CN108942570A - Silicon rod Multi-position processing machine and silicon rod multiplexing position processing method - Google Patents

Abstract

The application discloses a kind of silicon rod Multi-position processing machine and silicon rod multiplexing position processing method, which includes: base, has silicon rod processing platform；Silicon rod handler carries out the handling operation of silicon rod for the pretreatment position in silicon rod processing platform；First processing unit (plant), the silicon rod on the first processing position to silicon rod processing platform carry out the first processing operation；Second processing unit (plant), the silicon rod on the second processing position to silicon rod processing platform carry out the second processing operation；Silicon rod conversion equipment, for converting silicon rod between pretreatment position, the first processing position and the second processing position.The application silicon rod Multi-position processing machine, multiple processing unit (plant)s are gathered, by silicon rod quickly, it is steady and converted with no damage in each processing district interdigit, the multiple processing operations for realizing silicon rod processing can be automated, each processing operation seamless connection, it saves labour turnover and improves production efficiency, improve the quality of silicon rod processing operation.

Description

Silicon rod Multi-position processing machine and silicon rod multiplexing position processing method

Technical field

This application involves silicon workpiece processing technologies, add more particularly to silicon rod Multi-position processing machine and silicon rod multistation Work method.

Background technique

Currently, with attention and opening that society utilizes green regenerative energy sources, photovoltaic solar power field is more next More paid attention to and is developed.In field of photovoltaic power generation, common crystal silicon solar energy battery be made of the high quality silicon on piece, This silicon wafer is formed after the silicon ingot for lifting or casting by multi-thread saw cut and following process.

The production process of existing silicon wafer, by taking single crystal silicon product as an example, generally, rough flow chart can include: first make Truncation operation is carried out to form the short silicon rod of multistage to long silicon rod originally with silicon rod shear；After the completion of truncation, and use silicon rod Excavation machine forms silicon single crystal rod after carrying out evolution operation to the short silicon rod after truncation；Round as a ball, mill is carried out to each silicon single crystal rod again Face etc. processes operation, so that the surface shaping of silicon single crystal rod reaches corresponding flatness and size tolerance requirements；It is subsequent to reuse Slicer carries out slice operation to silicon single crystal rod, then obtains monocrystalline silicon piece.And by taking polysilicon product as an example, it is generally, rough Flow chart can include: evolution processing first is carried out to form secondary silicon to first grade silicon ingot (large scale silicon ingot) using silicon ingot excavation machine Ingot (small size silicon ingot)；After evolution, reuses silicon ingot shear and truncation processing is carried out to form polysilicon to secondary grade silicon ingot Stick；The processing operation such as chamfering, barreling is carried out to each polycrystalline silicon rod again, so that the surface shaping of polycrystalline silicon rod reaches corresponding flat Whole degree and size tolerance requirements；It is subsequent to reuse slicer slice operation is carried out to polycrystalline silicon rod, then obtain polysilicon chip.

But, under general scenario, in the related art, each procedures (such as grinding, chamfering, barreling or round as a ball Deng) needed for operation be independent arrangement, corresponding processing unit (plant) is dispersed in different production unit or workshop or production vehicle Between different production areas, the conversion for executing the workpiece of different procedures needs to carry out carrying allotment, and is executing each work It may require to carry out pretreatment work before sequence operation, in this way, process is many and diverse, inefficiency, and easily influence silicon rod processing and make The quality of industry needs more manpowers or transloading equipment, and security risk is big, in addition, the flowing between the operating equipment of each process Link is more, and the risk of workpiece damage is improved during workpiece transfer, is also easy to produce unqualified caused by nonproductive factors, reduction Unreasonable loss brought by the qualification rate of product and existing processing method, is the major improvement class that each company faces Topic.

Apply for content

In view of the disadvantages of the above existing the relevant technologies, the purpose of the application is to disclose a kind of silicon rod multistation processing Machine and silicon rod multiplexing position processing method, for solving inefficiency, silicon between each procedures present in existing the relevant technologies The problems such as stick transfer is many and diverse and silicon rod processing operation effectiveness is not good enough.

To achieve the above object and other purposes, the application disclose a kind of silicon rod Multi-position processing machine on the one hand, comprising: Base has silicon rod processing platform；Silicon rod handler, set on the pretreatment position of the silicon rod processing platform, for will be to The silicon rod of processing load to the pretreatment position of the silicon rod processing platform and will be processed after silicon rod add from the silicon rod The pretreatment position of work platform unloads；First processing unit (plant), set on the silicon rod processing platform first process position, for pair The silicon rod carries out the first processing operation；Second processing unit (plant), second set on the silicon rod processing platform processes position, is used for The second processing operation is carried out to by the first post-job silicon rod of processing of first processing unit (plant)；Silicon rod conversion equipment, rotation Turn be set on the silicon rod processing platform, for by by the silicon rod handler load Lai silicon rod processed in the silicon rod It is converted between pretreatment position, the first processing position and the second processing position on platform.

The application silicon rod Multi-position processing machine, has gathered multiple processing unit (plant)s, can be by silicon rod using silicon rod handler Quickly, steadily and with no damage loaded and unloaded, using silicon rod conversion equipment can by silicon rod between each processing unit (plant) orderly and The multiple procedures for realizing silicon rod processing are seamlessly shifted and are automated, multiple processing unit (plant)s can be simultaneously to corresponding silicon Stick carries out corresponding processing operation, improves the quality of production efficiency and product processing operation.

In some embodiments, the silicon rod handler includes: silicon rod handling position, equipped with for carrying the silicon Stick erects the silicon rod plummer placed；Commutate carrier, for making commutation movement；Silicon rod clamper, set on the of the commutation carrier One mounting surface；Wherein, by driving the commutation carrier to make commutation movement, so that the silicon rod clamper of the commutation carrier is described Silicon rod is loaded and unloaded and is converted between position and the pretreatment position to transfer the silicon rod.

In some embodiments, the silicon rod clamper includes: fixture installation part, is set on the commutation carrier；At least Two silicon rod clamping pieces are arranged along the fixture installation part spacing；Each described silicon rod clamping piece includes: clamp arm installation Seat is set on the fixture installation part；At least two clamp arm are movably arranged in the clamp arm mounting base；Clamp arm driving mechanism is used Make opening and closing movement in driving at least two clamp arm.

In some embodiments, at least one silicon rod clamping piece in at least two silicon rods clamping piece is equipped with guiding Driving mechanism, for driving it along the fixture installation part movement, to adjust at least two silicon rod clamping piece Spacing.

In some embodiments, the silicon rod handler further include: height testing instrument is set to the commutation carrier On, for detecting the height of the silicon rod.

In some embodiments, the silicon rod Multi-position processing machine further includes flatness detector, is set to the commutation Second mounting surface of carrier, for carrying out planar smoothness detection to the silicon rod.

In some embodiments, the flatness detector includes: contact measurement structure；Detector shift mechanism； Controller is detected, is connect with the contact measurement structure and the detector shift mechanism, is moved for controlling the detector Position mechanism drives the contact measurement structural shift and the control contact measurement structure sequentially to detect in the silicon rod The relative distance of each test point on tested surface.

In some embodiments, the silicon rod conversion equipment includes: the conveying ontology of disc or circular ring shape；Silicon rod is fixed Position mechanism, is set on the conveying ontology, for positioning to the silicon rod；Driving mechanism is converted, it is described defeated for driving It send ontology to rotate and position is converted with the silicon rod for driving the silicon rod positioning mechanism to be positioned.

In some embodiments, the silicon rod positioning mechanism includes: rotation plummer, is set to the disc or annulus On the conveying ontology of shape, for carrying the silicon rod；Rotary compacting device is relatively arranged on the top of the rotation plummer, For compressing the silicon rod；Lifting drive, for driving the rotary compacting device to make elevating movement along the vertical direction；Rotation Rotary driving device, for driving the rotary compacting device and the rotary compacting device being driven to rotate.

In some embodiments, first processing unit (plant) includes: the first rack；At least a pair of first grinding tool, it is opposite It is set in first rack, adds for carrying out first to the silicon rod on the silicon rod conversion equipment being located at the first processing position Work industry.

In some embodiments, first grinding tool includes: the first main shaft；At least one first grinding wheel is set to described The operation end of first main shaft；First grinding wheel has the first frosted particle of the first granularity.

In some embodiments, second processing unit (plant) includes: the second rack；At least a pair of second grinding tool, it is opposite It is set in second rack, adds for carrying out second to the silicon rod on the silicon rod conversion equipment being located at the second processing position Work industry.

In some embodiments, second grinding tool includes: the second main shaft；At least one second grinding wheel is set to described The operation end of second main shaft；Second grinding wheel has the second frosted particle of the second granularity.

In some embodiments, the silicon rod Multi-position processing machine further includes protective door, for will pre-process position and The first processing position and second processing position are isolated.

In some embodiments, the pretreatment position on the silicon rod processing platform, the first processing position and second Processing position is in 120 ° of distributions between any two, and the rotation angle range of the silicon rod conversion equipment is ± 240 °.

In some embodiments, the silicon rod Multi-position processing machine further includes third processing unit (plant), is set to the silicon The third of stick processing platform processes position；Pretreatment position, the first processing position, the second processing on the silicon rod processing platform In 90 ° of distributions between position and third processing district are adjacent two-by-two, the rotation angle range of the silicon rod conversion equipment is ± 270°。

In some embodiments, the rotation angle range of the silicon rod conversion equipment is ± 360 ° or the silicon rod turns Changing device uses unidirectional unlimited rotary mode.

The application discloses a kind of silicon rod multiplexing position processing method on the other hand, comprising the following steps: enables silicon rod handling dress The pretreatment position that the first silicon rod to be processed is loaded into silicon rod processing platform is set, and at the pretreatment position First silicon rod is pre-processed；Silicon rod conversion equipment is enabled to rotate the first predetermined angle so that pretreated first silicon rod will be completed by pre- It converts to the first processing position processing position；It enables the first processing unit (plant) carry out first to the first silicon rod on the first processing position to add Work industry, in this stage, enables silicon rod handler that the second silicon rod to be processed is loaded into pretreatment position and pre-processes； Silicon rod conversion equipment is enabled to rotate the second predetermined angle will complete the first silicon rod of the first processing operation by the first processing position and turn It shifts to the second processing position and pretreated second silicon rod will be completed and converted by pre-processing position to the first processing position；Enable Two processing unit (plant)s carry out the second processing operation to the first silicon rod on the second processing position and enable the first processing unit (plant) in this stage First processing operation is carried out to the second silicon rod on the first processing position and enables silicon rod handler by third silicon to be processed Stick is loaded into pretreatment position and is pre-processed.

The silicon rod multiplexing position processing method of the application, can be silicon rod is quick, steady and lossless using silicon rod handler It is loaded and unloaded to wound, silicon rod orderly and can seamlessly be shifted simultaneously between each processing unit (plant) using silicon rod conversion equipment Automation realizes that multiple procedures of silicon rod processing, multiple processing unit (plant)s can simultaneously process corresponding silicon rod accordingly Operation improves the quality of production efficiency and product processing operation.

In some embodiments, the pretreatment position on the silicon rod processing platform, the first processing position and second Processing position is in 120 ° of distributions between any two；When according to the pretreatment position, the first processing position and the second processing position The trend of sequence when being defined as forward direction, the first predetermined angle for enabling silicon rod conversion equipment rotate is to rotate forward 120 °；It enables It is to rotate forward 120 ° that silicon rod conversion equipment, which rotates the second predetermined angle,.

In some embodiments, the silicon rod multiplexing position processing method further include: silicon rod conversion equipment is enabled to rotate third Predetermined angle is converted by the second processing position to pretreatment position and will be complete with the first silicon rod that will complete the second processing operation It is converted by the first processing position to the second processing position at the second silicon rod of the first processing operation and pretreated third will be completed Silicon rod is converted by pre-processing position to the first processing position；Silicon rod handler is enabled to carry out the first silicon rod on position is pre-processed It unloads and is loaded into the 4th silicon rod to be processed and pre-process position and to the 4th silicon rod being located at the pretreatment position It is pre-processed, in this stage, the second processing unit (plant) is enabled to carry out the second processing operation to the second silicon rod on the second processing position And the first processing unit (plant) is enabled to carry out the first processing operation to the third silicon rod on the first processing position.

