The sensor unit 1 and the right-angle prism 2 are opposed to each other at a predetermined interval, and the projection beam F projected from the projection port 3 is incident on the right-angle prism 2 as incident light a from the B surface. The incident light is reflected twice by the A and C planes in total, and this reflected light b is emitted in parallel to the incident light a, so that it enters the light receiving aperture 4 as a light receiving beam F-1. Since the other configuration is the same as that of the first embodiment for carrying out the present invention, the description thereof is omitted.

  Next, detection of the wafer 22 by the wafer detection sensor 30 configured as described above will be described.

  When the power is turned on in the amplifier unit 25-1, the pulse generating unit of the arithmetic circuit 18 activates the light projecting circuit 15 to generate a pulse, and based on this pulse, the light projecting element 14 is turned on to generate light. . This light is transmitted by the light projecting side optical fiber 10 and converged from the light projecting lens 9 in the sensor unit 1 to become a light projecting beam F. The light projecting beam F is refracted at right angles by the light projecting side mirror 6 and then emitted from the light projecting opening 3 to the right angle prism 2 side.

  The light projection beam F emitted from the light projection port 3 is incident from the B surface as incident light a in the right-angle prism 2 and is reflected a total of two times on the A surface and the C surface, and this reflected light b becomes incident light a. The light is emitted in parallel and enters the light receiving opening 4 as a light receiving beam F-1.

  The light receiving beam F-1 is refracted at right angles by the light receiving side mirror 8, and then enters the light receiving lens 11 to become parallel light. This parallel light is transmitted to the light receiving side optical fiber 12 and received by the amplifier unit 25-1. Light is received by the element 16. The light receiving element 16 photoelectrically converts the light received and outputs it as a light receiving signal. The light receiving signal is amplified by the amplifier circuit 17 and sent to the arithmetic circuit 18.

  Since the wafer detection sensor 30 is mounted on a movable body that can move in the vertical direction at the entrance / exit 24 of the wafer cassette 23, the wafer detection sensor 30 is moved downward by moving the movable body downward. Moving.

  Due to the downward movement of the wafer detection sensor 30, the end face 22A of the wafer 22 blocks the projection beam F from the side. For this reason, the received light beam F-1 is not generated, and the comparison / determination unit of the arithmetic circuit 18 determines that there is a detection body (wafer 22), and a detection signal is sent to the output unit 19, and the display unit 20 In, the detection state of the detection body (wafer 22) is displayed.

  As described above, since the positional relationship between the wafer detection sensor 30 and the wafer 22 is arranged as shown in FIG. 5, the projection beam F having a small beam diameter is used for the detection of the wafer 22. The influence of the other wafers 22 positioned above and below the wafer 22 that is the detection target due to the spread of the received light beam F-1 after being reflected by the prism 2 can be reduced. For this reason, the detection of the wafer 22 becomes stable, and the presence or absence of the wafer 22 in the wafer cassette 23 can be detected.

  Further, when the end face 22A of the wafer 22 blocks the light projection beam F, the light projection beam F is reflected on the surface of the end face 22A of the wafer 22, but is the same as in the case of the first embodiment for carrying out the present invention. In addition, the amount of light returning to the light receiving side is much less, and this prevents the sensor unit 1 from malfunctioning.

  Further, since the sensor 30 for wafer detection has a configuration in which the sensor unit 1 and the right-angle prism 2 are relatively inclined with a predetermined interval, as in the case of the first embodiment for carrying out the present invention described above. The wafer detection sensor 30 can be easily attached and the number of wiring steps can be reduced. In addition, since the right-angle prism 2 has high dimensional accuracy, basically only the sensor unit 1 needs to be adjusted. Both the projection and light-receiving sides required in the conventional narrow-field-type transmission type wafer detection sensor are required. The optical axis adjustment is unnecessary, and the optical axis adjustment time is shortened.

