CN211086117U - Detection device and silicon wafer sorting equipment - Google Patents

Abstract

The utility model provides a detection device, including conveying mechanism and two sets of detection mechanism that are used for carrying the object that awaits measuring, first group's detection mechanism is configured to detect the first edge and the upper surface of the object that awaits measuring, second group's detection mechanism is configured to detect the second edge and the lower surface of the object that awaits measuring, first edge and second edge be on the object that awaits measuring relative and with two perpendicular edges of conveying mechanism's direction of delivery, every detection mechanism of group all includes the detection camera, the surface irradiation light source, edge irradiation light source and reflection mechanism, wherein, to every detection mechanism of group: the reflection mechanism reflects light rays emitted by the surface irradiation light source and the edge irradiation light source at least once so that light reflected by the detected surface of the object to be detected and light reflected by the detected edge can be detected by the corresponding detection camera. In the transportation process, the utility model discloses need not rotate the object that awaits measuring and can realize the detection to two edges of the perpendicular to conveying mechanism's of the object that awaits measuring direction and the upper and lower surface of the object that awaits measuring to promote detection efficiency, reduced the detection cost.

Description

Detection device and silicon wafer sorting equipment

Technical Field

The utility model belongs to silicon chip detection area especially relates to a detection device and silicon chip sorting facilities.

Background

Silicon wafer edge detection and contamination detection are essential steps in the silicon wafer detection process. The traditional silicon wafer detection device comprises a first edge detection device, a second edge detection device and a contamination detection device, wherein the first edge detection device and the second edge detection device are arranged on the side edge of a conveying line, the first edge detection device is used for detecting two side edges parallel to the conveying direction of a silicon wafer, after the conveying line conveys the silicon wafer to a station of the second edge detection device, the silicon wafer is rotated by 90 degrees, and the second edge detection device detects the two remaining side edges of the silicon wafer which are not detected; the contamination detection devices are respectively arranged above and below the conveying line to detect contamination of the upper surface and the lower surface of the silicon wafer conveyed by the conveying line.

Therefore, the traditional silicon wafer detection needs a large number of detection devices, and the cost is high. In addition, during the transmission of the silicon wafer, the detection device can only detect two sides of the silicon wafer parallel to the conveying line, if the other two sides of the silicon wafer are perpendicular to the conveying line, the silicon wafer must be rotated by 90 degrees, and the rotation process greatly reduces the detection efficiency.

SUMMERY OF THE UTILITY MODEL

To the above-mentioned technical defect that traditional detection device exists, the utility model discloses the first aspect provides a detection device that detects comprehensively is carried out to high-efficient automatic low-cost, and its technical scheme is as follows:

a detection device comprises a conveying mechanism and two groups of detection mechanisms, wherein the conveying mechanism is used for conveying an object to be detected, the first group of detection mechanisms are configured to detect a first edge and an upper surface of the object to be detected, the second group of detection mechanisms are configured to detect a second edge and a lower surface of the object to be detected, the first edge and the second edge are two opposite edges of the object to be detected and are perpendicular to the conveying direction of the conveying mechanism, each group of detection mechanisms comprises a detection camera, a surface irradiation light source, an edge irradiation light source and a reflection mechanism, and the detection mechanism comprises a detection camera, a surface irradiation light source, an edge irradiation light source and a reflection:

the reflection mechanism is configured to reflect the surface illumination light emitted by the surface illumination light source at least once, so that the surface illumination light is detected by the corresponding detection camera after being reflected by the detected surface of the object to be detected;

the reflection mechanism is used for reflecting the edge irradiation light emitted by the edge irradiation light source at least once so that the edge irradiation light is detected by the corresponding detection camera after being reflected by the detected edge of the object to be detected.

Through the cooperation of the detection mechanism of first group detection mechanism and second group, in transportation process, need not rotate the object that awaits measuring, the utility model discloses can realize the detection to two edges of the perpendicular to conveying mechanism's of the object that awaits measuring conveying direction and the upper and lower surface of the object that awaits measuring, detection efficiency can effectively improve, has reduced the detection cost simultaneously.

Further, for each group of detection mechanisms, the optical path length of the surface illumination light reflected from the detected surface of the object to be detected to the corresponding detection camera is equal to the optical path length of the edge illumination light reflected from the detected edge of the object to be detected to the corresponding detection camera.

For each group of detection mechanisms, the optical path between the surface of the object to be detected and the detection camera is equal to the optical path between the edge of the object to be detected and the detection camera. Therefore, in the detection process, the detection camera does not need to be focused, and continuous and clear imaging of the detection camera to the detected surface and the detection edge of the object to be detected can be realized, so that the detection efficiency and the detection effect are improved.

Furthermore, a detection camera of the first group of detection mechanisms is positioned above the conveying mechanism, a surface irradiation light source of the first group of detection mechanisms is positioned between the detection camera of the first group of detection mechanisms and the conveying mechanism, and an edge irradiation light source of the first group of detection mechanisms is positioned above or below the conveying mechanism; the detection camera of the second group of detection mechanism is positioned below the conveying mechanism, the surface irradiation light source of the second group of detection mechanism is positioned between the detection camera of the second group of detection mechanism and the conveying mechanism, and the edge irradiation light source of the second group of detection mechanism is positioned above or below the conveying mechanism.

Through setting up second detection mechanism, the first detection mechanism of organizing, realized in the transmission course to two edges of the perpendicular to conveying direction of conveying mechanism of the object that awaits measuring and the continuous detection of the upper and lower surface of the object that awaits measuring.

Furthermore, the edge irradiation light source and the surface irradiation light source of the first group of detection mechanism and the surface irradiation light source and the edge irradiation light source of the second group of detection mechanism are sequentially arranged from front to back along the conveying direction of the conveying mechanism, the first edge is the front end edge of the object to be detected, the second edge is the rear end edge of the object to be detected, and the conveying mechanism conveys the object to be detected from back to front. When the object to be detected is conveyed to the second detection position, the second group of detection mechanisms detect the edge of the rear end of the object to be detected, and when the object to be detected is conveyed to the position right above the surface irradiation light source of the second group of detection mechanisms, the second group of detection mechanisms detect the lower surface of the object to be detected; when the object to be detected is conveyed to the position under the surface irradiation light source of the first group of detection mechanisms, the second group of detection mechanisms detect the upper surface of the object to be detected, and when the object to be detected is conveyed to the first detection position, the first group of detection mechanisms detect the front end edge of the object to be detected.

Through setting up second detection mechanism, the first detection mechanism of group, the object that awaits measuring is from the back to preceding conveying process, and second detection mechanism, the detection to the rear end edge, lower surface, upper surface, the front end edge of object that awaits measuring can be realized in proper order, continuously to detection efficiency has been guaranteed.

Furthermore, the surface irradiation light source and the edge irradiation light source of the first group of detection mechanism and the edge irradiation light source and the surface irradiation light source of the second group of detection mechanism are sequentially arranged from front to back along the conveying direction of the conveying mechanism, the first edge is the rear end edge of the object to be detected, the second edge is the front end edge of the object to be detected, and the conveying mechanism conveys the object to be detected from back to front. When the object to be detected is conveyed to the position right above the surface irradiation light source of the second group of detection mechanisms, the second group of detection mechanisms detect the lower surface of the object to be detected, when the object to be detected is conveyed to the fourth detection position, the second group of detection mechanisms detect the front end edge of the object to be detected, when the object to be detected is conveyed to the third detection position, the first group of detection mechanisms detect the rear end edge of the object to be detected, and when the object to be detected is conveyed to the position right below the surface irradiation light source of the first group of detection mechanisms, the first group of detection mechanisms detect the upper surface of the object to be; the third detection position and the fourth detection position are the same or different in position on the conveying mechanism.