In some embodiments, the pretreatment position on the silicon rod processing platform, the first processing position and second Processing position is in 120 ° of distributions between any two；When according to the pretreatment position, the first processing position and the second processing position The trend of sequence when being defined as forward direction, first predetermined angle for enabling silicon rod conversion equipment rotate is to rotate forward 120°；Described enables silicon rod conversion equipment rotate the second predetermined angle to rotate forward 120 °；Described enables silicon rod conversion equipment Rotation third predetermined angle is to rotate forward 120 ° or 240 ° of backwards rotation.

Detailed description of the invention

Fig. 1 is shown as stereochemical structure signal of the silicon rod Multi-position processing machine under a certain visual angle in the application embodiment Figure.

Fig. 2 is shown as the top view of silicon rod Multi-position processing machine in the application embodiment.

Fig. 3 is shown as the side view of silicon rod Multi-position processing machine in the application embodiment.

Fig. 4 is shown as the structural representation of silicon rod clamping piece in one embodiment in the application silicon rod Multi-position processing machine Figure.

Fig. 5 is shown as the structural representation of silicon rod clamping piece in another embodiment in the application silicon rod Multi-position processing machine Figure.

Fig. 6 is shown as the rearview of silicon rod clamper in the application silicon rod Multi-position processing machine.

Fig. 7 is shown as the flow diagram of the application silicon rod multiplexing position processing method in one embodiment.

Fig. 8 is shown as the flow diagram of the application silicon rod multiplexing position processing method in another embodiment.

Fig. 9 is shown as silicon rod and is straightened the status diagram being placed on silicon rod plummer.

Figure 10 is shown as the status diagram that silicon rod is clamped by silicon rod clamper.

Figure 11 is shown as the status diagram that silicon rod is placed in pretreatment position by commutation carrier.

Figure 12 is shown as the status diagram that height testing instrument detection is located at silicon rod height on handling plummer.

Figure 13 and Figure 14 is shown as the status diagram of flatness detector detection silicon rod planar smoothness.

Figure 15 is shown as carrying out silicon single crystal rod in the schematic diagram of correction operation.

Figure 16 is shown as carrying out polycrystalline silicon rod in the schematic diagram of correction operation.

Figure 17 is shown as the status diagram for the first processing operation being carried out to the first silicon rod and the second silicon rod is loaded.

Figure 18 is shown as state change schematic diagram of the silicon single crystal rod in circle of contact processing operation.

Figure 19 is shown as state change schematic diagram of the silicon single crystal rod in corase grinding processing operation.

Figure 20 is shown as state change schematic diagram of the polycrystalline silicon rod in corase grinding processing operation.

The state that Figure 21 shows that the silicon rod Multi-position processing machine of the application carries out processing operation to three silicon rods simultaneously is illustrated Figure.

Figure 22 is shown as status diagram of the silicon single crystal rod in round as a ball processing operation.

Figure 23 is shown as status diagram of the silicon single crystal rod in fine grinding operation.

Figure 24 is shown as status diagram of the polycrystalline silicon rod in chamfer machining operation.

Figure 25 is shown as status diagram of the polycrystalline silicon rod in fine grinding operation.

Figure 26 is shown as completing the status diagram of the silicon rod discharging of processing operation.

It is the status diagram that three stations are processed in operation that Figure 27, which is shown as the application silicon rod Multi-position processing machine,.

It is the status diagram that four stations are processed in operation that Figure 28, which is shown as the application silicon rod Multi-position processing machine,.

Specific embodiment

Illustrate presently filed embodiment below by way of specific specific example, those skilled in the art can be by this specification Disclosed content understands other advantages and effect of the application easily.The application can also pass through in addition different specific realities The mode of applying is embodied or practiced, the various details in this specification can also based on different viewpoints and application, without departing from Various modifications or alterations are carried out under spirit herein.

It should be noted that this specification structure depicted in this specification institute accompanying drawings, ratio, size etc., only to cooperate The bright revealed content of book is not limited to the enforceable limit of the application so that those skilled in the art understands and reads Fixed condition, therefore do not have technical essential meaning, the modification of any structure, the change of proportionate relationship or the adjustment of size, not It influences still fall in techniques disclosed in this application content under the effect of the application can be generated and the purpose that can reach and obtain In the range of capable of covering.Meanwhile it is cited such as "upper", "lower", "left", "right", " centre " and " one " in this specification Term is merely convenient to being illustrated for narration, rather than to limit the enforceable range of the application, the change of relativeness or tune It is whole, under the content of no substantial changes in technology, when being also considered as the enforceable scope of the application.

The inventors of the present application found that in the relevant processing operation technique for silicon rod, the grinding that is related to, chamfering, The processing unit (plant)s such as barreling disperse each other and independently arrange, the conversion for executing the silicon rod of different procedures is carried The problems such as pretreatment before allotment and processing, there are process is many and diverse and inefficiency.

In view of this, present applicant proposes a kind of silicon rod Multi-position processing machine and silicon rod multiplexing position processing methods, by setting Standby transformation, has gathered multiple processing unit (plant)s within one device, by silicon rod quickly, it is steady and with no damage in each processing position Between converted, can automate realize silicon rod processing multiple processing operations and can simultaneously to corresponding silicon rod carry out accordingly add Work industry, seamless connection between each processing operation, saves labour turnover and improves production efficiency, improves silicon rod processing operation Quality.

It please refers to Fig.1 to Fig.3, is shown as the structural representation of the application silicon rod Multi-position processing machine in one embodiment Figure, wherein Fig. 1 is schematic perspective view of the silicon rod Multi-position processing machine under a certain visual angle in the application embodiment, Fig. 2 For the top view of silicon rod Multi-position processing machine in the application embodiment, Fig. 3 is that silicon rod multistation adds in the application embodiment The side view of work machine.In one embodiment, the application silicon rod Multi-position processing machine be for carrying out processing operation to silicon rod, Here, the silicon rod is class rectangle silicon rod, either silicon single crystal rod can also should belong to the guarantor of the application with polycrystalline silicon rod Protect range.

By taking silicon single crystal rod as an example, the formation process of silicon single crystal rod can include: first using silicon rod shear to long silicon originally Stick carries out truncation operation to form the short silicon rod of multistage；After the completion of truncation, but use squaring silicon bar machine to the short silicon rod after truncation into Row evolution operation Formation cross-section is in the silicon single crystal rod of class rectangle.Wherein, long silicon rod originally is cut using silicon rod shear Disconnected operation with formed the specific implementation of the short silicon rod of multistage can refer to for example, CN105856445A, CN105946127A, with And the patent publication us such as CN105196433A, it is formed after carrying out evolution operation to the short silicon rod after truncation using squaring silicon bar machine Section then can refer to the patent publication us such as CN105818285A in the specific embodiment of the silicon single crystal rod of class rectangle.But monocrystalline The formation process of silicon rod simultaneously loses and is limited to aforementioned techniques, and in optional example, the formation process of silicon single crystal rod may also include that and first make Long silicon single crystal rod of the evolution operation with Formation cross-section in class rectangle is carried out to long silicon rod originally with total silicon stick excavation machine；Evolution is complete Cheng Hou, and truncation operation is carried out to the long silicon single crystal rod after evolution using silicon rod shear and forms short crystalline silicon rod.Wherein, among the above Evolution operation is carried out to form the specific reality of the long silicon single crystal rod in class rectangle to long silicon rod originally using total silicon stick excavation machine Existing mode can refer to the patent publication us such as example, CN106003443A.

And by taking polycrystalline silicon rod as an example, the formation process of polycrystalline silicon rod can include: first using silicon ingot excavation machine to first grade silicon ingot Or silicon cube (large scale silicon ingot) carries out evolution processing to form time grade silicon ingot (small size silicon ingot)；After evolution, reuse Silicon ingot shear carries out truncation processing to secondary grade silicon ingot to form polycrystalline silicon rod.Wherein, using silicon ingot excavation machine to first grade silicon ingot (large scale silicon ingot) carries out evolution processing can refer to for example, with the specific implementation for forming time grade silicon ingot (small size silicon ingot) The patent publication us such as CN102172997A, CN105216128A, CN105690582A, using silicon ingot shear to secondary grade silicon ingot It carries out truncation processing and can refer to the patent disclosures such as example, CN105196434A text to form the specific implementation of polycrystalline silicon rod It offers.

Either silicon single crystal rod also or polycrystalline silicon rod, must all carry out corresponding following process operation, these it is subsequent plus Work industry may be, for example, grinding, chamfering, barreling or round as a ball etc., and these following process operations can pass through silicon described herein Stick Multi-position processing machine is implemented.

In conjunction with Fig. 1 to Fig. 3, the application silicon rod Multi-position processing machine includes: base 1, the processing of silicon rod handler 2, first Device 3, the second processing unit (plant) 4 and silicon rod conversion equipment 5.

The application silicon rod Multi-position processing machine is described in detail below.

Main element of the base 1 as the application silicon rod Multi-position processing machine has silicon rod processing platform, wherein described Silicon rod processing platform can process the specific job content of operation according to silicon rod and be divided into multiple function positions.Specifically, at this In embodiment, the silicon rod processing platform includes at least pretreatment position, the first processing position and the second processing position.

Silicon rod conversion equipment 5 is set to the centered region of the silicon rod processing platform, for that will be loaded by silicon rod handler 2 Pretreatment position of the silicon rod 100 to come up on the silicon rod processing platform, the first processing position and the second processing position it Between convert.In one embodiment, 5 rotary setting of silicon rod conversion equipment is on the silicon rod processing platform, silicon rod conversion equipment 5 It include: the conveying ontology 51 of disc or circular ring shape；Silicon rod positioning mechanism 53 is set on conveying ontology 51, for carrying out to silicon rod Positioning；The silicon rod translation bit that conversion driving mechanism is used to that conveying ontology 51 to be driven to rotate to drive silicon rod positioning mechanism 53 to be positioned It sets.

As previously mentioned, silicon rod processing platform in one embodiment include pretreatment position, first processing position, with And the second processing position, to be adapted with these function positions, the quantity for conveying the silicon rod positioning mechanism 53 on ontology 51 can be set Three are set to, each silicon rod positioning mechanism 53 can position a silicon rod.Further, 53 liang of these three silicon rod positioning mechanisms Set angle is also consistent with the angular distribution of three function positions between any two between two.In this way, working as some silicon Stick positioning mechanism 53 correspond to some function position when, inevitably, other two silicon rod positioning mechanisms 53 be also respectively with its His two function positions are corresponding.In this way, in continuous productive process, any moment, when fixed on each silicon rod positioning mechanism 53 There is a silicon rod in position and when silicon rod positioning mechanism 53 is corresponding with function position, then these silicon rods are located in corresponding a certain function Corresponding processing operation can be executed at position, such as: the silicon rod positioned at pretreatment position can carry out pre-treatment job, be located at the The silicon rod of one processing position can carry out the first processing operation, and the silicon rod positioned at the second processing position can carry out the second processing operation. In an alternative embodiment, the pretreatment position on the silicon rod processing platform, the first processing position and the second processing district Position is between any two in 120 ° of distributions, is three silicon rods on the conveying ontology 51 of disc or circular ring shape correspondingly therefore Positioning mechanism 53 is between any two also in 120 ° of distributions.Certainly, the quantity of silicon rod positioning mechanism 53 can be become according to actual needs Change and be not limited thereto, for example, the quantity of silicon rod positioning mechanism 53 can be according to the function position that silicon rod processing platform is arranged Depending on quantity.

In one embodiment, silicon rod positioning mechanism 53 is more can include: rotation plummer 531, rotary compacting device 533, Lifting drive (not indicated in figure) and rotation drive device (not indicated in figure).

Rotation plummer 531 is set in silicon rod conversion equipment 5 on the conveying ontology 51 of disc or circular ring shape, for holding It carries silicon rod 100 and silicon rod 100 is placed to erect, that is, the bottom of silicon rod 100 is seated on rotation plummer 531.In this reality It applies in mode, rotates plummer 531 and in silicon rod conversion equipment 531 one when the rotation of the conveying ontology 51 of disc or circular ring shape And it rotates.Particularly, rotation plummer 531 can also be designed as can spinning motion, such as rotation plummer 531 relative to conveying this Body 51 has shaft to realize spinning motion, in this way, rotating plummer after rotating 531 support of plummer silicon rod 100 531 and silicon rod 100 thereon can rotate together.Further, the contact surface in plummer 531 for contacting with silicon rod is rotated With damping, to provide the frictional force that silicon rod can be driven certain.Rotation plummer 531 is adapted to silicon rod 100, in an optional implementation In example, rotation plummer 531 can be round plummer compatible with the sectional dimension of silicon rod 100.