  FIG. 8 and FIG. 9 show a third embodiment for carrying out the wafer detection sensor according to the present invention.

  Form 3 for carrying out the wafer detection sensor 30 according to the present invention is such that a right-angle prism 31 as a sensor-side prism and a sensor section 32 are arranged on the light-projecting and light-receiving sides, and a right-angle prism as a reflector-side prism as a reflector. 33 is arranged.

  That is, the right-angle prism 31 used on the light projection and light reception side of the wafer detection sensor 30 is used as a 90-degree reflection prism. That is, as shown in FIG. 9, in this 90-degree reflecting prism, light enters perpendicularly to the C surface (the other surface portion forming the right angle portion of the right angle prism 31) and is incident on the B surface (the inclined surface portion of the right angle prism 31). The light is reflected and emitted perpendicularly to the A surface (one surface portion forming the right angle portion of the right angle prism 31). The sensor unit 32 has the same configuration as the sensor unit 1 in the first or second embodiment for implementing the wafer detection sensor according to the present invention.

  And the right-angle prism 31 and the sensor part 32 are arrange | positioned at the front part and base part of 13 A of sensor side holders. That is, the right-angle prism 31 has its A surface opposed to the B-surface of the right-angle prism 33 held by the reflector-side holding body 13B. It is provided on the sensor side holding body 13 </ b> A so as to face the C surface of 31.

  Therefore, the light emitted from the light projection port 3 is incident from the C surface as the incident light a and reflected by the B surface at the right angle prism 31, and the reflected light b is perpendicular to the incident light a from the A surface. The light is emitted to become a projection beam F. The projection beam F is incident on the right-angle prism 33 as incident light a ′ from the B surface and reflected by the A and C surfaces twice in total. The reflected light b ′ is emitted in parallel to the incident light a ′ and received. Beam F-1.

  The light beam F-1 is incident on the right-angle prism 31 as incident light a "from the A surface and reflected by the B surface, and the reflected light b" is perpendicular to the incident light a "from the C surface. The light is emitted, enters the light receiving opening 4, and is processed in the amplifier section 25 or 25-1 in the same manner as the sensor section 1 in the embodiment 1 or 2 for implementing the wafer detection sensor according to the present invention described above.

  Since the wafer detection sensor 30 is mounted on a movable body that can move in the vertical direction at the entrance / exit 24 of the wafer cassette 23, the wafer detection sensor 30 is moved downward by moving the movable body downward. Moving.

  Due to the downward movement of the wafer detection sensor 30, the end face 22A of the wafer 22 blocks the projection beam F from the side. For this reason, the received light beam F-1 is not generated, and the comparison / determination unit of the arithmetic circuit 18 determines that there is a detection body (wafer 22), and a detection signal is sent to the output unit 19, and the display unit 20 In, the detection state of the detection body (wafer 22) is displayed.

  Since the positional relationship between the wafer detection sensor 30 and the wafer 22 is arranged as shown in FIG. 8 as described above, the light projection beam F having a small beam diameter is used for the detection of the wafer 22. The influence of the other wafers 22 positioned above and below the wafer 22 that is the detection target due to the spread of the received light beam F-1 after being reflected by the prism 33 can be reduced. For this reason, the detection of the wafer 22 becomes stable, and the presence or absence of the wafer 22 in the wafer cassette 23 can be detected.

  Further, when the end face 22A of the wafer 22 blocks the light projection beam F, the light projection beam F is reflected on the surface of the end face 22A of the wafer 22, but is the same as in the case of the first embodiment for carrying out the present invention. In addition, the amount of light returning to the light receiving side is much less, and the sensor unit 1 does not malfunction.