Through setting up second detection mechanism, the first detection mechanism of group, the object that awaits measuring is from the back to preceding conveying process, and second detection mechanism, the first detection mechanism of group can realize in proper order, continuously that the lower surface, the front end edge, the rear end edge, the upper surface of object that awaits measuring detect in succession, comprehensively, have guaranteed detection efficiency.

Furthermore, the edge irradiation light source and the surface irradiation light source of the second group of detection mechanism and the surface irradiation light source and the edge irradiation light source of the first group of detection mechanism are sequentially arranged from front to back along the conveying direction of the conveying mechanism, the first edge is the rear end edge of the object to be detected, the second edge is the front end edge of the object to be detected, and the conveying mechanism conveys the object to be detected from back to front. When the object to be detected is conveyed to the first detection position, the first group of detection mechanisms detect the edge of the rear end of the object to be detected, and when the object to be detected is conveyed to the position right below the surface irradiation light source of the first group of detection mechanisms, the first group of detection mechanisms detect the upper surface of the object to be detected; when the object to be detected is conveyed to the position right above the surface irradiation light source of the second group of detection mechanisms, the second group of detection mechanisms detect the lower surface of the object to be detected, and when the object to be detected is conveyed to the second detection position, the second group of detection mechanisms detect the front end edge of the object to be detected.

Through setting up first set of detection mechanism, second set of detection mechanism, the object that awaits measuring is from the back to preceding conveying process, and first set of detection mechanism, second set of detection mechanism can realize in proper order, continuously the detection to the rear end edge, upper surface, lower surface, the front end edge of object that awaits measuring, have guaranteed detection efficiency.

Furthermore, the surface irradiation light source and the edge irradiation light source of the second group of detection mechanism and the edge irradiation light source and the surface irradiation light source of the first group of detection mechanism are sequentially arranged from front to back along the conveying direction of the conveying mechanism, the first edge is the front end edge of the object to be detected, the second edge is the rear end edge of the object to be detected, and the conveying mechanism conveys the object to be detected from back to front. When the object to be detected is conveyed to the position right below the surface irradiation light source of the first group of detection mechanisms, the first group of detection mechanisms detect the upper surface of the object to be detected, when the object to be detected is conveyed to the third detection position, the first group of detection mechanisms detect the front end edge of the object to be detected, when the object to be detected is conveyed to the fourth detection position, the second group of detection mechanisms detect the rear end edge of the object to be detected, and when the object to be detected is conveyed to the position right above the surface irradiation light source of the second group of detection mechanisms, the first group of detection mechanisms detect the lower surface of the object to be; the third detection position and the fourth detection position are the same or different in position on the conveying mechanism.

Through setting up first set of detection mechanism, second set of detection mechanism, the object that awaits measuring is from the back to preceding conveying process, and first set of detection mechanism, second set of detection mechanism can realize in proper order, continuously that the continuous detection to the upper surface of the object that awaits measuring, front end edge, rear end edge, lower surface has guaranteed detection efficiency.

Further, for each group of detection devices, the reflection mechanism comprises a surface light reflection mechanism, an edge light reflection mechanism and a light path integration mechanism, wherein: the surface light reflection mechanism is configured to reflect the surface irradiation light emitted by the surface irradiation light source to the optical path integration mechanism; the edge light reflecting mechanism is configured to reflect the edge irradiation light rays emitted by the edge irradiation light source to the light path integrating mechanism; the light path integration mechanism is configured to reflect the surface irradiation light reflected to the light path integration mechanism to the detection camera according to a preset light path; the light path integration mechanism is configured to transmit the edge illumination light reflected to the light path integration mechanism to the detection camera according to a preset light path.

Through setting up light path integration mechanism, can realize that the surface irradiation light of surface light reflex mechanism output reflects to detecting the camera according to predetermineeing the light path, can realize again that the edge irradiation light of edge light reflex mechanism output transmits to detecting the camera according to predetermineeing the light path promptly vertical direction. Thereby realizing that: in the detection process, the continuous imaging of the surface to be detected of the object to be detected and the edge to be detected of the object to be detected can be ensured without adjusting the field angle of the camera to be detected.

Further, the light path integration mechanism comprises a transflective lens, the transflective lens is arranged between the detection camera and the surface irradiation light source, the reflecting surface of the transflective lens faces the detection camera, and the light transmitting surface of the transflective lens faces the surface irradiation light source; the surface light reflection mechanism is configured to reflect the surface irradiation light emitted by the surface irradiation light source to the reflection surface of the transflective lens, and the surface irradiation light is reflected to the reflection surface of the transflective lens and then is reflected to the detection camera through the reflection surface of the transflective lens; the edge light reflection mechanism is configured to reflect edge illumination light rays emitted by the edge illumination light source to the light transmission surface of the reflecting mirror, and the edge illumination light rays directly penetrate through the reflecting mirror and enter the detection camera after being reflected to the light transmission surface of the reflecting mirror.

The realization mode of the light path integration mechanism with simple structure is provided, and the transflective lens is arranged in the detection device, so that the surface irradiation light output by the surface light reflection mechanism and the edge irradiation light output by the edge light reflection mechanism can enter the detection camera through the transflective lens.

Further, the surface light reflection mechanism comprises a surface incidence reflector and a surface exit reflector set, the surface exit reflector set comprises at least one surface exit reflector, the surface irradiation light source emits surface irradiation light to the detected surface, the surface incidence reflector receives the surface irradiation light reflected by the detected surface and reflects the surface irradiation light to the surface exit reflector set, and the surface emission reflector set reflects the surface irradiation light to the light path integration mechanism; the edge light reflecting mechanism comprises an edge incident reflector and an edge emergent reflector set, the edge emergent reflector set comprises at least one edge emergent reflector, an edge irradiation light source emits edge irradiation light to the detected edge, the edge incident reflector receives the edge irradiation light reflected by the detected edge and reflects the edge irradiation light to the edge emergent reflector set, and the edge irradiation light is reflected to the light path integrating mechanism by the edge emergent reflector set; or the edge incident reflector receives the edge irradiation light emitted by the edge irradiation light source, reflects the edge irradiation light to the detected edge, reflects the edge irradiation light to the edge emergent reflector group by the detected edge, and reflects the edge irradiation light to the light path integration mechanism by the edge emergent reflector group.

The surface light reflection mechanism and the edge light reflection mechanism are arranged, so that the surface irradiation light reflected by the detected surface and the edge irradiation light reflected by the detected edge are reflected to the light path integration mechanism.

The utility model discloses the second aspect provides a silicon chip sorting facilities, and this silicon chip sorting facilities includes the utility model discloses the detection device that the first aspect provided, wherein the object that awaits measuring is the silicon chip.

The utility model discloses a silicon chip sorting facilities has silicon chip detection function and silicon chip concurrently and selects separately the function, and it has promoted the sorting efficiency of silicon chip.