Rotary compacting device 533 is relatively arranged on the top of rotation plummer 531, for pressing in the top of silicon rod 100 To compress silicon rod 100.Rotary compacting device 533 can further comprise the support 532 of activity setting and be set to 532 bottom of support The press movable block 534 in portion.Support 532 is movably set on a central mounting rack 13, which is positioned at defeated It send the middle section of ontology 51 and is followed by conveying ontology 51 and rotate together.In specific implementation, central mounting rack 13 can be at least Including the six roots of sensation mounting post 131 being vertically arranged, it is divided into three groups in a manner of every group two, wherein two mounting posts in every group 131 for activity setting one support 532, each support 532 by a lifting drive drive and along mounting post 131 and Make elevating movement.In an alternative embodiment, mounting post 131 is that the relatively smooth cylindrical structure in surface can installed when necessary 131 surface of column coats lubricating oil, in favor of the smoothness of 532 elevating movement of support.Extraly, it can be arranged in mounting post 131 Protective sleeve avoids dust, sundries etc. from polluting to be protected mounting post 131.It presses movable block 534 and silicon rod 100 is suitable Match, in an alternative embodiment, press movable block 534 can be patty briquetting compatible with the sectional dimension of silicon rod 100. Further, 534 axis of press movable block in rotary compacting device 533 turn be connected to support 532 and can relative seat 532 and It can rotate.

It lives in the foregoing it is found that rotating plummer 531 and being designed to the press in spinning motion and rotary compacting device 533 534 axis of motion block turns to be connected to support 532, therefore, rotates plummer 531 or press 534 linkage of movable block and drives in a rotation Dynamic device.In one case, when rotation plummer 531 is in linkage with a rotation drive device, by 531 conduct of rotation plummer Active rotatable parts and press movable block 534 then as driven rotation component；In another scenario, when press movable block 534 When being in linkage with a rotation drive device, rotated by press movable block 534 as active rotatable parts plummer 531 then as from Turn dynamic component.

In practical applications, rotary compacting device 533 can cooperate with the rotation plummer 531 under it, specifically, when By silicon rod 100 it is vertical be placed in rotation plummer 531 on after, by lifting drive driving support 532 along mounting post 131 Make descending motion until the press movable block 534 on support 532 presses on the top of silicon rod 100.It is subsequent, it is needing to rotate silicon rod When 100, is rotated by the rotation plummer 531 or press movable block 534 of rotation drive device driving linkage, carried using rotation Platform 531, silicon rod 100 and the mutual frictional force of press movable block 534, take advantage of a situation and silicon rod 100 are driven also to rotate together, real The adjustment of work surface or operating area in existing silicon rod 100, so as to work surface adjusted in silicon rod 100 or operating area Carry out processing operation.The velocity of rotation and rotational angle of silicon rod 100 can be controlled by rotation drive device.In specific implementation side In formula, lifting drive may be, for example, cylinder or lifting motor, and rotation drive device then may be, for example, rotating electric machine.

Further, from the foregoing, it will be observed that in some cases, rotation can be controlled by by rotating plummer 531 or press movable block 534 Rotary driving device and rotate to drive the rotation of silicon rod 100 to change work surface or operating area, sometimes, when silicon rod 100 turns to It then needs to stop actuation when required work surface or operating area and positions to receive processing unit (plant) in corresponding function position Processing operation.Therefore, in this application, if it is necessary to can also configure a lockable mechanism for the silicon rod positioning mechanism.In one kind In implementation, a plummer lockable mechanism can be configured (not at the bottom of central mounting rack 13 and neighbouring rotation plummer 531 Show in the drawings), the plummer lockable mechanism may include locking bolt and the lock-up cylinder that connect with locking bolt.In reality In the application of border, when needing to lock rotation plummer 531, the lock-up cylinder in plummer lockable mechanism just drives locking bolt to stretch Out and act on the bottom for rotating plummer 531 or neck, it is ensured that rotation plummer 531 consolidates motionless；Wait need to rotate silicon rod When changing work surface or operating area, then by the plummer lockable mechanism lock-up cylinder driving locking bolt shrink, Unlock rotation plummer 531, so that rotation plummer 531 is able to rotate.

The conveying ontology 51 of disc or circular ring shape is controllable by the driving of conversion driving mechanism and rotates, and passes through disc Or the conveying ontology 51 of circular ring shape rotation and realize conveying ontology 51 on silicon rod positioning mechanism 53 and by silicon rod positioning mechanism 53 silicon rods 100 positioned are converted between different function positions.

In one embodiment, the conversion driving mechanism further comprises: conversion tooth band, is set to disc or circular ring shape Conveying ontology 51 side；Driving motor and connection driving motor and be driven motor-driven linkage structure, be set to base 1 Silicon rod processing platform on, the linkage structure includes the rotate gear being meshed with the conversion tooth band.In this way, the rotation Gear drives the conveying ontology 51 of disc or circular ring shape to rotate to drive silicon rod positioning mechanism under driving motor driving 53 and thereon silicon rod 100 conversion to other function position complete convey, the driving motor can be servo motor.

Silicon rod handler 2 is set to the pretreatment position of the silicon rod processing platform, for loading silicon rod to be processed To silicon rod processing platform pretreatment position and will be processed after silicon rod unloaded from the pretreatment position of silicon rod processing platform. Further, silicon rod handler 2 be used to load silicon rod to be processed to the pretreatment position of silicon rod processing platform and Silicon rod after will be processed refers specifically to be used to fill silicon rod to be processed from the unloading of the pretreatment position of silicon rod processing platform It is loaded onto conveying ontology 51 on rotation plummer 531 corresponding with the pretreatment position of silicon rod processing platform and after will be processed Silicon rod unloaded on rotation plummer 531 corresponding with the pretreatment position of silicon rod processing platform from conveying ontology 51.

In one embodiment, silicon rod handler 2 further includes: silicon rod loads and unloads position, and commutate carrier 23 and silicon rod folder Tool 25.

Silicon rod handling position is equipped with the silicon rod plummer 21 vertically placed for carrying silicon rod 100；Commutation carrier 23 is used for Make commutation movement；Silicon rod clamper 25 is set to the first mounting surface of commutation carrier 23.Make commutation movement by driving commutation carrier 23, It converts so that the silicon rod clamper 25 of commutation carrier 23 is loaded and unloaded in the silicon rod between position and the pretreatment position to transfer silicon Stick 100.

Silicon rod handler is arranged on a bottom installation structure, and the bottom installation structure is convexly equipped in base 1.Bottom peace The side of assembling structure is then used as silicon rod to load and unload position, is equipped with silicon rod plummer 21, silicon rod plummer 21 on silicon rod handling position For carrying silicon rod 100.It in a preferred embodiment, is the clamping convenient for silicon rod clamper 25, if carrying can be made Silicon rod 100 can adjust position in due course to adapt to silicon rod clamper 25, and therefore, silicon rod plummer 21 is swiveling design, and silicon rod is held Microscope carrier 21 is equipped with rotation axis and driving motor, and silicon rod plummer 21 rotates under the control of driving motor around rotation axis to adjust The angle of silicon rod 100 on silicon rod plummer 21.In addition to this, in an alternative embodiment, silicon rod plummer 21 more be can be used Lift design, that is, expanding-contracting action can be made after the rotation axis of 21 lower section of silicon rod plummer is controlled to drive silicon rod plummer 21 Make elevating movement, so as to adjust the height of the silicon rod on silicon rod plummer 21.

Commutation carrier 23 is set on bottom installation structure and can the work commutation movement of opposing floor portion mounting structure.Implement one In mode, commutation carrier 23 is that commutation movement is realized by a reversing mechanism.So that commutation carrier 23 realizes commutation movement Reversing mechanism may include rotation axis and reversing motor, commutation carrier 23 is tied by bottom installation of the rotation axis axis connection in it under Structure.When implementing divertical motion, then start reversing motor, the rotation of driving rotation axis is to drive commutation carrier 23 to rotate to realize Commutation movement.Aforementioned driving rotation axis rotation may be designed as one-directional rotation and be also designed to Double-directional rotary, and the one-directional rotation can It for example, rotates clockwise or rotates counterclockwise, the Double-directional rotary then may be, for example, to rotate clockwise and rotate counterclockwise.Separately Outside, the angle of driving rotation axis rotation can be set according to actual configuration of silicon rod handler etc., wherein the silicon rod handling dress The actual configuration set may be, for example, to drive the angle of rotation axis rotation that can be loaded and unloaded between position and pretreatment position according to silicon rod The structure etc. of positional relationship or the carrier 23 that commutates.231 central location of commutation pedestal and rotation axis connection in commutation carrier 23, Generally, the structure of disk can be used in the shape of commutation pedestal 231, but is not limited thereto, and square plate or ellipse can also be used Disk.

In addition, in the case of necessity, due to Design of Mechanical Structure, silicon rod load and unload position and pretreatment position it Between positional relationship be not able to satisfy commutation carrier 23 by commutate movement enable commutation carrier 23 on silicon rod clamper 25 just Corresponding to silicon rod loading place and pretreatment position, at this point, silicon rod handler may also include translation mechanism, for driving commutation to carry Have 23 opposing floor portion mounting structures to make towards/away from the translational motion for pre-processing position.In one embodiment, silicon rod handling dress It sets and is separately provided with a conversion chassis 241 between commutation carrier 23 and bottom installation structure, wherein commutation carrier 23 passes through rotation Axis axis connection is set up on bottom installation structure in conversion chassis 241, conversion chassis 241 by translation mechanism.

In a kind of achievable mode, the translation mechanism further comprises: translation rack rails is laid in along translation direction On bottom installation structure；Rotate gear is translated, be set on conversion chassis 241 and is meshed with translation rack rails；Driven in translation electricity Machine (is not illustrated), for driving shiftable gear to be rotated such that conversion chassis 241 and commutation carrier 23 thereon along flat Rack rails is moved to retreat relative to bottom installation structure.

In practical applications, translation rack rails may be, for example, at least one rack gear with certain length, this at least one tooth Item is mountable on bottom installation structure.To convert chassis 241 and commutation carrier 23 thereon more stablely along translation Direction is mobile, can configure at least two shiftable gears, the setting of at least two shiftable gear intervals for each rack gear.Translate tooth Wheel can be sequentially connected by transmission shaft and pan drive motor.Pan drive motor may be, for example, servo motor.

In practical applications, as previously mentioned, the translation mechanism includes translation rack rails, shiftable gear and driven in translation electricity Machine is driven shiftable gear to be rotated such that conversion chassis 241 and commutation carrier 23 thereon along flat by pan drive motor Move the purpose that rack rails is mobile, and realization is precisely moved.Above-mentioned translation mechanism is only one to illustrate, but be not intended to limit this Shen Please, ground, in other alternative embodiments, the translation mechanism are changed can include: lead screw and servo motor, lead screw have high-precision Degree, invertibity and efficient feature improve conversion chassis 241 and thereon in this way, pass through the cooperation of servo motor and lead screw Commutate the horizontal precision advanced in a transverse direction of carrier 23, that is, so that conversion chassis 241 and commutation carrier 23 thereon exist The distance for being translated towards horizontal traveling is more accurate.

Further, in the present embodiment, for make convert chassis 241 and thereon 23 opposing floor portion of commutation carrier installation Structure is moved along translation direction can be more stable and more smooth, and the translation mechanism may also include translating rails and translation slide, Wherein, translating rails are laid in the bottom on conversion chassis 241 along translation direction, and translation slide is installed on bottom installation structure, By the cooperation of translating rails and translation slide, auxiliary conversion chassis 241 and commutation carrier 23 thereon are moved along translation direction It is dynamic.In practical applications, shiftable gear is driven to be rotated such that conversion chassis 241 and commutation thereon by pan drive motor Carrier 23 is moved along translation rack rails, meanwhile, translating rails and translation slide, translating rails as auxiliary equipment are slided in translation It is slid in seat, to realize that conversion chassis 241 and commutation carrier 23 thereon are moved along translation direction.Ground is changed, at it In his embodiment, the translation mechanism may also include translating rails and translator slider, wherein translating rails are laid along translation direction In on bottom installation structure, translation slide is installed on the bottom on conversion chassis 241, passes through the cooperation of translating rails and translator slider Translator slider may make to slide along translating rails, to assist conversion chassis 241 and commutation carrier 23 thereon along translation Direction is mobile.

Silicon rod clamper 25 is for clamping silicon rod.In one embodiment, silicon rod clamper 25 includes: 251 He of fixture installation part At least two silicon rod clamping pieces 253.Fixture installation part 251 is set on commutation carrier 23.At least two silicon rod clamping pieces 253 are edges 251 spacing of fixture installation part setting.In one embodiment, the Workpiece carrier platform at aforementioned silicon rod handling position can carry silicon Stick, which is erect, to be placed, and therefore, at least two silicon rod clamping pieces 253 are vertical interval setting, that is, at least two silicon rod clamping pieces 253 It is setting up and down.

