TWM542850U - Wafer inspection and classification device - Google Patents

Description

Wafer inspection and classification device

This creation relates to a wafer inspection and classification device, and in particular to a high-speed, sophisticated and innovative structure type revealer with detection and classification functions.

According to the rapid development of technology, high-tech electronic products are widely used in daily life, such as mobile phones, motherboards, digital cameras and other electronic products. These electronic products are installed inside and are filled with many IC semiconductors. The source of IC semiconductor materials is wafers. In order to meet the large demand of various high-tech electronic products, the foundry industry is constantly developing and developing the wafer manufacturing process with a faster and more efficient target. Improved breakthroughs.

At present, the wafer inspection equipment on the market is designed for the sampling measurement of IC semiconductors. Therefore, the measurement speed is slow, and the number of input and output ports provided by the IC is small. Generally, it can be divided into semi-automatic and fully automatic detection equipment. And even if it is fully automatic, only two outputs are set. When the robot arm extracts the wafer from one of the input and output ports, the wafer is returned to the original output port after the detection. If a defective product is found during the detection, the defective product is placed in another output port. Such a detection method can only satisfy the early semiconductor process. However, for LED wafers, all sapphire wafers need to be measured and classified and graded according to different specifications. In addition, the demand for sapphire wafers on the market is increasing. Wafer inspection equipment is no longer sufficient or even usable on sapphire wafer processes.

Therefore, in view of the problems existing in the above-mentioned conventional technologies, how to develop an innovative structure of a high-speed, precise wafer inspection device with detection and classification function is subject to the consideration and direction of the relevant industry.

In view of this, the creator has been engaged in the manufacturing development and design experience of related products for many years. After the detailed design and careful evaluation of the above objectives, the creator will have a practical and practical creation.

The main purpose of this creation is to provide a wafer inspection and classification device and its detection and classification method. The technical problem to be solved is to develop a new high-speed, precise and classification function with more ideal and practicality. The structural type is an innovative breakthrough for the goal.

The technical feature of the present invention is mainly that the wafer detecting device includes a pedestal, and the top surface of the pedestal is disposed as a reference surface; the first side of the reference surface is provided with at least one input And a first mechanical arm disposed adjacent to the at least one receiving device and a rim searching station; a measuring platform mounted at a central portion of the reference surface; the second side of the reference surface is provided with a plurality of a discharge mechanism and a second robot arm mounted on the inner side of the discharge magazine; the base is provided with a central control unit; the reference surface is provided with an operation interface and an input interface, wherein the operation interface is The input interface is electrically connected to the central control unit, and the first robot arm, the edge finding station, the measuring platform and the second robot arm are electrically connected to the central control unit respectively; The robot arm takes out the wafer to be inspected from the at least one feeding material and sends it to the edge finding station, and sets the detection reference point through the edge finding station, and then sends the wafer to be tested to the measurement by using the first mechanical arm. Platform, the measurement platform is input according to the input interface The detection parameter detection begins, until testing is completed, i.e., the second robot according to a detection result of the wafer to the designated discharge port, the wafer inspection classification purposes.

With this innovative and unique design, this creation can be classified and classified according to the input detection parameters according to the input technology, and provide a high-speed, precise and classified wafer inspection and classification device.