Drawings

Fig. 1 is a schematic perspective view of a detection device according to an embodiment of the present invention;

FIG. 2 is a perspective view of the detecting device of FIG. 1 with a sealing plate of a first set of detecting mechanisms removed;

FIG. 3 is a perspective view of the inspection device of FIG. 1 with a cover plate of the second set of inspection mechanisms removed;

fig. 4 is a schematic structural diagram of two sets of detection mechanisms in the first embodiment of the present invention;

fig. 5 is a schematic structural diagram of two sets of detection mechanisms in a second implementation of the present invention;

fig. 6 is a schematic structural diagram of two sets of detection mechanisms in a third embodiment of the present invention;

fig. 7 is a schematic structural diagram of two sets of detection mechanisms in a fourth implementation of the present invention;

Detailed Description

In order to make the above objects, features and advantages of the present invention more comprehensible, the present invention is described in detail with reference to the accompanying drawings and the detailed description.

Before this, the following technical terms mentioned in the present specification are explained:

a reflector: i.e. a common total reflection mirror.

A double-reflection mirror: which has two opposing light-reflecting surfaces.

A transflective mirror: it has two opposite surfaces, one of which is a light-reflecting surface (equivalent to a common reflector) and the other of which is a light-transmitting surface through which light can directly pass through the mirror.

Fig. 1 is a schematic perspective view of a detection device according to an embodiment of the present invention;

FIG. 2 is a perspective view of the detecting device of FIG. 1 with a sealing plate of a first set of detecting mechanisms removed;

FIG. 3 is a perspective view of the inspection device of FIG. 1 with a cover plate of the second set of inspection mechanisms removed;

as shown in fig. 1 to 3, the inspection apparatus of this embodiment includes a conveying mechanism 1 for conveying an object to be inspected, and two sets of inspection mechanisms, a first set of inspection mechanisms 2 being configured to inspect a first edge and an upper surface of the object to be inspected 5, and a second set of inspection mechanisms 3 being configured to inspect a second edge and a lower surface 54 of the object to be inspected 5, each set of inspection mechanisms including an inspection camera 41, a surface irradiation light source 44, an edge irradiation light source 42, and a reflection mechanism 43. The first edge and the second edge are two opposite edges of the object 5 to be measured, which are perpendicular to the conveying direction of the conveying mechanism 1, such as an edge 51 and an edge 52 in fig. 1.

It should be noted that the surface illumination light source 55 and the edge illumination light source 42 in this application may be a common light source, a laser, etc., and the specific type and wavelength of the light source are not limited.

The reflection mechanism 43 is configured to reflect the surface irradiation light emitted from the surface irradiation light source 44 at least once, so that the surface irradiation light is detected by the corresponding detection camera 41 after being reflected by the detected surface of the object 5 to be detected. The reflection mechanism 43 is further configured to reflect the edge illumination light emitted from the edge illumination light source 42 at least once, so that the edge illumination light is detected by the corresponding detection camera 41 after being reflected by the detected edge of the object 5 to be detected. The object 5 to be measured is a silicon wafer or other sheet-like member, and in this embodiment, the object 5 to be measured is a silicon wafer as an example.

In this embodiment, the conveying mechanism 1 includes a support structure 11, a conveying belt 12, and a driving portion that drives the conveying belt 12 to convey. The supporting structure 11 comprises a supporting plate and a supporting vertical frame, the supporting vertical frame is used for installing the supporting plate, the supporting plate is horizontally arranged, the conveying belts 12 are arranged on the supporting plate through belt wheels, the number of the conveying belts can be two, the two conveying belts are parallel to each other and are arranged at a preset distance, the object 5 to be detected is horizontally placed on the two conveying belts 12 for conveying, a transmission hole for light rays to pass through is formed in the supporting plate of the conveying mechanism 1, and the light rays can pass through the transmission hole and the interval between the two conveying belts 12 and then are emitted to the object 5 to; the drive may be a motor which is in driving connection with the conveyor belt 12 via a pulley.

In this embodiment, the detection device further includes side edge detection mechanisms (not shown) disposed at two sides of the conveying mechanism 1, the two side edge detection mechanisms respectively correspond to two side edges of the object 5 to be detected on the conveying belt 12, so as to detect the two side edges of the object 5 to be detected respectively, the two side edges are two opposite edges of the object 5 to be detected and parallel to the conveying direction of the conveying mechanism 1, each side edge detection mechanism includes a side irradiation light source and a side edge detection camera, the side irradiation light source irradiates to the corresponding side edge of the object to be detected, the corresponding side edge reflects light to the side edge detection camera, and detection of the two side edges of the object 5 to be detected is achieved.

In this embodiment, for each set of detection mechanisms, the optical path length of the surface illumination light reflected from the detected surface of the object 5 to be detected to the corresponding detection camera 41 is equal to the optical path length of the edge illumination light reflected from the detected edge of the object 5 to be detected to the corresponding detection camera 41.

So set up, can realize: for each set of detection mechanisms, the imaging distances of the detection camera 41 to the detected surface and the detected edge of the object 5 to be detected are equal. Therefore, in the detection process, the two clear surface imaging graphs and the edge imaging graph can be continuously obtained without adjusting the focal length of the detection camera 41, so that the detection efficiency is improved, and the detection effect is improved.

In this embodiment, the detection camera 41 of the first detection mechanism 2 is located above the conveying mechanism 1, the surface irradiation light source 44 of the first group of detection mechanisms 2 is located between the detection camera 41 of the first group of detection mechanisms 2 and the conveying mechanism 1, and the edge irradiation light source 42 of the first group of detection mechanisms 2 is located above or below the conveying mechanism.

The detection camera 41 of the second group of detection mechanisms 3 is positioned below the conveying mechanism 1, the surface irradiation light source 44 of the second group of detection mechanisms 3 is positioned between the detection camera 41 of the second group of detection mechanisms 3 and the conveying mechanism 1, and the edge irradiation light source 42 of the second group of detection mechanisms 3 is positioned above or below the conveying mechanism 1.

The reflecting means 33 of the two sets of detecting means have the same composition and structure, and are different only in azimuth layout. In this embodiment, the reflection mechanism 33 includes a first mirror 431, a second mirror 432, a third mirror 434, a fourth mirror 435, a double mirror 433, and a transparent mirror 436. Specifically, for each set of detection mechanism, the double-reflection mirror 433 and the transflective mirror 436 are sequentially disposed between the surface irradiation light source 44 and the detection camera 41, the first reflection mirror 431 and the second reflection mirror 432 are disposed on one side of the surface irradiation light source 44, the third reflection mirror 434 and the fourth reflection mirror 435 are disposed on the other side of the surface irradiation light source 44, and the second reflection mirror 432, the third reflection mirror 434, the fourth reflection mirror 435, the double-reflection mirror 433, and the transflective mirror 436 are all disposed at 45 °. The reflective surface of the mirror 436 faces the inspection camera 41, and the transmissive surface of the mirror 436 faces the surface to illuminate the light source 44.

Taking the first group of detecting mechanisms 2 as an example, in this embodiment, the transmission optical paths of the surface irradiation light and the edge irradiation light are specifically as follows:

the surface irradiation light 44 source emits surface irradiation light to the upper surface 53 of the object 5 to be measured, the upper surface 53 of the object 5 to be measured reflects the surface irradiation light to the lower surface of the double-reflector 433, the lower surface of the double-reflector 433 reflects the surface irradiation light to the third reflector 434, the third reflector 434 reflects the surface irradiation light to the fourth reflector 435, the fourth reflector 435 reflects the surface irradiation light to the upper surface (reflection surface) of the transflective mirror 436, and the upper surface of the transflective mirror 436 reflects the surface irradiation light to the detection camera 41. Thus, the detection of the upper surface 53 of the object 5 by the first group of detection means 2 is achieved.