In specific implementation, each silicon rod clamping piece 253 is further included: clamp arm mounting base 252 and at least two folders Arm 254, wherein clamp arm mounting base 252 is provided on fixture installation part 251, and at least two clamp arm 254 are to be movably arranged at clamp arm peace It fills on seat 252.In view of as silicon rod to be processed either silicon single crystal rod or polycrystalline silicon rod, the section of silicon rod is polygon Shape, in the related art, the section of silicon rod are in class rectangle more, therefore, in one embodiment, silicon rod clamping piece 253 it is whole and Speech is square workpiece fixture, and the clamp arm 254 of composition silicon rod clamping piece 253 is two of symmetric design, and single clamp arm 254 is designed as With single clamped flat face (referring to fig. 4) or dog-ear clamping face (referring to Fig. 5), the dog-ear clamping face is by continuous two Clamped flat face forms, and has a dog-ear between two clamped flat faces.Certainly, may be used also on the clamped flat face in clamp arm 254 Additional cushion causes the damage to silicon rod surface for avoiding during clamping silicon rod, plays protection silicon rod Good result.Extraly, the effect for the adjusting that centers can be more had both using silicon rod clamping piece 253.

Under general scenario, the clamp arm 254 in silicon rod clamping piece 253 is under clamping state, folder that two clamp arm 254 are constituted The center for holding space is coincided with the center of silicon rod plummer 21.Therefore, with the silicon rod with clamp arm 254 shown in fig. 5 For clamping piece 253, when erectting the silicon rod 100 of placement on using 253 de-clamping silicon rod plummer 21 of silicon rod clamping piece, silicon rod Clamp arm 254 in clamping piece 253 is shunk, and is resisted against silicon rod 100 by the dog-ear clamping face in clamp arm 254, wherein the dog-ear folder It holds two in face clamped flat faces and corresponds respectively to two sides adjacent in silicon rod 100.Simultaneously clamping silicon is shunk in clamp arm 254 During stick 100, silicon rod 100 is pushed by two clamp arm 254 of both sides and towards the movement of the middle section of grasping part, directly It is clamped to silicon rod 100 by two clamp arm 254 in silicon rod clamping piece 253, at this point, the center of silicon rod 100 can be located at silicon rod The center of the grasping part of clamping piece 253.Particularly, to enable at least two clamp arm 254 in silicon rod clamping piece 253 smooth And it is held fixedly the silicon rod of different type difference dimensions, silicon rod clamping piece 253 further includes clamp arm driving mechanism, is used for At least two clamp arm 254 are driven to make opening and closing movement.

Referring to Fig. 6, its rearview for being schematically shown as silicon rod clamper 25.In specific implementation, as shown in fig. 6, clamp arm drives Mechanism further comprises: folding gear 255, gear drive 256 and driving source 257.

Opening and closing gear 255 is set in corresponding clamp arm 254.Gear drive 256 has and the folding in clamp arm 254 The groove that gear 255 engages.Driving source is connected to gear drive 256, for driving gear drive 256 to move.In one kind On implementation, gear drive 256 is rack gear, which is located at the centre of two clamp arm 254, in rack gear respectively for Corresponding tooth is engaged with the folding gear 255 in two clamp arm 254 in being respectively equipped on two lateral surfaces of the clamp arm 254 of two sides Line, driving source 257 may be, for example, driving motor or or cylinder.

In this way, according to above-mentioned implementation, in practical applications, when that need to realize 254 clamping of clamp arm, by as driving source Driving motor or cylinder driving moved up as the rack gear 256 of gear drive, drive what both sides engaged to open by rack gear 256 It closes gear 255 and makees outward turning movement, folding gear 255 drives clamp arm 254 during revolving outside (folding gear 255 and clamp arm 254 can Connected by shaft) make decentralization movement to be transferred to clamping state by releasing orientation；Conversely, when that need to realize that clamp arm 254 is unclamped, by Driving motor (or cylinder) driving as driving source is moved down as the rack gear 256 of gear drive, is driven by rack gear 256 The folding gear 255 of both sides engagement makees pronation, and folding gear 255 drives (the folding gear of clamp arm 254 during revolving inside 255 can be connect with clamp arm 254 by shaft) raising up acts to be transferred to releasing orientation by clamping state.Certainly, it above are only one Embodiment is not intended to limit the working condition of silicon rod clamping piece 253, in fact, " upward ", " outward turning " in aforementioned, " under Put ", " downward ", " inward turning ", " raising up " and " release " and " clamping " state change can be according to the structure and fortune of clamp arm 254 Make mode, clamp arm driving mechanism construction and have other changes.

Just as it is known by a person skilled in the art that silicon single crystal rod or polycrystalline silicon rod are directed to, due to long silicon rod originally or just The specification of grade silicon ingot (large scale silicon ingot) is different, carries out truncation operation to long silicon rod originally or carries out evolution work to first grade silicon ingot Industry and truncation operation are different, are bound to so that between silicon single crystal rod and polycrystalline silicon rod, between silicon single crystal rod individual and polycrystalline silicon rod Size difference between individual is totally different, in view of silicon rod clamper 25 be for erect placement status under silicon rod 100 clamp, Therefore, for silicon rod clamper 25, the influence of aforementioned dimensions difference mainly just shows the length difference opposite sex of silicon rod to silicon rod Whether the silicon rod clamping piece 253 in fixture 25 can correspond to the secret worry for being clamped to silicon rod.

To reduce the risk even exempted above-mentioned silicon rod clamping piece 253 and may can not be clamped to silicon rod.In a kind of reality In existing mode, silicon rod clamper 25 uses fixed silicon rod clamping piece, that is, with vertical side on the first mounting surface of commutation carrier 23 Silicon rod clamping piece 253 as much as possible is fixedly installed in formula, and, two neighboring silicon rod clamping piece 253 in these silicon rod clamping pieces 253 Spacing it is as small as possible, in this way, using these silicon rod clamping pieces 253 can cover all kinds scale lengths silicon rod.For example, if silicon The length of stick is longer, then participates in clamping using silicon rod clamping piece 253 more on commutation carrier 23；If the length of silicon rod is shorter, Then clamping is participated in using silicon rod clamping piece 253 less on commutation carrier 23.

And in other implementations, silicon rod clamper 25 uses movable silicon rod clamping piece, that is, the of commutation carrier 23 Silicon rod clamping piece 253 is arranged in activity in a manner of vertical on one mounting surface, due to, silicon rod clamping piece 253 is movable design, because This, the quantity of silicon rod clamping piece 253 can be greatly decreased, and generally two or three can meet.In this way, utilizing these activities Formula silicon rod clamping piece 253 can cover all kinds scale lengths silicon rod.For example, moving silicon rod clamping if the length of silicon rod is longer Part 253 extends the clamping spacing of two silicon rod clamping pieces 253；If the length of silicon rod is shorter, silicon rod clamping piece 253 is moved, is contracted The clamping spacing of short two silicon rod clamping pieces 253.In implementation of the silicon rod clamper 25 using movable silicon rod clamping piece, it is It is smooth smoothly up and down to adjust position convenient for movable silicon rod clamping piece, it is installed using the fixture in silicon rod clamper 25 Part 251 plays the guiding role of boot activity formula silicon rod clamping piece 253, and in a kind of achievable mode, fixture installation part 251 can Using guide post structure, clamp arm mounting base 252 is then using the movable block structure for being socketed on guide post structure.Specifically, as folder The guide post structure of tool installation part 251 includes erectting setting and two parallel guide posts, as clamp arm mounting base 252 Two perforations corresponding with two guide posts in the guide post structure or two clips are then equipped in the activity block structure. According to perforation, the movable block is sheathed on the guide post and can realize and slides along the guide post.According to clip, institute Movable block is stated to be clipped on the guide post and can realize along guide post sliding, wherein in practical applications, the clip An at least half part for the guide post can be clipped on.

For the silicon rod clamper 25 of movable silicon rod clamping piece 253, different change case is also had.It is clamped with two silicon rods For part 253, in an alternative embodiment, a silicon rod clamping piece 253 in two silicon rod clamping pieces 253 is movable sets Counting another silicon rod clamping piece 253 then is fixed design, in this way, being all by the movable design of movement in practical applications That silicon rod clamping piece 253 adjust the clamping spacing between the silicon rod clamping piece 253 of fixed design.It can from above To know, silicon rod 100 is to erect to place, therefore, no matter the scale lengths of silicon rod, always the bottom of silicon rod 100 can be relatively easy to determine , it is thus preferable to, that silicon rod clamping piece 253 being located above in two silicon rod clamping pieces 253 can be designed as activity Formula, in this way, need to only adjust the position of the silicon rod clamping piece 253 of top.It is described for the movement for realizing silicon rod clamping piece 253 The silicon rod clamping piece 253 of movable design can be equipped with guiding driving mechanism.Movable design can be driven using guiding driving mechanism Silicon rod clamping piece 253 along fixture installation part 251 move up and down.

In one implementation, guiding driving mechanism can for example, guiding leading screw 258 and guide motor 259, In, guiding leading screw 258 is to erect setting, and one end of guiding leading screw 258 is connected to clamp arm mounting base 252, guiding leading screw 258 it is another One end is then connected to guide motor 259, and guide motor 259 may be provided at the top of commutation carrier 23, but be not limited thereto, and leads It may also be arranged on the bottom of commutation carrier 23 to motor 259.Guiding leading screw 258 has high-precision, invertibity and efficient spy Point, in this way, driving guiding leading screw 258 to revolve by guide motor 259 when needing the position of the silicon rod clamping piece 253 above adjustment Turn, drives silicon rod clamping piece 253 to move up and down along fixture installation part 251 in 258 rotary course of guiding leading screw, such as: guiding Motor 259 drives guiding leading screw 258 to rotate in the forward direction, then drives the silicon rod clamping piece 253 of top upward along fixture installation part 251 Movement is with the silicon rod clamping piece 253 far from lower section；Guide motor 259 drives 258 counter-rotating of guiding leading screw, then drives top Silicon rod clamping piece 253 is moved downward along fixture installation part 251 close to the silicon rod clamping piece 253 of lower section.Adjust two silicon rods Clamping spacing between clamping piece 253, so that the silicon rod 100 to different size length is effectively clamped.

In another alternative embodiment, two silicon rod clamping pieces 253 are movable design, in this way, in practical application In, mutual clamping spacing can be adjusted by the movement of two silicon rod clamping pieces 253 of movable design.Due to silicon rod Clamping piece 253 is movable design, then, at least one silicon rod clamping piece 253 in two silicon rod clamping pieces 253, which need to be arranged, leads To driving mechanism, for driving two silicon rod clamping pieces 253 to move along fixture installation part 251.

Relative to a kind of this preceding alternative embodiment, in this alternative embodiment, since two silicon rods in silicon rod clamper 25 Clamping piece 253 is movable, then will exist on some silicon rod clamping piece 253 in two silicon rod clamping pieces 253 The situation that guiding driving mechanism is still respectively provided with guiding driving mechanism on two silicon rod clamping pieces 253 is set.Now at two The silicon rod clamping piece 253 of top is provided with for guiding driving mechanism in silicon rod clamping piece 253, in this case, one, two It is to be flexibly connected between clamp arm mounting base 252 and fixture installation part 251 in a silicon rod clamping piece 253, that is, any one silicon rod folder Clamp arm mounting base 252 and clamp arm 254 thereon are up and down along fixture installation part 251 in gripping member 253, in addition, setting Guiding driving mechanism includes guiding leading screw 258 and guide motor, wherein one end of guiding leading screw 258 is connected to the silicon rod of top In clamp arm mounting base 252 in clamping piece 253, the other end of guiding leading screw 258 is then connected to guide motor 259, guide motor 259 may be provided at the top of commutation carrier 23, in this way, when the position of the silicon rod clamping piece 253 above needing to adjust, by being oriented to Motor 259 drives guiding leading screw 258 to rotate, and drives silicon rod clamping piece 253 to install along fixture in 258 rotary course of guiding leading screw Part 251 moves up and down, such as: guide motor 259 drives guiding leading screw 258 to rotate in the forward direction, then drives the silicon rod clamping piece of top 253 move upwards along fixture installation part 251 with the silicon rod clamping piece 253 far from lower section；Guide motor 259 drives guiding leading screw 258 counter-rotatings then drive the silicon rod clamping piece 253 of top to move downward along fixture installation part 251 close to the silicon of lower section Stick clamping piece 253.The silicon rod clamping piece 253 moves up and down along fixture installation part 251 and then adjusts two silicon rod clamping pieces Clamping spacing between 253, so that the silicon rod 100 to different size length is effectively clamped.