Please refer to Figures 1 and 2 for a preferred embodiment of the present wafer inspection and sorting apparatus. However, these embodiments are for illustrative purposes only and are not limited by the structure in the patent application; The circular detection and classification device includes a base 10, and the top surface of the base 10 is disposed as a reference surface 11; the first side of the reference surface 11 is provided with at least one loading cassette 20 adjacent to the at least one a loading arm 20 is provided with a first robot arm 30 and a rim searching station 40; a measuring platform 50 mounted on a central portion of the reference surface 11; the second side of the reference surface 11 is provided with a plurality of discharging materials The cymbal 60 and a second robot arm 70 mounted on the inner side of the discharge raft 60; the base 10 is provided with a central control unit 80; the reference surface 11 is provided with an operation interface 81 and an input interface 82. The operation interface 81 and the input interface 82 are electrically connected to the central control unit 80, respectively, and the first mechanical arm 30, the edge finding station 40, the measuring platform 50, and the second robot arm 70 are They are electrically connected to the central control unit 80, respectively. The first robot arm 30 takes out the wafer to be inspected from the at least one loading cassette 20 and sends it to the edge finding station 40. After the detection reference point is set by the edge finding station 40, the wafer to be tested is used. A robot arm 30 is sent to the measurement platform 50, and the measurement platform 50 starts to detect according to the detection parameter input by the input interface 82. After the detection is completed, the second robot arm 70 sends the wafer to the test result according to the detection result. In the proper discharge 埠60, the purpose of wafer inspection classification is achieved. In the preferred embodiment of the present invention, the operation interface 81 and the input interface 82 are mounted on the reference surface 11 to facilitate the operator to set various parameters and initiate the creation. The operation interface 81 and the input interface 82 are of course It can also be controlled remotely via internet connection or wireless transmission.

As shown in FIGS. 3 and 4, the at least one loading cassette 20 includes at least one base 21 for detachably mounting at least one wafer storage box 90, wherein At least one of the bases 21 is provided with a plurality of jigs 211 for mounting the wafer storage boxes 90 of different sizes according to actual requirements. In the preferred embodiment of the present invention, the number of the magazines 20 is set to ten, and the upper and lower layers are arranged in an arc-like manner. As shown in FIG. 4, the wafer storage box 90A is for storing two wafers; as shown in FIG. 5, the wafer storage box 90B is for storing four wafers; as shown in FIG. 6, The wafer storage case 90C is for storing six wafers.

As shown in Figures 2 and 10, the first robot arm 30 has a dual-axis design and includes a first telescopic pick-and-place plate 31 and a second telescopic pick-and-place plate. 32, wherein the first telescopic pick-and-place board 31 and the second telescopic pick-and-place board 32 independently transfer the wafer from the at least one feed cassette 20 to the edge-finding station 40, and then the crystal on the edge-finding station 40 The circle is transmitted to the measurement platform 50.

Referring to FIG. 2, the structure of the at least two discharge trays 60 is the same as the at least one magazine 20, and also includes at least two bases 61 for detachably mounting. At least two wafer storage boxes 90, wherein the at least two bases 61 are provided with a plurality of jigs 611, so that the wafer storage boxes 90 of different specifications are installed according to actual requirements. In the preferred embodiment of the present invention, the number of the discharge magazines 60 is set to ten, and the upper and lower layers are arranged in an arc-like manner.

The second robot arm 70 has a function of lifting and rotating, and includes a telescopic pick-and-place plate 71. The main function of the second robot arm 70 is to remove the detected wafer from the measuring platform 50 and crystallize according to the detection result. The round is sent to a suitable discharge port 60.

The central control unit 80 has a built-in interpretation classification module 800.