The edge irradiation light source 42 emits edge irradiation light to the edge 51 of the object 5 to be detected, the edge 51 reflects the edge irradiation light to the first reflecting mirror 431, the first reflecting mirror 431 reflects the edge irradiation light to the second reflecting mirror 432, the second reflecting mirror 432 reflects the edge irradiation light to the upper surface of the double-reflecting mirror 433, the upper surface of the double-reflecting mirror 433 reflects the edge irradiation light to the lower surface (light-transmitting surface) of the transflective mirror 436, and the edge irradiation light passes through the transflective mirror 436 and then reaches the detection camera 41. By this, the detection of the first edge 51 of the object 5 by the first set of detection means 2 is achieved.

It can be seen that the reflection mechanism 43 of this embodiment includes the following three parts:

the surface light reflection mechanism includes a lower surface of a double mirror 433, a third mirror 434 and a fourth mirror 435 for reflecting surface illumination light, in which: the lower surface of the double mirror 433 forms a surface incidence mirror for receiving the surface illumination reflected from the surface to be measured, and the third mirror 434 and the fourth mirror 435 form a surface exit mirror group for emitting and transmitting the surface illumination.

The edge light reflection mechanism includes the upper surfaces of a first reflector 431, a second reflector 432 and a double reflector 433, and is used for reflecting edge illumination light, wherein: the first reflector 431 constitutes an edge-incident reflector for receiving the edge-illuminated light reflected by the edge to be detected, and the upper surfaces of the second reflector 432 and the double reflector 433 constitute an edge-exit reflector set for emitting and transmitting the edge-illuminated light. And

the light path integrating mechanism includes a mirror 436 for reflecting the surface illumination light output by the surface light reflecting mechanism to the detecting camera 41 according to a predetermined light path, and for transmitting the edge illumination light output by the edge light reflecting mechanism to the detecting camera 41 according to a predetermined light path, i.e. in the vertical direction.

The reflection mechanism 43 is set in such a way, so that the surface irradiation light output by the surface light reflection mechanism and the edge irradiation light output by the edge light reflection mechanism can enter the detection camera according to a preset light path when passing through the light path integration mechanism, namely, the surface irradiation light and the edge irradiation light can finally enter the detection camera 41 according to the same incident angle. Therefore, in the detection process, the continuous imaging of the camera to be detected on the surface to be detected of the object to be detected and the edge to be detected of the object to be detected can be ensured without adjusting the field angle of the camera to be detected.

Of course, in other embodiments, the specific components of the reflective mechanism may be adjusted, for example, the dual-reflector 433 is replaced by two ordinary reflectors arranged above and below, the upper reflector is used for reflecting the edge-illuminating light (which acts as the upper surface of the dual-reflector 433), and the lower reflector is used for reflecting the surface-illuminating light (which acts as the lower surface of the dual-reflector 433).

As shown in fig. 1, in general, each component of the reflection mechanism 43 is enclosed in a light shielding plate in order to avoid interference of ambient light.

The following describes, by way of example, the specific arrangement of the two groups of detection mechanisms with respect to the conveying mechanism 1 in connection with four embodiments, but the following description is not exhaustive, and the arrangement form of the two groups of detection mechanisms can be flexibly adjusted according to actual needs.

Fig. 4 is a schematic structural diagram of two sets of detection mechanisms in the first embodiment of the present invention;

fig. 5 is a schematic structural diagram of two sets of detection mechanisms in a second implementation of the present invention;

fig. 6 is a schematic structural diagram of two sets of detection mechanisms in a third embodiment of the present invention;

fig. 7 is a schematic structural diagram of two sets of detection mechanisms in a fourth implementation of the present invention;

first embodiment

As shown in fig. 4, in this embodiment, the edge irradiation light source 41 and the surface irradiation light source 44 of the first group detection mechanism 2 and the surface irradiation light source 44 and the edge irradiation light source 42 of the second group detection mechanism 3 are arranged in the front-back order in the conveying direction of the conveying mechanism 1, that is, the second group detection mechanism 3 is located at the back, the first group detection mechanism 2 is located at the front, and the conveying mechanism 1 conveys the object 5 to be measured from the back to the front (indicated by arrows in the figure).

The detection camera 41 of the first group of detection mechanisms 2 is positioned above the conveying mechanism 1, the surface irradiation light source 44 of the first group of detection mechanisms is positioned between the detection camera 41 of the first group of detection mechanisms 2 and the conveying mechanism 1, and the edge irradiation light source 42 of the first group of detection mechanisms 2 is positioned above the conveying mechanism 1.

The detection camera 41 of the second group of detection mechanisms 3 is located below the conveying mechanism 1, the surface irradiation light source 44 of the second group of detection mechanisms is located between the detection camera 41 of the second group of detection mechanisms 3 and the conveying mechanism 1, and the edge irradiation light source 42 of the second group of detection mechanisms 3 is located above the conveying mechanism 1.

In this embodiment, the first edge is a front edge 51 of the object 5 to be measured when being conveyed on the conveying mechanism 1, and the second edge is a rear edge 52 of the object 5 to be measured when being conveyed on the conveying mechanism 1; the conveying mechanism 1 is provided with a first detection position 61 and a second detection position 62, wherein the first detection position 61 corresponds to the first group of detection mechanisms 2, and the second detection position 62 corresponds to the second group of detection mechanisms 3.

In this embodiment, for the first set of detection means 2, the reflection means 43 comprises a first mirror 431, a second mirror 432, a double mirror 433, a third mirror 434, a fourth mirror 435, a transflective mirror 436, wherein: the double mirror 433 and the half mirror 436 are sequentially disposed between the transport mechanism 1 and the inspection camera 41, the first mirror 431 and the second mirror 432 are disposed on the front side of the surface irradiation light source 44, the third mirror 434 and the fourth mirror 435 are disposed on the rear side of the inspection camera 41, the second mirror 432, the double mirror 433, the third mirror 434, the fourth mirror 435, and the half mirror 436 are all disposed at an angle of 45 °, and the reflection surface of the half mirror 436 faces upward and faces the inspection camera 41.

For the second set of detection means 3, the reflecting means 43 comprises a first mirror 431, a second mirror 432, a double mirror 433, a third mirror 434, a fourth mirror 435, a transflective mirror 436, wherein: the double mirror 433 and the half mirror 436 are sequentially disposed between the transport mechanism 1 and the inspection camera 41, the first mirror 431 and the second mirror 432 are disposed on the rear side of the surface irradiation light source 44, the third mirror 434 and the fourth mirror 435 are disposed on the front side of the inspection camera 41, the second mirror 432, the double mirror 433, the third mirror 434, the fourth mirror 435, and the half mirror 436 are all disposed at an angle of 45 °, and the reflection surface of the half mirror 436 faces downward and faces the inspection camera 41.

The object 5 to be detected firstly enters the second detection position 62 in the process of being conveyed from back to front on the conveying mechanism 1, the edge irradiation light source 42 of the second detection mechanism 3 emits edge irradiation light to the rear end edge 52 of the object 5 to be detected, the edge irradiation light is reflected to the first reflector 431 by the rear end edge 52, the edge irradiation light is reflected to the second reflector 432 by the first reflector 431, the edge irradiation light is reflected to the lower surface of the double-reflector 433 by the second reflector 432, the edge irradiation light is reflected to the upper surface (light-transmitting surface) of the double-reflector 433 by the lower surface of the double-reflector 433, and the edge irradiation light passes through the double-reflector 436 and vertically enters the detection camera 41 downwards. Thereby realizing the detection of the rear end edge 52 of the object 5 to be detected by the second detection mechanism 3.