In fact, in the case of two silicon rod clamping pieces 253 are movable design, not only using guiding driving mechanism Clamping spacing between adjustable two silicon rod clamping pieces 253 is effectively clamped it come the silicon rod 100 to different size length Outside, the purpose that lifting can be also realized to the silicon rod 100 of clamping is led to after two silicon rod clamping pieces 253 effectively clamp silicon rod Overdrive silicon rod clamping piece 253 movement and go up and down silicon rod 100.Specifically, it is still provided with and is led with the silicon rod clamping piece 253 of top To for driving mechanism, firstly, the silicon rod clamping piece 253 of top is by guiding driving mechanism along about 251 fixture installation part It moves and has adjusted the clamping spacing between lower section silicon rod clamping piece 253；Then, using in each silicon rod clamping piece 253 Clamp arm driving mechanism drive corresponding two clamp arm to make clamping movement with smooth and be held fixedly silicon rod；Then, top Silicon rod clamping piece 253 driven by guiding driving mechanism move upwards along fixture installation part 251 again, at this point, due to rubbing Power effect is wiped, the silicon rod clamping piece 253 of the silicon rod 100 and lower section that clamp moves upwards therewith together, wherein the silicon clamped Stick 100 move upwards utilize be top silicon rod clamping piece 253 and silicon rod 100 between frictional force effect, silicon rod clamping piece 253 move upwards, and what is utilized is the frictional force effect between silicon rod 100 and the silicon rod clamping piece 253 of lower section.The silicon rod of top It is also phase that clamping piece 253 drives silicon rod 100 and the silicon rod clamping piece 253 of lower section to move downward under the driving of guiding driving mechanism Same process, details are not described herein.

It should be noted that in other change case, the silicon rod clamping piece of lower section e.g. in two silicon rod clamping pieces 253 Guiding driving mechanism, structure, set-up mode and driving working method and the aforementioned top of guiding driving mechanism are set on 253 The guiding driving mechanism of silicon rod clamping piece 253 is similar, for example, by lower section silicon rod clamping piece 253 guiding driving mechanism drive It moves up and down under dynamic along fixture installation part 251 and adjusts the clamping spacing between top silicon rod clamping piece 253, and under The silicon rod clamping piece 253 of side drives silicon rod 100 and the silicon rod clamping piece 253 of top edge together under the driving of guiding driving mechanism Fixture installation part 251 move up and down etc. modes.For example two silicon rod clamping pieces 253 are provided with guiding driving mechanism again, then The set-up mode and driving working method of guiding driving mechanism and the motion mode of two silicon rod clamping pieces 253 are self-evident, Details are not described herein.

It is long to adapt to different size moving up and down for movable silicon rod clamping piece 253 along fixture installation part 251 In the situation that the silicon rod of degree is clamped, in addition to silicon rod clamping piece 253 is using movable structure design, silicon rod clamping piece 253 It need to be arranged except guiding driving mechanism etc., certainly will also need to know the scale lengths for the silicon rod for currently needing to clamp.In view of this, Silicon rod handler in the application may also include height testing instrument 7, put for detecting the setting that silicon rod plummer 21 is carried The height for the silicon rod set, to be moved up subsequent along silicon rod clamper installation part 251 as movable silicon rod clamping piece 253 Or it moves down and the foundation of moving distance.

It loads when silicon rod to be processed is loaded and unloaded position by silicon rod using the silicon rod clamper 25 in silicon rod handler 2 to silicon The pretreatment position of stick processing platform 11 is for subsequent processing operation, in one embodiment, such as 3 He of the first processing unit (plant) Second processing unit (plant) 4 carries out the first processing operation and the second processing operation to silicon rod 100 respectively, in following process operation at least It include corresponding silicon rod surface Shape correction.Therefore, it before carrying out subsequent processing operation to silicon rod, certainly will need to know The current flatness situation of silicon rod 100.In view of this, the application silicon rod Multi-position processing machine may also include flatness detector, At least for carrying out planar smoothness detection to silicon rod 100 to be processed.In one embodiment, flatness detector is set to and changes It to the second mounting surface of carrier 23, specifically includes: contact measurement structure, detector shift mechanism and detection controller.

Contact measurement structure in flatness detector is used for the tested surface by contacting silicon rod to implement tested surface Flatness detection.In general, the flatness that contact measurement structure implements tested surface by contacting the tested surface of silicon rod is examined Survey specifically refers to: each test point of the tested surface of silicon rod is sequentially contacted by contact measurement structure with detect to obtain correspond to it is each The relative distance value of test point determines the flatness of the tested surface according to these relative distance values.

In the present embodiment, determine that the flatness of the tested surface is then logical according to the relative distance value of each test point It crosses the difference in these relative distance values that will be measured between maxima and minima to determine, if the difference is less than mark Quasi- value is fallen into critical field, then shows that the flatness of the tested surface meets specification.In specific implementation, contact measurement Structure 61 is more can include: telescopic contact probe head and on-off switch.

Telescopic contact probe head is used to contact the tested surface of silicon rod 100.On-off switch is then associated with telescopic contact probe head And connect with detection controller, for touching the tested surface of silicon rod 100 in telescopic contact probe head one i.e. to detection controller Corresponding on-off signal is sent, so that detection controller converses the tested surface that telescopic contact probe head is currently touched accordingly In relative distance of the test point relative to datum mark.

In an alternative embodiment, the telescopic contact probe head in contact measurement structure is more can include: contact is visited Head, is at least partly built in probe base and the bullet for shoring contact probe at the probe base for contact probe is arranged Property supporting element.Contact probe may be, for example, the club in cylindrical body, and the top of the club can be made at tipping and sphering Reason or additional salient point, in practical applications, high rigidity can be used in contact probe, the hard alloy of high abrasion is made Make.Probe base may be, for example, cylinder table, and the cylinder table is hollow structure, for accommodating the contact probe for being in club. When probe base is after accommodating contact probe, the top of contact probe protrudes from probe base.In elastic supporting member for supporting optical member It is placed in probe base and for shoring contact probe, and, elastic supporting member for supporting optical member is also associated with on-off switch.Elastic supporting member for supporting optical member top Support contact probe is mainly reflected in the conduction of power, and herein, the conduction of power is at least embodied in two following aspects: one, connecing What receipts contact probe was subject to by contact measured face compresses power and supports pressure conduction by described in on-off switch, so that on-off is opened Pass compresses power according to and generates corresponding on-off signal.Two, restorable restoring force is provided to contact probe, received Relative probe pedestal inside contracts contact probe due to contact measured face, according to the effect of power and to connecing after elastic supporting member for supporting optical member stress Touch probe provides restorable restoring force so that contact probe according to the restoring force and relative probe pedestal towards outward transport It moves to restore.In practical applications, such as compression spring can be used in elastic supporting member for supporting optical member, and the opposite end of compression spring can divide It Dui Yingyu not contact probe and on-off switch.But, the knot of the building block of contact measurement structure and each building block Structure is not limited in aforementioned embodiments,

In other embodiments, contact measurement structure can still make other variations, such as: contact probe may be, for example, In tetrahedral club, and, probe base also may be, for example, tetrahedral tubulose platform.Pliability can also be used in elastic supporting member for supporting optical member The opposite end of elastic slice, flexible elastic slice can correspond respectively to contact probe and on-off switch.On-off switch is that high-precision is opened It closes, sensitivity with higher, even very subtle active force can perceive to obtain.In addition, the alternative embodiment its In his implementation, it may also include signal transmission device part or signal circuit between on-off switch and detection controller, in this way, On-off signal caused by on-off switch can be transmitted to detection controller by signal transmission device part or signal circuit.

Contact measurement structure in the present embodiment in practical applications, when telescopic contact probe head touches silicon rod 100 Tested surface when, just relative probe pedestal inside contracts telescopic contact probe head under the blocking of the tested surface of silicon rod 100, elasticity branch Support member receives compressing power and described supporting pressure conduction to on-off switch for contact probe and shoring contact probe, with Power is compressed according to for on-off switch and generates corresponding Continuity signal or cut-off signal, the Continuity signal or cut-off signal Detection controller is transmitted to by signal transmission device part or signal circuit, detection controller is according to the Continuity signal or breaks ON signal can converse the test point in the tested surface that contact probe is currently touched relative to datum mark it is opposite away from From.

Detector shift mechanism in flatness detector is for driving contact measurement structure 61 to shift.In the present embodiment In, detector shift mechanism may be, for example, three-dimensional displacement mechanism, in specific implementation, the three-dimensional displacement mechanism can include: the One direction shift mechanism, second direction shift mechanism and third direction shift mechanism, for ease of description, by the first party To X-axis is denoted as, the second direction is denoted as Y-axis, the third direction is denoted as Z axis.In conjunction with Fig. 1 it is found that second Direction Y-axis be it is consistent with the translation direction of translation mechanism in aforementioned silicon rod handler, therefore, in a kind of optional embodiment In, second direction shift mechanism can coincide with translation mechanism above-mentioned, that is, second direction shift mechanism is just by translation above-mentioned Mechanism is held a concurrent post, and the structure and its function mode of the translation mechanism can be found in preceding description, therefore for second direction moving machine Structure repeats no more.

It is described in detail emphatically below for first direction shift mechanism and third direction shift mechanism.

The first direction shift mechanism further includes: sidesway pedestal 243 and first direction shift unit pass through first direction Shift unit can provide displacement of the sidesway pedestal 243 in a first direction in (such as X-direction).First direction shift unit is into one Step includes: first direction rack rails, is laid on bottom installation structure along first direction；First rotate gear is set to sidesway bottom It is meshed on seat 243 and with first direction rack rails；First driving motor, for driving the first rotate gear to be rotated such that sidesway Pedestal 243 along a first direction retreat by rack rails.Specifically, first direction rack rails may be, for example, at least one with certain length Rack gear, this at least one rack gear are installed on bottom installation structure.To make sidesway pedestal 243 more stablely along a first direction It is mobile, it can configure at least two first rotate gears, the setting of at least two first rotate gear intervals for each rack gear.The One rotate gear can be sequentially connected by transmission shaft and the first driving motor, the first driving motor with detect controller connect and by Detect controller control.First driving motor may be, for example, servo motor.In practical applications, as previously mentioned, first direction moves Bit location includes first direction rack rails, the first rotate gear and the first driving motor, and the first driving motor, which receives, carrys out self-test control The shift control of device processed instructs, and is instructed according to the shift control to drive the first rotate gear to be rotated such that sidesway pedestal 243 requirements of the rack rails displacement up to meeting displacement numerical value along a first direction, realize the purpose precisely shifted.The shift control Displacement numerical value or parameter relevant to displacement numerical value are included at least in instruction.

In addition, above-mentioned first direction shift unit be only one illustrate, but be not intended to limit the application, for example, In one alternative embodiment, first direction shift unit can include: lead screw and servo motor, lead screw have high-precision, invertibity and Efficient feature improves the horizontal line in a first direction of sidesway pedestal 243 in this way, passing through the cooperation of servo motor and lead screw Into precision.In addition, first direction shift unit may also include first direction guide rail and the first sliding block, wherein first direction Guide rail is laid on bottom installation structure along first direction, the first sliding block be then set to sidesway pedestal 243 and with first party guide Rail matches, and by the cooperation of first direction guide rail and the first sliding block, sidesway pedestal 243 is assisted to shift along a first direction.

In practical applications, the first driving motor receives shift control instruction (the displacement control for carrying out self-test controller Included at least in system instruction displacement numerical value or to the relevant parameter of displacement numerical value) and instructed according to the shift control and to drive the One rotate gear is rotated such that rack rails shifts sidesway pedestal 243 along a first direction, at least wraps in the shift control instruction Include displacement numerical value or to the relevant parameter of displacement numerical value, meanwhile, as the first direction guide rail and the first sliding block of auxiliary equipment, the Guide rail slides one sliding block along a first direction, to realize that sidesway pedestal 243 shifts along a first direction.