  Further, in the third embodiment for implementing the wafer detection sensor 30 according to the present invention, on the light projecting and light receiving side, the sensor unit 32 and the light projection beam F from the sensor unit 32 are applied to the right-angle prism 33 as a reflector. A right-angle prism 31 that refracts the light and reflects the light-receiving beam F-1 reflected from the right-angle prism 33 to the light-receiving opening 4 of the sensor unit 32 is disposed, and the right-angle prism 33 is disposed as a reflector. In addition, depending on the shape and arrangement of the prisms, it is possible to detect the wafer 22 by using two or more prisms, and it is also possible to detect the sensor unit 32 from a location separated to some extent. Moreover, since only the right-angle prism 31 is arranged on the front side of the sensor side holding body 13A, the thickness of the sensor side holding body 13A can be reduced. For example, the wafer detection sensor 30 can be reduced. This is advantageous when the is mounted on a robot.

  In the first, second, and third embodiments for implementing the wafer detection sensor according to the present invention described above, the right-angle prisms 2 and 33 are used as the reflectors, but the two mirrors 35 as shown in FIG. It is also possible to use a configuration in which 36 is arranged at a right angle, or a single mirror that changes the optical axis may be used as a reflector.

  The present invention can reduce the influence of other wafers positioned above and below the wafer to be detected due to the spread of the received light beam after the reflector reflection by using a projection beam with a small diffraction spread for wafer detection. Thus, the detection of the wafer becomes stable and the presence or absence of the wafer in the wafer cassette can be detected, which is suitable for a wafer detection sensor or the like.

DESCRIPTION OF SYMBOLS 1 Sensor part 1A Sensor main body 2 Right angle prism (reflector)
3 Light emitting part (lighting part)
3A Emitting-side optical fiber insertion hole 4 Receiving port (receiving unit)
4A Light receiving side optical fiber insertion hole 5 Orthogonal part 6 Light emitting side mirror 7 Right angle part 8 Light receiving side mirror 9 Light emitting lens 10 Light emitting side optical fiber 11 Light receiving lens 12 Light receiving side optical fiber 13A Sensor side holding body 13B Reflector side holding body 14 Throw Optical element 15 Light projecting circuit 16 Light receiving element 17 Amplifying circuit 18 Arithmetic circuit 19 Output unit 20 Display unit 21 Power supply input unit 22 Wafer (detector)
22A End face 23 Wafer cassette 24 Entrance / exit 25 Amplifier section 25-1 Amplifier section 30 Wafer detection sensor 31 Right angle prism (sensor side prism)
32 Sensor unit 33 Right angle prism (reflector side prism)
F Light projecting beam F-1 Light receiving beam

Claims (6)

A wafer detection sensor for detecting the presence or absence of the wafer by detecting a blocking of the light beam on a light receiving side by the wafer blocking the light beam,
A sensor unit including a light projecting unit that emits the light beam to form a light projecting beam, and a light receiving unit that receives a light receiving beam that is light from the detection region;
A reflector that reflects the projected light as incident light to form the received light beam and changes a position of an optical axis that is a traveling direction of the projected light beam and an optical axis that is a traveling direction of the received light beam; ,
A wafer detection sensor using the light projection beam as the light beam for detecting the presence or absence of the wafer.   The wafer detection sensor according to claim 1, wherein the sensor unit and the reflector are configured to be relatively inclined with a predetermined interval.   The sensor for wafer detection according to claim 1, wherein the sensor unit is an amplifier built-in type.   The sensor unit is an optical fiber type connected to an amplifier unit by an optical fiber, and the light emitted from the light projecting element of the amplifier unit is transmitted by a light-projecting side optical fiber, and the reflector is used as the light projection beam in the sensor unit The wafer detection sensor according to claim 1, wherein the sensor is emitted to the side.   The light projecting / receiving side has a sensor-side prism that refracts the light projection beam from the sensor unit toward the reflector side and makes the light reception beam reflected from the reflector enter the light receiving unit of the sensor unit. The wafer detection sensor according to claim 1 or claim 3 or claim 4.   6. The wafer detection sensor according to claim 1, wherein the reflector is a right angle prism.