Further, the object 5 to be detected enters right above the surface irradiation light source 44 of the second group of detection mechanisms 3, the surface irradiation light source 44 of the second group of detection mechanisms 3 emits surface irradiation light to the lower surface 54 of the object 5 to be detected, the lower surface 54 of the object 5 to be detected reflects the surface irradiation light to the upper surface of the double-reflector 433, the upper surface of the double-reflector 433 reflects the surface irradiation light to the third reflector 434, the third reflector 434 reflects the surface irradiation light to the fourth reflector 435, the fourth reflector 435 reflects the surface irradiation light to the lower surface (reflection surface) of the transflective mirror 436, and the lower surface of the transflective mirror 436 vertically reflects the surface irradiation light downward into the detection camera 41. Thereby realizing the detection of the lower surface of the object 5 to be detected by the second detection mechanism 3.

Further, the object 5 to be detected enters right below the surface irradiation light source 44 of the first group of detection mechanisms 2, the surface irradiation light source 44 of the first group of detection mechanisms 2 emits surface irradiation light to the upper surface 53 of the object 5 to be detected, the upper surface 53 of the object 5 to be detected reflects the surface irradiation light to the lower surface of the double-reflector 433, the lower surface of the double-reflector 433 reflects the surface irradiation light to the third reflector 434, the third reflector 434 reflects the surface irradiation light to the fourth reflector 435, the fourth reflector 435 reflects the surface irradiation light to the upper surface (reflection surface) of the transflective mirror 436, and the upper surface of the transflective mirror 436 vertically reflects the surface irradiation light upwards into the detection camera 41. Thereby realizing the detection of the upper surface of the object 5 to be detected by the first detection mechanism 3.

Further, the object 5 to be detected enters the first detection position 61, the edge irradiation light source 42 of the first detection mechanism 2 emits edge irradiation light to the front end edge 51 of the object 5 to be detected, the front end edge 51 reflects the edge irradiation light to the first reflector 431, the first reflector 431 reflects the edge irradiation light to the second reflector 432, the second reflector 432 reflects the edge irradiation light to the upper surface of the double-reflector 433, the upper surface of the double-reflector 433 reflects the edge irradiation light to the lower surface (light-transmitting surface) of the transparent mirror 436, and the edge irradiation light passes through the transparent mirror 436 and vertically and upwardly enters the detection camera 41. Thereby, the detection of the front end edge 51 of the object 5 to be detected by the first detection mechanism 2 is realized.

Referring to fig. 1 to 3 again, in this embodiment, the edge irradiation light source 42 of the first group of detection mechanisms 2 and the edge irradiation light source 42 of the second group of detection mechanisms 3 may be respectively disposed on the front side and the rear side of the transmission mechanism 1 through a bracket, so that the edge irradiation light emitted by the edge irradiation light source 42 can directly irradiate the measured edge of the measured object 5 without passing through the light-transmitting holes and the transmission belt gaps in the transmission mechanism 1.

Preferably, the distance between the reflecting members in the reflecting mechanism 43 may be adjusted so that the optical path length of the surface irradiation light reflected from the detected surface of the object 5 to be detected to the corresponding detection camera 41 is equal to the optical path length of the edge irradiation light reflected from the detected edge of the object 5 to be detected to the corresponding detection camera 41.

Second embodiment

As shown in fig. 5, in this embodiment, the surface irradiation light source 44 and the edge irradiation light source 42 of the first group detection mechanism 2, and the edge irradiation light source 42 and the surface irradiation light source 44 of the second group detection mechanism 3 are arranged in the front-to-back order along the conveying direction of the conveying mechanism 1, that is, the second group detection mechanism 3 is located at the rear position, the first group detection mechanism 2 is located at the front position, and the conveying mechanism 1 conveys the object 5 to be measured from the rear position to the front position (indicated by arrows in the figure).

The detection camera 41 of the first group of detection mechanisms 2 is positioned above the conveying mechanism 1, the surface irradiation light source 44 of the first group of detection mechanisms is positioned between the detection camera 41 of the first group of detection mechanisms 2 and the conveying mechanism 1, and the edge irradiation light source 42 of the first group of detection mechanisms 2 is positioned below the conveying mechanism 1.

The detection camera 41 of the second group of detection mechanisms 3 is located below the conveying mechanism 1, the surface irradiation light source 44 of the second group of detection mechanisms is located between the detection camera 41 of the second group of detection mechanisms 3 and the conveying mechanism 1, and the edge irradiation light source 42 of the second group of detection mechanisms 3 is located below the conveying mechanism 1.

In this embodiment, the first edge is a rear end edge 52 of the object 5 to be measured when being conveyed on the conveying mechanism 1, and the second edge is a front end edge 51 of the object 5 to be measured when being conveyed on the conveying mechanism 1; the conveying mechanism is provided with a third detection position 63 and a fourth detection position 64, wherein the third detection position 63 corresponds to the first group detection mechanism 2, and the fourth detection position 64 corresponds to the second group detection mechanism 3.

In this embodiment, the edge irradiation light source 42 of the first group of detection mechanisms and the edge irradiation light source 42 of the second group of detection mechanisms are the same light source or different light sources, please refer to fig. 5, when the edge irradiation light source 42 of the first group of detection mechanisms and the edge irradiation light source 42 of the second group of detection mechanisms are the same light source, that is, the first group of detection mechanisms and the second group of detection mechanisms share one light source, the number of light sources can be reduced; when the edge irradiation light source 42 of the first group of detection mechanisms and the edge irradiation light source 42 of the second group of detection mechanisms are different light sources, i.e. two groups of mutually independent light sources, the heat dissipation of the light sources is more facilitated.

In this embodiment, for the first set of detection means 2, the reflection means 43 comprises a first mirror 431, a second mirror 432, a double mirror 433, a third mirror 434, a fourth mirror 435, a transflective mirror 436, wherein: the double mirror 433 and the half mirror 436 are disposed in this order between the transport mechanism 1 and the inspection camera 41, the first mirror 431 and the second mirror 432 are disposed on the rear side of the surface irradiation light source 44, the third mirror 434 and the fourth mirror 435 are disposed on the front side of the inspection camera 41, the second mirror 432, the double mirror 433, the third mirror 434, the fourth mirror 435, and the half mirror 436 are disposed at an angle of 45 °, and the reflection surface of the half mirror 436 faces upward and faces the inspection camera 41.

For the second set of detection means 3, the reflecting means 43 comprises a first mirror 431, a second mirror 432, a double mirror 433, a third mirror 434, a fourth mirror 435, a transflective mirror 436, wherein: the double mirror 433 and the half mirror 436 are sequentially disposed between the transport mechanism 1 and the inspection camera 41, the first mirror 431 and the second mirror 432 are disposed on the front side of the surface irradiation light source 44, the third mirror 434 and the fourth mirror 435 are disposed on the rear side of the inspection camera 41, the second mirror 432, the double mirror 433, the third mirror 434, the fourth mirror 435, and the half mirror 436 are all disposed at an angle of 45 °, and the reflection surface of the half mirror 436 faces downward and faces the inspection camera 41.