Ground is changed, in other embodiments, first direction shift unit may also include first direction guide rail and first and slide Seat, wherein first direction guide rail is laid in sidesway pedestal 243 along first direction, and first slide is installed on bottom installation structure, By the cooperation of first direction guide rail and first slide, sidesway pedestal 243 is assisted to shift along a first direction.As previously mentioned, flat Whole degree detector is for carrying out surface smoothness detection to silicon rod, and therefore, under general scenario, flatness detector can be with other What process equipment was used cooperatively, this kind of process equipments can be simple function process equipment, and (such as cutting processing machine, flour milling add Work machine or polishing machine) it is also possible to the combined-machining equipment of multiple function, the simple function process equipment may be, for example, Such as cutting processing machine, flour milling processing machine or polishing machine, the combined-machining equipment may be, for example, flour milling polishing one Machine.

Since in one embodiment, second direction shift mechanism is held a concurrent post by translation mechanism above-mentioned, therefore, is With the cooperation of first direction translation mechanism, in the structure of the translation mechanism, conversion chassis 241 is set up in by translation mechanism It is substantially exactly the sidesway bottom converted chassis 241 and be set up in first direction shift mechanism by translation mechanism on bottom installation structure On seat, illustrate herein.

The third direction shift mechanism can provide contact measurement structure 61 with respect to commutation carrier 23 and in third direction (such as Z-direction for the displacement on third direction, can also be colloquially called displacement up and down below herein) moves up Position.In one embodiment, contact measurement structure 61 is that commutation carrier 23 is set to by a detection structure installation part 63 On.Guide post structure can be used in detection structure installation part 63, and contact measurement structure then uses and is socketed on guide post structure Movable block structure.It specifically, include erectting two be arranged and parallel as the guide post structure of detection structure installation part 63 A guide post, and contact measurement structure 61 is then equipped with two perforations corresponding with two guide posts in the guide post structure Or two clips.

According to perforation, the contact measurement structure is sheathed on the guide post and can realize sliding along the guide post It moves.According to clip, the contact measurement structure is clipped on the guide post and can realize and slides along the guide post, In, the clip can be clipped on an at least half part for the guide post.It therefore, is realization 61 edge of contact measurement structure Detection structure installation part 63 and shift up and down, third direction shift mechanism can further comprise: lead screw and lifting motor, In, lead screw is to erect setting, and one end of lead screw is connected to contact measurement structure 61, and the other end of lead screw is then connected to lifting electricity Machine, lifting motor may be provided at the top of commutation carrier 23, but be not limited thereto, and lifting motor may also be arranged on commutation carrier 23 bottom.Lead screw has the characteristics that high-precision, invertibity and efficient, in this way, needing to adjust contact measurement structure 61 Position when, by lifting motor driving lead screw rotation, drive contact measurement structure 61 to tie along detection in screw rod rotary course Structure installation part 63 moves up and down, such as: driving motor driving lead screw rotates in the forward direction, then drives the contact measurement structure 61 of top It is moved upwards along detection structure installation part 63；Driving motor drives lead screw counter-rotating, then drives contact measurement structure 61 It is moved downward along detection structure installation part 63.

In practical applications, lifting motor receive come self-test controller issued include at least displacement numerical value or with The shift control instruction of the relevant parameter of displacement numerical value is simultaneously instructed according to the shift control to drive lead screw to rotate to drive and connect Touch detection structure 61 moves up and down along detection structure installation part 63 until satisfaction shifts the requirement of numerical value, realization precisely displacement Purpose.It should be noted that above-mentioned third direction shift mechanism is only a kind of example using the combination of lead screw and driving motor, and It is non-to be used to limit the application third direction shift mechanism, change ground, in other embodiments, the third direction shift mechanism Tooth band shift mechanism can also be used, in tooth band shift mechanism, it may include synchronous toothed belt, rotate gear and driving motor, In, synchronous toothed belt is set on the second mounting surface of commutation carrier 23, and contact measurement structure 61 can pass through connector and synchronous gear Band connection, rotate gear are then meshed with synchronous toothed belt, and driving motor is then used to that rotate gear to be driven to rotate to utilize synchronous gear Band drives contact measurement structure 61 to move up and down along detection structure installation part 63.

Detection controller is connect with contact measurement structure and detector shift mechanism, for controlling detector shift mechanism Contact measurement structural shift and control contact measurement structure is driven sequentially to detect in silicon rod each test point on tested surface Relative distance.In one embodiment, detector shift mechanism may include first direction shift mechanism, second direction shifting machine Structure and third direction shift mechanism, therefore, detection controller and first direction shift mechanism, second direction shift mechanism, with And third direction shift mechanism, it is used for first direction shift mechanism, second direction shift mechanism and third direction shifting machine Structure sends the instruction of corresponding shift control respectively, is reached with drive control contact measurement structure by three-dimensional displacement scheduled It detection position simultaneously can be in the test point in the tested surface that the inspection positions are able to contact silicon rod 100.Contact measurement structure Can include: telescopic contact probe head and on-off switch, wherein on-off switch is connect with detection controller, and on-off switch is flexible Formula contact probe head when touching the tested surface of silicon rod 100 to detection controller send on-off signal, detection controller according to The on-off signal converses the test point in the tested surface that contact probe is currently touched relative to the opposite of datum mark Distance.

In practical applications, the datum mark setting can according to the architectural characteristic or detection mode of flatness detector and It is fixed, first direction shift mechanism, second direction shift mechanism, Yi Ji in the architectural characteristic such as detector shift mechanism The structure of three direction shift mechanisms.It is with datum mark and using second party according to the relative distance that the datum mark converts Drive contact measurement structure along the translocation distance of second direction to shift mechanism) it is relevant.It is described along second direction Translocation distance is the initial position and contact measurement of contact measurement structure under second direction shift mechanism inactive state Structure touches the contact measurement structure under second direction shift mechanism halted state after the test point in side of silicon rod 100 The distance between contact position.Certainly, easily processing mode is: datum mark is directly disposed as second direction shift mechanism The initial position of contact measurement structure under inactive state, in this way, the test point in tested surface is relative to the opposite of datum mark Distance is to drive contact measurement structure along the translocation distance of second direction using second direction shift mechanism.

It should be noted that in one embodiment, flatness detector is set to the second mounting surface of commutation carrier 23, and preceding The silicon rod clamper stated then is set to the first mounting surface of commutation carrier 23, and herein, the first mounting surface and the second mounting surface can be according to realities Border apparatus structure and set.For example, the first mounting surface and the second mounting surface are two installations in commutation carrier 23 backwards to setting Face, further, the first mounting surface and the second mounting surface can differ 180 °, so that the silicon rod for being located at silicon rod handling position is held The rotation plummer 531 for being located at pretreatment position in microscope carrier 21 and silicon rod conversion equipment 5 connects being aligned, in this way, when the load that will commutate After 23 180 ° of rotation of tool, the first original mounting surface can be switched to the second mounting surface or the second original mounting surface is changeable For the first mounting surface, but not must so make excessive demands in practical application for the setting relationship of the first mounting surface or the second mounting surface, First mounting surface and the second mounting surface can also for example differ 90 °, that is, silicon rod plummer 21 and silicon rod positioned at silicon rod handling position The rotation plummer 531 for being located at pretreatment position in conversion equipment 5 is in 90 ° of phase differences, even, the first mounting surface and the second peace Dress face can differ any position in OK range, as long as loading and unloading between the first mounting surface and the second mounting surface or positioned at silicon rod Ensuring between the rotation plummer 531 of pretreatment position in the silicon rod plummer 21 and silicon rod conversion equipment 5 of position will not If generating unnecessary interference.In addition, aforementioned mentioned height testing instrument 7, both can be set in can also on the first mounting surface To be set on the second mounting surface, the other parts for the carrier 23 that even commutates.

Particularly, by the cooperation of flatness detector 7 and silicon rod clamper 25, can also correction operation be carried out to silicon rod 100. It is found that can be clamped silicon rod 100 using silicon rod clamper 25 and make commutation movement by commutation carrier 23 again in being described above On the rotation plummer 531 for the silicon rod positioning mechanism 53 that silicon rod 100 is transferred at pretreatment position afterwards.But thus and thus, may be used Following situation can be will appear: middle section of the rotation plummer 531 not at silicon rod 100.In which case, process is subsequent Silicon rod product after processing operation is likely to not meet specification of workpieces requirement.Therefore, following process work is being carried out to silicon rod Before industry, can also silicon rod 100 carry out correction operation, it is easily operated and be ideally exactly by silicon rod 100 in correction operation Center with rotation the center of plummer 531 it is corresponding coincidence.

In practical applications, plane is carried out by the silicon rod 100 carried on 7 pairs of rotation plummers 531 of flatness detector to put down Whole degree detection, to obtain the integral position overview of silicon rod 100；The integral position overview of the silicon rod 100 of acquisition is held with rotation The position of microscope carrier 531 is compared, and then obtains inclined between the center of silicon rod 100 and the center for rotating plummer 531 Poor information；The carrier 23 that commutates rotates 180 ° of work commutation movements, corresponds to rotation carrying by the silicon rod clamper 25 on commutation carrier 23 Silicon rod 100 on platform 531 simultaneously clamps silicon rod 100；Utilize the first direction shift mechanism and in aforementioned three-dimensional displacement mechanism Two direction shift mechanisms driving commutation carrier 23 is in a first direction and/or second party moves up, to drive silicon rod clamper 25 and the 100 relative rotation plummer 531 of silicon rod that is clamped by silicon rod clamper 25 make position adjustment, be finally able to silicon rod 100 Center is corresponding with the rotation center of plummer 531 to be overlapped, the correction operation for completing to be directed to silicon rod 100.

First processing unit (plant) 3 is set to the first processing position of silicon rod processing platform 11, adds for carrying out first to silicon rod 100 Work industry.Second processing unit (plant) 4 is set to the second processing position of silicon rod processing platform 11, is used for by the first processing unit (plant) 3 The first post-job silicon rod 100 of processing carry out the second processing operation.In the present embodiment, as previously mentioned, it is fixed by silicon rod Position mechanism 53 can be positioned silicon rod 100 to erect modes of emplacement, and therefore, the first 3 pairs of processing unit (plant) erects the silicon rod placed 100, which carry out the silicon rods 100 that the first processing operation and 4 pairs of the second processing unit (plant) settings are placed, carries out what the second processing operations used It is exactly vertical processing method.

Specifically, it is also had for the silicon rod of different kenels, the first processing unit (plant) 3 and the second processing unit (plant) 4 Example is combined in different variations.Such as: if silicon rod 100 is silicon single crystal rod, the first processing unit (plant) 3 can be the circle of contact and corase grinding device And the second processing unit (plant) 4 can be round as a ball and fine grinding device；If silicon rod 100 is polycrystalline silicon rod, the first processing unit (plant) 3 be can be Roughly grind device and the second processing unit (plant) can be chamfering and fine grinding device.Particularly, in one embodiment, in the pretreatment It can also be added between position and first processing position and between the second processing position and the pretreatment position anti- Door is protected, for the pretreatment position and the first processing position and second processing position to be isolated, to play The effect for protecting silicon rod, avoids silicon rod from being contaminated or damage.

Following elder generation is described in detail so that silicon rod 100 is silicon single crystal rod as an example.

In the case of silicon rod 100 is silicon single crystal rod, the first processing unit (plant) 3 is the circle of contact and corase grinding device, the second processing dress 4 are set as round as a ball and fine grinding device.

As the circle of contact and corase grinding device 3 of the first processing unit (plant), on base 1 and it is located at the first of silicon rod processing platform Position is processed, for carrying out the circle of contact and corase grinding operation to silicon single crystal rod.The circle of contact and corase grinding device 3 have first receiving space, use In receive by silicon rod conversion equipment 5 conveying ontology 51 conveying come silicon single crystal rod.The circle of contact and corase grinding device 3 mainly include First rack 31 and at least a pair of first grinding tool 33, at least a pair of first grinding tool 33 are arranged oppositely in the first rack 31, are used for The circle of contact and corase grinding operation are carried out to the silicon single crystal rod on the silicon rod conversion equipment 5 being located at the first processing position.Further, Each first grinding tool 33 further includes the first main shaft 32 and the first grinding wheel 34, wherein the peace of the first main shaft 32 and the first rack 31 Dress face is equipped with and slides laterally guide mechanism and longitudinal sliding motion guide mechanism, and such as sliding rail can be used in the guide mechanism that slides laterally With the combination of sliding block etc., the longitudinal sliding motion guide mechanism be can be used such as the combination of sliding rail and sliding block.Using sliding laterally Guide mechanism can enable the first main shaft 32 or the first grinding wheel 34 the first rack 31 can make laterally advancing and retreating movement relatively.Utilize longitudinal direction Guide mechanism is slided, opposite first rack 31 of 32 energy of the first main shaft can be enabled longitudinally to move up and down.