With the above-described structural composition design, the operation of the present invention will be described as follows: As shown in FIG. 1, at least one wafer storage box 90A/90B/90C containing undetected wafers is first mounted by a jig 211. The at least two wafer storage boxes 90A/90B/90C are respectively mounted on the at least two bases 61 of the discharge magazine 60 by the clamp 611; and the input interface 82 is used. All the parameters required for the detection are input into the central control unit 80, and the creation interface 81 is used to initiate the creation; see, as shown in FIGS. 7 and 8, when the creation is started, the first robot arm 30 is A telescopic pick-and-place board 31 immediately takes a wafer from the at least one wafer storage box 90A/90B90C and immediately transfers it to the edge-finding station 40, and uses the edge-finding station 40 to set the detection according to the shape and thickness of the wafer. a reference point; as shown in FIG. 9, after the edge-finding station 40 sets the reference point for detection, the first telescopic pick-and-place board 31 transmits the wafer of the edge-finding station 40 to the measuring platform 50, The measurement platform 50 is for thickness, flatness, total thickness variation, curvature, linearity The wafer is inspected for the same condition; and when the first telescopic pick-and-place panel 31 is transporting the wafer to the measuring platform 50, the second telescopic pick-and-place panel 32 is also simultaneously loaded from the at least one magazine. Another wafer is taken out of 20 and transferred to the edge finding station 40. Referring to FIG. 10, after the detection operation is completed, the measurement platform 50 transmits the data detected by the measurement platform 50 to the central control unit 80, and uses the interpretation classification module 800 to interpret the wafer classification. Basis. The central control unit 80 sends a sorting command to the second robot arm 70 according to the classification result of the interpretation classification module 800, so that the telescopic pick-and-place board 71 of the second robot arm 70 is removed from the measuring platform 50 ( After the wafer is detected, the wafer is sent to a designated discharge port 60 according to the classification instruction of the central control unit 80 to achieve the purpose of wafer inspection and classification. When the telescopic pick-and-place board 60 transports the wafer on the simple side, the first telescopic pick-and-place board 31 and the second telescopic pick-up board 32 respectively transmit the undetected and to-be-detected wafers to the edge-finding station 40 and In the measurement platform 50, the edge-finding station 40 and the measurement platform 50 can be synchronized to shorten the time for wafer detection and classification.

In addition, the first telescopic pick-and-place board 31, the second telescopic pick-and-place board 32, and the telescopic pick-and-place board 71 of the second robot arm 70 respectively have an image-finding module built therein (in the figure) Not shown) to improve the accuracy of the wafer being picked.

Please refer to Figure 11 for the detection and classification method of the wafer used in this creation. The method includes the following steps: Installing the loading and discharging device: mounting at least one wafer storage box containing the undetected wafer in one The at least two wafer storage boxes are mounted on at least two bases of a discharge magazine; wherein the feed cassette and the discharge cassette are respectively disposed on a base The top surface is set; the detection parameter is set: the central unit is provided with a central control unit, and the detection parameter is transmitted to the central control unit by using an input interface; in the preferred embodiment of the creation, the input interface is installed An operation interface is disposed on the reference surface, and the operation interface and the input interface are electrically connected to the central control unit. Transmitting and detecting the wafer: using a first robot arm to take a wafer from the at least one wafer storage box and transferring it to the edge-finding station, and using the edge-finding station to set the detection reference point according to the shape and thickness of the wafer; After the edge-finding station sets the reference point of the detection, the first robot arm transmits the wafer of the edge-finding station to the measurement platform, so that the measurement platform performs a detection operation on the wafer with a pre-input detection parameter; The data is used as a classification basis: when the detection operation is completed, the measurement platform transmits the data detected by the measurement platform to the central control unit for interpretation using a built-in interpretation classification module, as a basis for wafer classification. The central control unit issues a sorting instruction to the second robot arm according to the classification result of the interpretation classification module; and transmits and classifies the detected wafer: when the program for detecting the interpretation data is completed, the second robot arm and the middle robot The sorting instruction issued by the control unit causes the telescopic pick-and-place board to remove the wafer from the measuring platform, and sends the wafer to a designated discharge tray according to the classification (detection) result to achieve the wafer inspection classification. the goal of.

The operation and purpose of the wafer inspection and classification device used in the above-mentioned wafer detection and classification method, and the efficiency and purpose of the wafer inspection classification are the same as those of the foregoing embodiment, so the detailed structure and operation flow of each component are no longer used. Narration.

Efficacy Description: The "wafer detection classification device and its detection classification method" disclosed in this creation mainly uses innovative first unique structural types and technical features such as the first robot arm, the edge finding station, the measuring platform and the second robot arm. According to the conventional structure proposed in [Prior Art], the present invention can classify and classify wafers according to the input detection parameters, and provide a high-speed, precise and classifying wafer inspection and classification device.