In the process of conveying the object 5 to be detected from back to front on the conveying mechanism 1, the object 5 to be detected firstly enters right above the surface irradiation light source 44 of the second group of detection mechanisms 3, the surface irradiation light source 44 of the second detection mechanism 3 emits surface irradiation light to the lower surface 54 of the object 5 to be detected, the lower surface 54 of the object 5 to be detected reflects the surface irradiation light to the upper surface of the double-reflector 433, the upper surface of the double-reflector 433 reflects the surface irradiation light to the third reflector 434, the third reflector 434 reflects the surface irradiation light to the fourth reflector 435, the fourth reflector 435 reflects the surface irradiation light to the lower surface (reflecting surface) of the transparent reflector 436, and the lower surface of the transparent reflector 436 reflects the surface irradiation light into the detection camera 41. Thereby realizing the detection of the lower surface 54 of the object 5 to be detected by the second detection mechanism 3.

Further, the object 5 to be detected enters the fourth detection position 64, the edge irradiation light source 42 of the second detection mechanism 3 emits edge irradiation light to the front edge 51 of the object 5 to be detected, the front edge 51 reflects the edge irradiation light to the first reflector 431, the first reflector 431 reflects the edge irradiation light to the second reflector 432, the second reflector 432 reflects the edge irradiation light to the lower surface of the double-reflector 433, the lower surface of the double-reflector 433 reflects the edge irradiation light to the upper surface (light-transmitting surface) of the half-mirror 436, and the edge irradiation light passes through the half-reflector 436 and vertically enters the detection camera 41. Thereby realizing the detection of the front end edge 51 of the object 5 to be detected by the second detection mechanism 3.

Further, the object 5 to be detected enters the third detection position 63, the edge irradiation light source 42 of the first detection mechanism 2 emits edge irradiation light to the rear end edge 52 of the object 5 to be detected, the rear end edge 52 reflects the edge irradiation light to the first reflector 431, the first reflector 431 reflects the edge irradiation light to the second reflector 432, the second reflector 432 reflects the edge irradiation light to the upper surface of the double-reflector 433, the upper surface of the double-reflector 433 reflects the edge irradiation light to the lower surface (light-transmitting surface) of the half-mirror 436, and the edge irradiation light passes through the half-mirror 436 and vertically and upwardly enters the detection camera 41. Thereby, the detection of the rear end edge 52 of the object 5 to be detected by the first detection mechanism 2 is realized.

Further, the object 5 to be detected enters right below the surface irradiation light source 44 of the first group of detection mechanisms 2, the surface irradiation light source 44 of the first group of detection mechanisms 2 emits surface irradiation light to the upper surface 53 of the object 5 to be detected, the upper surface 53 of the object 5 to be detected reflects the surface irradiation light to the lower surface of the dual-reflector 433, the lower surface of the dual-reflector 433 reflects the surface irradiation light to the third reflector 434, the third reflector 434 reflects the surface irradiation light to the fourth reflector 435, the fourth reflector 435 reflects the surface irradiation light to the upper surface (reflection surface) of the transflective mirror 436, and the upper surface of the transflective mirror 436 vertically reflects the surface irradiation light upwards into the detection camera 41. Thereby realizing the detection of the upper surface 53 of the object 5 to be detected by the first detection mechanism 2.

As in the first embodiment, it is preferable that the optical path length of the surface irradiation light reflected from the detected surface of the object 5 to be detected to the corresponding detection camera 41 be equal to the optical path length of the edge irradiation light reflected from the detected edge of the object 5 to be detected to the corresponding detection camera 41 by adjusting the pitch between the components in the reflection mechanism 43.

Third embodiment

As shown in fig. 6, in this embodiment, the arrangement layout of the detection camera 41, the edge irradiation light source 42, the surface irradiation light source 44, and the reflection mechanism 43 in the two sets of detection mechanisms is the same as the form shown in fig. 4 in the first embodiment, except that: the object 5 to be detected firstly enters the first detection position 61 in the process of being conveyed from back to front on the conveying mechanism 1, the edge irradiation light source 42 of the first detection mechanism 2 emits edge irradiation light to the detected edge of the object 5 to be detected, namely the rear end edge 51, the rear end edge 51 reflects the edge irradiation light to the first reflector 431, the first reflector 431 reflects the edge irradiation light to the second reflector 432, the second reflector 432 reflects the edge irradiation light to the upper surface of the double-reflector 433, the upper surface of the double-reflector 433 reflects the edge irradiation light to the lower surface (light-transmitting surface) of the transflective 436, and the edge irradiation light passes through the transflective 436 and vertically upwards enters the detection camera 41. Thereby, the detection of the rear end edge 51 of the object 5 to be detected by the first detection mechanism 2 is realized.

Further, the object 5 to be detected enters right below the surface irradiation light source 44 of the first group of detection mechanisms 2, the surface irradiation light source 44 of the first group of detection mechanisms 2 emits surface irradiation light to the upper surface 53 of the object 5 to be detected, the upper surface 53 of the object 5 to be detected reflects the surface irradiation light to the lower surface of the double-reflector 433, the lower surface of the double-reflector 433 reflects the surface irradiation light to the third reflector 434, the third reflector 434 reflects the surface irradiation light to the fourth reflector 435, the fourth reflector 435 reflects the surface irradiation light to the upper surface (reflection surface) of the transflective mirror 436, and the upper surface of the transflective mirror 436 vertically reflects the surface irradiation light upwards into the detection camera 41. Thereby realizing the detection of the upper surface 53 of the object 5 to be detected by the first detection mechanism 3.

Further, the object 5 to be detected enters right above the surface irradiation light source 44 of the second group of detection mechanisms 3, the surface irradiation light source 44 of the second group of detection mechanisms 3 emits surface irradiation light to the lower surface 54 of the object 5 to be detected, the lower surface 54 of the object 5 to be detected reflects the surface irradiation light to the upper surface of the double-reflector 433, the upper surface of the double-reflector 433 reflects the surface irradiation light to the third reflector 434, the third reflector 434 reflects the surface irradiation light to the fourth reflector 435, the fourth reflector 435 reflects the surface irradiation light to the lower surface (reflection surface) of the transflective mirror 436, and the lower surface of the transflective mirror 436 vertically reflects the surface irradiation light downward into the detection camera 41. Thereby realizing the detection of the lower surface of the object 5 to be detected by the second detection mechanism 3.

Further, the object 5 to be detected enters the second detection position 62, the edge irradiation light source 42 of the second detection mechanism 3 emits edge irradiation light to the detected edge of the object 5 to be detected, i.e. the front edge 52, the front edge 52 reflects the edge irradiation light to the first reflector 431, the first reflector 431 reflects the edge irradiation light to the second reflector 432, the second reflector 432 reflects the edge irradiation light to the lower surface of the double-reflector 433, the lower surface of the double-reflector 433 reflects the edge irradiation light to the upper surface (light-transmitting surface) of the transparent mirror 436, and the edge irradiation light passes through the transparent mirror 436 and vertically enters the detection camera 41 downward. Thereby realizing the detection of the front end edge 52 of the object 5 to be detected by the second detection mechanism 3.