In a practical application, at least a pair of first grinding tool 33 is set on a grinding tool pedestal, the grinding tool pedestal and lead to Cross longitudinal sliding motion guide mechanism and can longitudinal sliding motion be connected to the first rack 31, at least a pair of first grinding tool 33 is by sliding laterally Guide mechanism and can slide laterally and be connected to the grinding tool pedestal, wherein the grinding tool pedestal is controlled by a lifting motor and indulges To sliding guide mechanism longitudinal sliding motion in the first rack 31, each of at least a pair of first grinding tool 33 first grinding tool 33 is independent It is controlled by an advance and retreat motor and slides laterally in the grinding tool pedestal.First grinding wheel 34 is set to the operation end of the first main shaft 32, The first frosted particle with the first granularity.Herein, silicon single crystal rod to be processed is the silicon cube that section is substantially in class rectangle, Tool is formed with the connection faceted pebble in the angle R there are four side between two neighboring side.Therefore, the circle of contact and corase grinding device 3 in one It is to be oppositely arranged to the first grinding tool 33, there are the first receiving spaces for accommodating silicon single crystal rod between the two, when silicon single crystal rod is defeated It is opposite in the i.e. accessible silicon single crystal rod of the first grinding wheel 34 after sending between the first grinding wheel of a pair 34 into the first receiving space A pair of of side or a pair of of connection faceted pebble carry out corresponding processing operation.

In practical applications, add first with first that silicon single crystal rod is transferred to silicon rod processing platform by silicon rod conversion equipment 5 Work area position, carries out positioning adjustment to silicon single crystal rod by silicon rod positioning mechanism 53, so that a pair of of connecting edge in silicon single crystal rod faces The circle of contact should be carried out by connection faceted pebble of first grinding tool 33 to silicon single crystal rod and process operation in a pair of first grinding tool 33.The circle of contact Processing operation can for example, carries out positioning adjustment to silicon single crystal rod with silicon rod positioning mechanism 53 and matches, according to the amount of feeding, rotation Turn the first grinding wheel 34 in the first grinding tool 33 and the first grinding tool 33 is driven to move up and down to implement to grind, to first pair of connection faceted pebble And its adjacent domain repeatedly slightly cut and is repeatedly slightly cut to second pair of connection faceted pebble and its adjacent domain progress, so that each Connection between connection faceted pebble and adjacent side forms preliminary arc and connects.Again by silicon rod positioning mechanism 53 to silicon single crystal rod into Row positioning adjustment, so that a pair of of side in silicon single crystal rod corresponds to a pair of first grinding tool 33, by the first grinding tool 33 to monocrystalline silicon The side of stick carries out corase grinding processing operation.

Corase grinding operation may be, for example: positioning adjustment be carried out to silicon single crystal rod by silicon rod positioning mechanism 53, so that silicon single crystal rod The first opposite side face correspond to a pair of first grinding tool 33, by the first grinding wheel 34 in a pair of first grinding tool 33 to the of silicon single crystal rod A pair of of side carries out corase grinding processing operation；Then, positioning adjustment is carried out to silicon single crystal rod by silicon rod positioning mechanism 53, so that monocrystalline Second opposite side face of silicon rod corresponds to a pair of first grinding tool 33, by the first grinding wheel 34 in a pair of first grinding tool 33 to silicon single crystal rod Second pair of side carry out corase grinding processing operation.Wherein, the corase grinding processing operation of any pair of side can for example, provide one into To amount, the first grinding wheel 34 in a pair of first grinding tool 33 is driven to be moved from top to bottom to grind a pair of of side of silicon single crystal rod；One First grinding wheel 34 is ground to after silicon single crystal rod bottom and passes through silicon single crystal rod and stays in lower limit later, is further added by a feeding Amount drives a pair of first grinding wheel 34 to be moved from the bottom up to grind silicon single crystal rod；A pair of first grinding wheel 34 is ground to silicon single crystal rod After top and pass through and stay in upper limit after silicon single crystal rod, continue growing an amount of feeding, drive a pair of first grinding wheel 34 from On down movement to grind silicon single crystal rod；In this way, grinding, increases the amount of feeding, and it is reversed to grind, increase the amount of feeding, is repeated several times it Afterwards, a pair of of side of silicon single crystal rod can be ground to preset size.

As the round as a ball and fine grinding device of the second processing unit (plant), on base 1 and it is located at the second of silicon rod processing platform Position is processed, it is round as a ball and smart for being carried out to the silicon single crystal rod after the circle of contact and corase grinding 3 circle of contact of device and corase grinding processing operation Mill processing operation.Round as a ball and fine grinding device 4 has the second accommodation space, for receiving the conveying passed through in silicon rod conversion equipment 5 The silicon single crystal rod that the conveying of ontology 51 comes.Round as a ball and fine grinding device 4 mainly includes the second rack 41 and at least the second grinding tool 43 of a pair, At least a pair of second grinding tool 43 is arranged oppositely in the second rack 41, for the silicon rod converting means being located at the second processing position The silicon single crystal rod set on 5 carries out round as a ball and fine grinding operation.

Further, each second grinding tool 43 further includes the second main shaft 42 and the second grinding wheel 44, wherein the second main shaft 42 and second rack 41 mounting surface be equipped with slide laterally guide mechanism and longitudinal sliding motion guide mechanism, it is described to slide laterally guiding Mechanism can be used such as the combination of sliding rail and sliding block, and the group of such as sliding rail and sliding block can be used in the longitudinal sliding motion guide mechanism Close etc..Using guide mechanism is slid laterally, the second main shaft 42 or the second grinding wheel 44 can be enabled the second rack 41 to make laterally relatively Advancing and retreating movement can enable opposite second rack 41 of 42 energy of the second main shaft longitudinally move up and down using longitudinal sliding motion guide mechanism.

In a practical application, at least a pair of second grinding tool 43 is set on a grinding tool pedestal, the grinding tool pedestal and lead to Cross longitudinal sliding motion guide mechanism and can longitudinal sliding motion be connected to the second rack 41, at least a pair of second grinding tool 43 is by sliding laterally Guide mechanism and can slide laterally and be connected to the grinding tool pedestal, wherein the grinding tool pedestal is controlled by a lifting motor and indulges To sliding guide mechanism longitudinal sliding motion in the second rack 41, each of at least a pair of second grinding tool 43 second grinding tool 43 is independent It is controlled by an advance and retreat motor and slides laterally in the grinding tool pedestal.Second grinding wheel 44 is set to the operation end of the second main shaft 42, The second frosted particle with the second granularity.In contrast, the granularity of the second frosted particle in the second grinding wheel 44 is to want small The granularity of the first frosted particle in the circle of contact and corase grinding device 3 in first grinding wheel 34.Therefore, in round as a ball and fine grinding device 4 The second grinding tool of a pair 43 be oppositely arranged, between the two there are for accommodate silicon single crystal rod the second accommodation space, work as silicon single crystal rod After being transported between the second grinding wheel of a pair 44 in second accommodation space, the i.e. accessible silicon single crystal rod of the second grinding wheel 44 into The corresponding processing operation of row.

In practical applications, add first with second that silicon single crystal rod is transferred to silicon rod processing platform by silicon rod conversion equipment 5 Work area position, is positioned to silicon single crystal rod by silicon rod positioning mechanism 53 and is rotated silicon single crystal rod, by the second grinding tool 43 to monocrystalline silicon The connection faceted pebble of stick carries out round as a ball processing operation.

The round as a ball processing operation can for example, silicon single crystal rod positioned by silicon rod positioning mechanism 53, so that the The second grinding wheel of a pair 44 in two grinding tools 43 is right against the side of silicon single crystal rod, and the spacing between a pair of second grinding wheel 44 is to want small In the current diagonal pitch of silicon single crystal rod, the gap of the two spacing is the amount of feeding of this at least a pair of second grinding wheel 44；It is single Crystalline silicon rod drives rotation by silicon rod positioning mechanism 53 in second accommodation space, and a pair of second grinding wheel 44 will be in the rotation Corresponding a pair of of the connection faceted pebble of a pair of of chamfering in silicon single crystal rod section be ground to arc-shaped, wherein silicon single crystal rod is by second Revolving speed is slower when the contact grinding of grinding wheel 44, and silicon single crystal rod passes through the second grinding wheel 44 after it connects faceted pebble by the grinding of the second grinding wheel 44 Revolving speed is very fast afterwards, also, silicon single crystal rod continues to rotate and makes the corresponding another pair connecting edge face contact of its another pair chamfering Two grinding wheels 44 are simultaneously ground into arc-shaped by the second grinding wheel 44；A pair of second grinding wheel 44 continues downwards, such as abovementioned steps, to monocrystalline Each connection faceted pebble of next section of silicon rod grind it is round as a ball, until grind the round as a ball bottom to silicon single crystal rod, completion monocrystalline The single connection faceted pebble grinding of silicon rod is round as a ball；An amount of feeding is continued growing, a pair of second grinding wheel 44 is driven to move from the bottom up, by Each connection faceted pebble of second grinding wheel 44 grinding silicon single crystal rod；In this way, grinding, increases the amount of feeding, and it is reversed to grind, increase feeding Amount, after being repeated several times, can be ground to preset size and whole rounding for the connection faceted pebble of silicon single crystal rod, that is, connecting edge Face and side rounding off.Positioning adjustment is carried out to silicon single crystal rod by silicon rod positioning mechanism 53 again, so that one in silicon single crystal rod Opposite side face corresponds to a pair of second grinding tool 43, carries out fine grinding operation by side of second grinding tool 43 to silicon single crystal rod.

Fine grinding operation may be, for example: positioning adjustment be carried out to silicon single crystal rod by silicon rod positioning mechanism 53, so that monocrystalline First opposite side face of silicon rod corresponds to a pair of second grinding tool 43, by the second grinding wheel 44 in a pair of second grinding tool 43 to silicon single crystal rod First pair of side carry out fine grinding operation；Then, positioning adjustment is carried out to silicon single crystal rod by silicon rod positioning mechanism 53, so that Second opposite side face of silicon single crystal rod corresponds to a pair of second grinding tool 43, by the second grinding wheel 44 in a pair of second grinding tool 43 to monocrystalline Second pair of side of silicon rod carries out fine grinding operation.Wherein, the fine grinding operation of any pair of side can for example, provides One amount of feeding drives the second grinding wheel 44 in a pair of second grinding tool 43 to be moved from top to bottom to grind an opposite side of silicon single crystal rod Face；A pair of second grinding wheel 44, which is ground to after silicon single crystal rod bottom and passes through silicon single crystal rod, stays in lower limit later, is further added by One amount of feeding drives a pair of second grinding wheel 44 to be moved from the bottom up to grind silicon single crystal rod；A pair of second grinding wheel 44 is ground to list Upper limit is stayed in after at the top of crystalline silicon rod and after silicon single crystal rod, continues growing an amount of feeding, drives a pair of second sand The movement from top to bottom of wheel 44 is to grind silicon single crystal rod；In this way, grinding, increases the amount of feeding, and it is reversed to grind, increase the amount of feeding, repeatedly After for several times, a pair of of side of silicon single crystal rod can be ground to preset size.

As seen from the above description, in an alternative embodiment, right as the round as a ball and fine grinding device 4 of the second processing unit (plant) The grinding process of trailing flank grinding is ground in the round as a ball and fine grinding operation that silicon single crystal rod carries out using first connection faceted pebble, but It is not limited thereto, in other change embodiments, round as a ball and fine grinding that round as a ball and fine grinding device 4 carries out silicon single crystal rod The grinding process of connection faceted pebble grinding after first side grinding can also be used in operation, answers technical effect having the same.

It is described in detail so that silicon rod 100 is polycrystalline silicon rod as an example again below.

In the case of silicon rod 100 is polycrystalline silicon rod, the first processing unit (plant) 3 is corase grinding device, and the second processing unit (plant) 4 is to fall Angle and fine grinding device.