10‧‧‧ pedestal 11‧‧ ‧ datum 20 ‧ ‧ feeding 埠 21 ‧ ‧ pedestal 211 ‧ ‧ fixture 30 ‧ ‧ first mechanical arm 31 ‧ ‧ first telescopic access plate 32‧ ‧Second telescopic pick-and-place board 40‧‧‧ Searching station 50‧‧‧Measurement platform 60‧‧‧Drawing 埠61‧‧‧Base 611‧‧‧Clamp 70‧‧‧Second robotic arm 71‧‧‧ Telescopic access plate 80‧‧‧Central control unit 800‧‧‧Interpretation classification module 81‧‧‧Operation interface 82‧‧‧Input interface 90, 90A, 90B, 90C‧‧‧ wafer storage box

The first picture is a three-dimensional appearance of the creation. Figure 2 is a top view of the creation. Figure 3 is a partial exploded view of the creation. Figures 4 to 6 are schematic diagrams of the use of clamps to hold wafer storage boxes of different sizes. Figures 7 to 10 show the action of the first robot arm and the second robot arm to transfer the wafer. Figure 11 is a flow chart of the method for detecting wafers in the present invention.

10‧‧‧ Pedestal

11‧‧‧Datum

20‧‧‧Feeding

40‧‧‧ Looking for the station

50‧‧‧Measurement platform

60‧‧‧Drawing machine

80‧‧‧Central Control Unit

800‧‧‧Interpretation classification module

81‧‧‧Operator interface

82‧‧‧Input interface

90‧‧‧ Wafer Storage Box

Claims (3)

A wafer inspection and classification device mainly includes a pedestal, and a top surface of the pedestal is disposed as a reference surface; a first side of the reference surface is provided with at least one loading raft and adjacent to the a first mechanical arm and a rim searching station; at least one loading platform; a measuring platform installed at a central portion of the reference surface; the second side of the reference surface is provided with a plurality of discharging rafts and a mounting a second robot arm on the inner side of the discharge cassette; the base unit is provided with a central control unit; the reference surface is provided with an operation interface and an input interface, wherein the operation interface and the input interface are respectively electrically Connecting to the central control unit, the first robot arm, the edge finding station, the measuring platform and the second robot arm are respectively electrically connected to the central control unit, and the central control unit has a built-in interpretation a sorting module; the first robot arm takes out the wafer to be inspected from the at least one feed cassette and sends it to the edge finding station, and sets the detection reference point through the edge finding station, and then uses the wafer to be tested a mechanical arm is sent to the measuring platform, and the measuring platform is The detection parameters input by the input interface are started to be detected. After the detection is completed, the obtained detection data is transmitted to the central control unit, and the interpretation classification module is used for the classification, and the central control unit is classified according to the classification result of the classification module. A sorting command is issued to the second robot arm, and the second robot arm transmits the detected wafer to an appropriate discharge port according to the classification instruction from the central control unit to achieve the purpose of wafer inspection and classification. The wafer inspection and classification device according to claim 1, wherein the first mechanical arm has a function of lifting and rotating, and adopts a dual-axis design and includes a first telescopic pick-and-place plate and a second The telescopic pick-and-place board, wherein the first telescopic pick-and-place board and the second telescopic pick-and-place board respectively transfer the wafer from the at least one feed to the edge-finding station, and then transfer the wafer on the edge-finding station To the measurement platform. The wafer inspection and sorting device of claim 1 or 2, wherein the at least one loading cassette comprises at least one base, wherein the at least one base is configured to detachably mount at least one wafer storage box The at least one base is provided with a plurality of clamps, so as to install the wafer storage boxes of different specifications according to actual requirements; the structure of the at least two discharges is the same as the at least one feed, and also includes At least two bases, the at least two bases are configured to detachably mount at least two wafer storage boxes, wherein the at least two bases are provided with a plurality of clamps, so as to install different sizes of wafer storage boxes according to actual requirements. .