Fourth embodiment

As shown in fig. 7, in this embodiment, the arrangement layout of the detection camera 41, the edge irradiation light source 42, the surface irradiation light source 44 and the reflection mechanism 43 in the two sets of detection mechanisms is the same as that shown in fig. 5 in the second embodiment, and the edge irradiation light source of the first set of detection mechanisms and the edge irradiation light source of the second set of detection mechanisms may be the same light source or different light sources, and the difference is that: in the process of conveying the object 5 to be detected from back to front on the conveying mechanism 1, the object 5 to be detected firstly enters right below the surface irradiation light source 44 of the first group of detection mechanisms 2, the surface irradiation light source 44 of the first detection mechanism 2 emits surface irradiation light to the upper surface 53 of the object 5 to be detected, the upper surface 53 of the object 5 to be detected reflects the surface irradiation light to the lower surface of the double-reflector 433, the lower surface of the double-reflector 433 reflects the surface irradiation light to the third reflector 434, the third reflector 434 reflects the surface irradiation light to the fourth reflector 435, the fourth reflector 435 reflects the surface irradiation light to the upper surface (reflecting surface) of the transflective mirror 436, and the upper surface of the transflective mirror 436 vertically reflects the surface irradiation light upwards into the detection camera 41. Thereby realizing the detection of the upper surface 53 of the object 5 to be detected by the first detection mechanism 2.

Further, the object 5 to be detected enters the third detection position 63, the edge irradiation light source 42 of the first detection mechanism 2 emits edge irradiation light to the detected edge of the object 5 to be detected, i.e. the front edge 52, the front edge 52 reflects the edge irradiation light to the first reflector 431, the first reflector 431 reflects the edge irradiation light to the second reflector 432, the second reflector 432 reflects the edge irradiation light to the upper surface of the double-reflector 433, the upper surface of the double-reflector 433 reflects the edge irradiation light to the lower surface (light-transmitting surface) of the transparent mirror 436, and the edge irradiation light passes through the transparent mirror 436 and vertically enters the detection camera 41 upwards. Thereby, the detection of the front end edge 52 of the object 5 to be detected by the first detection mechanism 2 is realized. Further, the object 5 to be detected enters the fourth detection position 64, the edge irradiation light source 42 of the second detection mechanism 3 emits edge irradiation light to the detected edge of the object 5 to be detected, i.e. the rear end edge 51, the rear end edge 51 reflects the edge irradiation light to the first reflector 431, the first reflector 431 reflects the edge irradiation light to the second reflector 432, the second reflector 432 reflects the edge irradiation light to the lower surface of the double-reflector 433, the lower surface of the double-reflector 433 reflects the edge irradiation light to the upper surface (light-transmitting surface) of the transparent mirror 436, and the edge irradiation light passes through the transparent mirror 436 and vertically enters the detection camera 41 downward. Thereby, the detection of the rear end edge 51 of the object 5 to be detected by the second detection mechanism 3 is realized.

Further, the object 5 to be detected enters right above the surface irradiation light source 44 of the second group of detection mechanisms 3, the surface irradiation light source 44 of the second group of detection mechanisms 3 emits surface irradiation light to the lower surface 54 of the object 5 to be detected, the lower surface 54 of the object 5 to be detected reflects the surface irradiation light to the upper surface of the dual-reflector 433, the upper surface of the dual-reflector 433 reflects the surface irradiation light to the third reflector 434, the third reflector 434 reflects the surface irradiation light to the fourth reflector 435, the fourth reflector 435 reflects the surface irradiation light to the lower surface (reflection surface) of the transflective mirror 436, and the lower surface of the transflective mirror 436 vertically reflects the surface irradiation light downward into the detection camera 41. Thereby realizing the detection of the lower surface 54 of the object 5 to be detected by the second detection mechanism 3.

In the above four embodiments, when detecting the detected edge of the object 5 to be detected, the edge illumination light emitted from the edge illumination light source 42 directly illuminates the detected edge, and then is reflected by the detected edge to the edge incident reflector (the first reflector 431 in the above embodiments), and then the edge incident reflector reflects the edge illumination light to the edge exit reflector set (the first reflector 432 and the double reflector 433 in the above embodiments face the reflecting surface of the detection camera 42).

However, in other embodiments, due to the structural specificity of the transmission mechanism 1, it is difficult to ensure that the edge-illuminating light emitted from the edge-illuminating light source 42 can directly illuminate the detected edge. Therefore, in these embodiments, the edge illumination light emitted from the edge illumination light source 42 first illuminates the edge incident mirror, then is reflected by the edge incident mirror to the detected edge of the object 5, and then the detected edge reflects the edge illumination light into the edge exit mirror group. With such an arrangement, the edge irradiation light emitted by the edge irradiation light source 42 can be ensured to irradiate the detected edge by adaptively adjusting the setting position and angle of the edge incident reflector.

The utility model also discloses a silicon wafer sorting device, which comprises the detection device, wherein the object to be detected is a silicon wafer; the silicon wafer sorting equipment further comprises overall dimension detection equipment for detecting whether the overall dimension of the silicon wafer conveyed on the conveying mechanism 1 is qualified, a subfissure detection device for detecting whether the silicon wafer is qualified, a thickness detection device for detecting whether the thickness of the silicon wafer is qualified and the like.

The utility model discloses in, first edge and the upper surface that first group detection mechanism detected the silicon chip, the second that second group detection mechanism detected the silicon chip detects edge and lower surface, and the silicon chip need not stop in transmission process, need not rotate, can realize detecting comprehensively promptly, and detection efficiency can improve, the structure is simplified, and equipment manufacturing cost is low, detection cost reduces, the testing process continuity is better, is difficult for causing the damage to the silicon chip, has very high economic nature.

The invention has been described above with a certain degree of particularity and detail. It will be understood by those of ordinary skill in the art that the description of the embodiments is merely exemplary and that all changes that may be made without departing from the true spirit and scope of the present invention are intended to be within the scope of the present invention. The scope of the invention is defined by the appended claims rather than by the foregoing description of the embodiments.

Claims (11)

1. The utility model provides a detection device, its characterized in that, detection device is including conveying mechanism and two sets of detection mechanism that are used for carrying the object that awaits measuring, and first set of detection mechanism is configured to detect the first edge and the upper surface of the object that awaits measuring, and second set of detection mechanism is configured to detect the second edge and the lower surface of the object that awaits measuring, first edge with the second edge does relative on the object that awaits measuring and with two edges of conveying mechanism's direction of delivery vertically, every detection mechanism of group all includes detection camera, surface irradiation light source, edge irradiation light source and reflecting mechanism, wherein, for every group detection mechanism:

the reflection mechanism is configured to reflect the surface illumination light emitted by the surface illumination light source at least once, so that the surface illumination light is detected by the corresponding detection camera after being reflected by the detected surface of the object to be detected;

the reflection mechanism is further configured to reflect the edge illumination light emitted by the edge illumination light source at least once, so that the edge illumination light is detected by the corresponding detection camera after being reflected by the detected edge of the object to be detected.

2. The detection device of claim 1, wherein: for each group of detection mechanisms, the optical path length of the surface illumination light reflected from the detected surface of the object to be detected to the corresponding detection camera is equal to the optical path length of the edge illumination light reflected from the detected edge of the object to be detected to the corresponding detection camera.

3. The detection device of claim 1, wherein:

the detection camera of the first group of detection mechanisms is positioned above the conveying mechanism, the surface irradiation light source of the first group of detection mechanisms is positioned between the detection camera of the first group of detection mechanisms and the conveying mechanism, and the edge irradiation light source of the first group of detection mechanisms is positioned above or below the conveying mechanism;

the detection camera of the second group of detection mechanisms is positioned below the conveying mechanism, the surface irradiation light source of the second group of detection mechanisms is positioned between the detection camera of the second group of detection mechanisms and the conveying mechanism, and the edge irradiation light source of the second group of detection mechanisms is positioned above or below the conveying mechanism.

4. A testing device according to claim 3, wherein:

the edge irradiation light source and the surface irradiation light source of the first group of detection mechanism and the surface irradiation light source and the edge irradiation light source of the second group of detection mechanism are arranged in sequence from front to back along the conveying direction of the conveying mechanism, the first edge is the front end edge of the object to be detected, the second edge is the rear end edge of the object to be detected, and the conveying mechanism conveys the object to be detected from back to front;

the utility model discloses a detection structure for detecting the object of awaiting measuring, including first set of detection mechanism and second set of detection mechanism, the object of awaiting measuring carries to when the second detects the position, the rear end edge that the second set of detection mechanism detected the object of awaiting measuring, the object of awaiting measuring carries to when the surface irradiation light source of second set of detection mechanism is directly over, the lower surface that the second set of detection mechanism detected the object of awaiting measuring, the object of awaiting measuring carries to when the first detection position, the front end edge that the first set of detection mechanism detected the object of awaiting measuring.

5. A testing device according to claim 3, wherein:

the surface irradiation light source and the edge irradiation light source of the first group of detection mechanism and the edge irradiation light source and the surface irradiation light source of the second group of detection mechanism are sequentially arranged from front to back along the conveying direction of the conveying mechanism, the first edge is the rear end edge of the object to be detected, the second edge is the front end edge of the object to be detected, and the conveying mechanism conveys the object to be detected from back to front;

when the object to be detected is conveyed to a position right above the surface irradiation light source of the second group of detection mechanisms, the second group of detection mechanisms detect the lower surface of the object to be detected, when the object to be detected is conveyed to a fourth detection position, the second group of detection mechanisms detect the front end edge of the object to be detected, when the object to be detected is conveyed to a third detection position, the first group of detection mechanisms detect the rear end edge of the object to be detected, and when the object to be detected is conveyed to a position right below the surface irradiation light source of the first group of detection mechanisms, the first group of detection mechanisms detect the upper surface of the object to be detected;

the edge irradiation light source of the first group of detection mechanism and the edge irradiation light source of the second group of detection mechanism are the same light source or different light sources.

6. A testing device according to claim 3, wherein:

the edge irradiation light source and the surface irradiation light source of the second group of detection mechanism and the surface irradiation light source and the edge irradiation light source of the first group of detection mechanism are arranged in sequence from front to back along the conveying direction of the conveying mechanism, the first edge is the rear end edge of the object to be detected, the second edge is the front end edge of the object to be detected, and the conveying mechanism conveys the object to be detected from back to front;

the utility model discloses a detection mechanism for detecting the object of awaiting measuring, including first set of detection mechanism and second set of detection mechanism, the object of awaiting measuring carries to when first detection position, first set of detection mechanism detects the rear end edge of the object of awaiting measuring, the object of awaiting measuring carries to when the surface irradiation light source of first set of detection mechanism is under, first set of detection mechanism detects the upper surface of the object of awaiting measuring, the object of awaiting measuring carry to when the surface irradiation light source of second set of detection mechanism is over, the lower surface that the object of awaiting measuring was detected to second set of detection mechanism, the object of awaiting measuring carries when the second detects the position, the front end edge that the object of awaiting measuring was.

7. A testing device according to claim 3, wherein:

the surface irradiation light source and the edge irradiation light source of the second group of detection mechanism and the edge irradiation light source and the surface irradiation light source of the first group of detection mechanism are sequentially arranged from front to back along the conveying direction of the conveying mechanism, the first edge is the front end edge of the object to be detected, the second edge is the rear end edge of the object to be detected, and the conveying mechanism conveys the object to be detected from back to front;

when the object to be detected is conveyed to a position right below the surface irradiation light source of the first group of detection mechanisms, the first group of detection mechanisms detect the upper surface of the object to be detected, when the object to be detected is conveyed to a third detection position, the first group of detection mechanisms detect the front end edge of the object to be detected, when the object to be detected is conveyed to a fourth detection position, the second group of detection mechanisms detect the rear end edge of the object to be detected, and when the object to be detected is conveyed to a position right above the surface irradiation light source of the second group of detection mechanisms, the first group of detection mechanisms detect the lower surface of the object to be detected;

the edge irradiation light source of the first group of detection mechanism and the edge irradiation light source of the second group of detection mechanism are the same light source or different light sources.

8. The inspection device of claim 1, wherein for each set of inspection devices, the reflecting means comprises surface light reflecting means, edge light reflecting means, and optical path integrating means, wherein:

the surface light reflection mechanism is configured to reflect the surface irradiation light emitted from the surface irradiation light source to the optical path integration mechanism;

the edge light reflecting mechanism is configured to reflect the edge illumination light rays emitted by the edge illumination light source to the light path integration mechanism;

the light path integration mechanism is configured to reflect the surface illumination light reflected to the light path integration mechanism to a detection camera according to a preset light path;

the light path integration mechanism is further configured to transmit the edge illumination light reflected to the light path integration mechanism to a detection camera according to a preset light path.

9. The detection device of claim 8, wherein:

the light path integration mechanism comprises a transflective lens, the transflective lens is arranged between the detection camera and the surface irradiation light source, the reflecting surface of the transflective lens faces the detection camera, and the light transmitting surface of the transflective lens faces the surface irradiation light source;

the surface light reflection mechanism is configured to reflect the surface illumination light emitted by the surface illumination light source to the reflecting surface of the transflective lens, and the surface illumination light is reflected to the reflecting surface of the transflective lens and then is reflected into the detection camera through the reflecting surface of the transflective lens;

the edge light reflection mechanism is configured to reflect edge illumination light rays emitted by the edge illumination light source to the light transmission surface of the transflective lens, and the edge illumination light rays directly penetrate through the transflective lens and enter the detection camera after being reflected to the light transmission surface of the transflective lens.

10. The sensing device of claim 8, wherein for each set of sensing mechanisms:

the surface light reflection mechanism comprises a surface incidence reflector and a surface exit reflector set, the surface exit reflector set comprises at least one surface exit reflector, the surface irradiation light source emits surface irradiation light to the detected surface, the surface incidence reflector receives the surface irradiation light reflected by the detected surface and reflects the surface irradiation light to the surface exit reflector set, and the surface exit reflector set reflects the surface irradiation light to the light path integration mechanism;

the edge light reflecting mechanism comprises an edge incident reflector and an edge emergent reflector group, the edge emergent reflector group comprises at least one edge emergent reflector, the edge irradiation light source emits edge irradiation light to the edge to be detected, the edge incident reflector receives the edge irradiation light reflected by the edge to be detected and reflects the edge irradiation light to the edge emergent reflector group, and the edge irradiation light is reflected to the light path integrating mechanism by the edge emergent reflector group; or

The edge incident reflector receives edge illumination light emitted by the edge illumination light source, reflects the edge illumination light to a detected edge, reflects the edge illumination light to the edge emergent reflector group by the detected edge, and reflects the edge illumination light to the light path integration mechanism by the edge emergent reflector group.

11. A silicon wafer sorting apparatus comprising the inspection device according to any one of claims 1 to 10, wherein the object to be inspected is a silicon wafer.

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