The first processing district as the corase grinding device 3 of the first processing unit (plant), on base 1 and positioned at silicon rod processing platform Position, for carrying out corase grinding operation to polycrystalline silicon rod.Roughly grinding device 3 has first receiving space, is converted for receiving by silicon rod The polycrystalline silicon rod that the conveying conveying of ontology 51 in device 5 comes.Roughly grinding device 3 mainly includes the first rack 31 and at least a pair of first Grinding tool 33, at least a pair of first grinding tool 33 is arranged oppositely in the first rack 31, for the silicon being located at the first processing position Polycrystalline silicon rod on stick conversion equipment 5 carries out corase grinding operation.Further, each first grinding tool 33 further includes the first main shaft 32 and first grinding wheel 34, wherein the first main shaft 32 and the mounting surface of the first rack 31 are equipped with and slide laterally guide mechanism and longitudinal direction Guide mechanism is slided, the guide mechanism that slides laterally can be used such as the combination of sliding rail and sliding block, and the longitudinal sliding motion is led Drawing mechanism can be used such as the combination of sliding rail and sliding block.Using guide mechanism is slid laterally, the first main shaft 32 or the first can be enabled Grinding wheel 34 can opposite first rack 31 make laterally advancing and retreating movement and using longitudinal sliding motion guide mechanism can enable 32 energy of the first main shaft Opposite first rack 31 longitudinally moves up and down.

In a practical application, at least a pair of first grinding tool 33 is set on a grinding tool pedestal, the grinding tool pedestal and lead to Cross longitudinal sliding motion guide mechanism and can longitudinal sliding motion be connected to the first rack 31, at least a pair of first grinding tool 33 is by sliding laterally Guide mechanism and can slide laterally and be connected to the grinding tool pedestal, wherein the grinding tool pedestal is controlled by a lifting motor and indulges To sliding guide mechanism longitudinal sliding motion in the first rack 31, each of at least a pair of first grinding tool 33 first grinding tool 33 is independent It is controlled by an advance and retreat motor and slides laterally in the grinding tool pedestal.First grinding wheel 34 is set to the operation end of the first main shaft 32, The first frosted particle with the first granularity.Herein, polycrystalline silicon rod to be processed is the silicon cube of rectangular in cross-section, has four A side and four corner angle.Therefore, roughly grinding the first grinding tool of a pair 33 in device 3 is to be oppositely arranged, and there are for accommodating between the two The first receiving space of polycrystalline silicon rod, when polycrystalline silicon rod be transported to the first grinding wheel of a pair 34 in the first receiving space it Between after, the first grinding wheel 34 is that a pair of of side opposite in accessible polycrystalline silicon rod or a pair of of corner angle carry out corresponding corase grinding processing and make Industry.

In practical applications, add first with first that polycrystalline silicon rod is transferred to silicon rod processing platform by silicon rod conversion equipment 5 Work area position, carries out positioning adjustment to polycrystalline silicon rod by silicon rod positioning mechanism 53, so that a pair of of side in polycrystalline silicon rod corresponds to A pair of first grinding tool 33 carries out corase grinding processing processing operation by side of first grinding tool 33 to polycrystalline silicon rod.

Corase grinding processing operation may be, for example: positioning adjustment be carried out to polycrystalline silicon rod by silicon rod positioning mechanism 53, so that polycrystalline First opposite side face of silicon rod corresponds to a pair of first grinding tool 33, by the first grinding wheel 34 in a pair of first grinding tool 33 to polycrystalline silicon rod First pair of side carry out corase grinding processing operation；Then, positioning adjustment is carried out to polycrystalline silicon rod by silicon rod positioning mechanism 53, so that Second opposite side face of polycrystalline silicon rod corresponds to a pair of first grinding tool 33, by the first grinding wheel 34 in a pair of first grinding tool 33 to polycrystalline Second pair of side of silicon rod carries out corase grinding processing operation, wherein the corase grinding processing operation of any pair of side can for example, provides One amount of feeding drives the first grinding wheel 34 in a pair of first grinding tool 33 to be moved from top to bottom to grind an opposite side of polycrystalline silicon rod Face；A pair of first grinding wheel 34, which is ground to after polycrystalline silicon rod bottom and passes through polycrystalline silicon rod, stays in lower limit later, is further added by One amount of feeding drives a pair of first grinding wheel 34 to be moved from the bottom up to grind polycrystalline silicon rod；A pair of first grinding wheel 34 is ground to more Upper limit is stayed in after at the top of crystalline silicon rod and after polycrystalline silicon rod, continues growing an amount of feeding, drives a pair of first sand The movement from top to bottom of wheel 34 is to grind polycrystalline silicon rod；In this way, grinding, increases the amount of feeding, and it is reversed to grind, increase the amount of feeding, repeatedly After for several times, a pair of of side of polycrystalline silicon rod can be ground to preset size.

As the chamfering and fine grinding device of the second processing unit (plant), on base 1 and it is located at the second of silicon rod processing platform Position is processed, for the polycrystalline silicon rod that processing is processed after operation to carry out chamfering and fine grinding is made to roughly grinding through corase grinding device 3 Industry.Chamfering and fine grinding device 4 have the second accommodation space, for receiving the conveying ontology 51 passed through in silicon rod conversion equipment 5 defeated The polycrystalline silicon rod sent.Chamfering and fine grinding device 4 mainly include the second rack 41 and at least a pair of second grinding tool 43, at least a pair Second grinding tool 43 is arranged oppositely in the second rack 41, for on the silicon rod conversion equipment 5 being located at the second processing position Polycrystalline silicon rod carries out chamfering and fine grinding operation.

Further, each second grinding tool 43 further includes the second main shaft 42 and the second grinding wheel 44, wherein the second main shaft 42 and second rack 41 mounting surface be equipped with slide laterally guide mechanism and longitudinal sliding motion guide mechanism, it is described to slide laterally guiding Mechanism can be used such as the combination of sliding rail and sliding block, and the group of such as sliding rail and sliding block can be used in the longitudinal sliding motion guide mechanism Close etc..Using guide mechanism is slid laterally, the second main shaft 42 or the second grinding wheel 44 can be enabled the second rack 41 to make laterally relatively Advancing and retreating movement can enable opposite second rack 41 of 42 energy of the second main shaft longitudinally move up and down using longitudinal sliding motion guide mechanism.

In a practical application, at least a pair of second grinding tool 43 is set on a grinding tool pedestal, the grinding tool pedestal and lead to Cross longitudinal sliding motion guide mechanism and can longitudinal sliding motion be connected to the second rack 41, at least a pair of second grinding tool 43 is by sliding laterally Guide mechanism and can slide laterally and be connected to the grinding tool pedestal, wherein the grinding tool pedestal is controlled by a lifting motor and indulges To sliding guide mechanism longitudinal sliding motion in the second rack 41, each of at least a pair of second grinding tool 43 second grinding tool 43 is independent It is controlled by an advance and retreat motor and slides laterally in the grinding tool pedestal.Second grinding wheel 44 is set to the operation end of the second main shaft 42, The second frosted particle with the second granularity, in contrast, the granularity of the second frosted particle in the second grinding wheel 44 is to want small The granularity of the first frosted particle in corase grinding device 3 in first grinding wheel 34.Therefore, a pair in chamfering and fine grinding device 4 Second grinding tool 43 is to be oppositely arranged, and there are the second accommodation spaces for accommodating polycrystalline silicon rod between the two, when polycrystalline silicon rod is conveyed To after between the second grinding wheel of a pair 44 in second accommodation space, the i.e. accessible polycrystalline silicon rod of the second grinding wheel 44 carries out corresponding Chamfer machining operation.

In practical applications, add first with second that polycrystalline silicon rod is transferred to silicon rod processing platform by silicon rod conversion equipment 5 Work area position is positioned to polycrystalline silicon rod by silicon rod positioning mechanism 53 and is rotated the corner angle correspondence that polycrystalline silicon rod makes polycrystalline silicon rod The second grinding wheel 44 in a pair of second grinding tool 43 carries out chamfer machining operation to polycrystalline silicon rod by the second grinding tool 43.

Chamfer machining operation can for example, in chamfering, rotate by a certain angle first with silicon rod positioning mechanism 53 so that First pair of corner angle of polycrystalline silicon rod are obtained corresponding to the second grinding wheel 44 in a pair of second grinding tool 43；A pair of second grinding wheel 44 drops to Grinding position, at this point, the spacing between a pair of second grinding wheel 44 is to be less than current diagonal of first pair of corner angle in polycrystalline silicon rod Spacing, the gap of the two spacing are the amount of feeding of this pair of second grinding wheel 44, and a pair of second grinding wheel 44 is moved down to silicon First pair of corner angle in stick 100 are ground to form fillet surface；A pair of second grinding wheel 44 continues downwards, such as abovementioned steps, Next section of first pair of corner angle of silicon rod 100 are ground, until being ground to the bottom of silicon rod 100, complete the list of silicon rod 100 Secondary corner angle grinding；An amount of feeding is continued growing, the second grinding tool 43 of driving moves from the bottom up, is ground silicon rod by the second grinding wheel 44 100 first pair of corner angle；It is reversed to be ground in this way, grinding, increases the amount of feeding, increase the amount of feeding, it, can will after being repeated several times First pair of corner angle of silicon rod 100 are ground to preset size to form first pair of fillet surface.Chamfering is carried out to second pair of corner angle again And fine grinding: in chamfering, rotate by a certain angle first with silicon rod positioning mechanism 53 so that polycrystalline silicon rod second pair of corner angle pair It should be in the second grinding wheel 44 in a pair of second grinding tool 43；A pair of second grinding wheel 44 drops to grinding position, at this point, a pair of second sand Spacing between wheel 44 is to be less than the diagonal pitch that second pair of corner angle is current in silicon rod 100, and the gap of the two spacing is The amount of feeding of this pair of second grinding wheel 44, a pair of second grinding wheel 44, which moves down, grinds second pair of corner angle in silicon rod 100 It cuts to form fillet surface；A pair of second grinding wheel 44 continues downwards, such as abovementioned steps, to second pair of next section of silicon rod 100 Corner angle are ground, until being ground to the bottom of silicon rod 100, complete the single corner angle grinding of silicon rod 100；Continue growing a feeding Amount, the second grinding tool 43 of driving move from the bottom up, by second pair of corner angle of the second grinding wheel 44 grinding silicon rod 100；In this way, grinding, Increase the amount of feeding, it is reversed to be ground, increase the amount of feeding, after being repeated several times, second pair of corner angle of silicon rod 100 can be ground to pre- If size to form second pair of fillet surface.

Then, it recycles silicon rod positioning mechanism 53 to be positioned to polycrystalline silicon rod and rotate polycrystalline silicon rod and makes polycrystalline silicon rod Side correspond to the second grinding wheel 44 in a pair of second grinding tool 43, fine grinding work is carried out to polycrystalline silicon rod by the second grinding tool 43 Industry.Fine grinding operation can for example, positioning adjustment is carried out to polycrystalline silicon rod by silicon rod positioning mechanism 53, so that polycrystalline silicon rod The first opposite side face correspond to a pair of second grinding tool 43, by the second grinding wheel 44 in a pair of second grinding tool 43 to the of polycrystalline silicon rod A pair of of side carries out fine grinding operation；Then, positioning adjustment is carried out to polycrystalline silicon rod by silicon rod positioning mechanism 53, so that polycrystalline Second opposite side face of silicon rod corresponds to a pair of second grinding tool 43, by the second grinding wheel 44 in a pair of second grinding tool 43 to polycrystalline silicon rod Second pair of side carry out fine grinding operation, wherein the fine grinding operation of any pair of side can for example, provide one into To amount, the second grinding wheel 44 in a pair of second grinding tool 43 is driven to be moved from top to bottom to grind a pair of of side of polycrystalline silicon rod；One Second grinding wheel 44 is ground to after polycrystalline silicon rod bottom and passes through polycrystalline silicon rod and stays in lower limit later, is further added by a feeding Amount drives a pair of second grinding wheel 44 to be moved from the bottom up to grind polycrystalline silicon rod；A pair of second grinding wheel 44 is ground to polycrystalline silicon rod After top and pass through and stay in upper limit after polycrystalline silicon rod, continue growing an amount of feeding, drive a pair of second grinding wheel 44 from On down movement to grind polycrystalline silicon rod；In this way, grinding, increases the amount of feeding, and it is reversed to grind, increase the amount of feeding, is repeated several times it Afterwards, a pair of of side of polycrystalline silicon rod can be ground to preset size.

It should be noted that above are only exemplary illustration, it is not intended to limit the protection scope of the application, for example, in needle Chamfering to chamfering and fine grinding device as the second processing unit (plant) and in the processing job description of fine grinding device, is to first carry out The chamfer machining operation of polycrystalline silicon rod performs the fine grinding operation of polycrystalline silicon rod again, but is not limited thereto, in other realities It applies in mode, it is also feasible for first carrying out and executing the chamfer machining operation of polycrystalline silicon rod again after the fine grinding operation of polycrystalline silicon rod , it still should belong to the protection scope of the application.

Subsequent, silicon rod 100 is after the processing operation of the first processing unit (plant) 3 and the second processing unit (plant) 4, then by silicon rod converting means Set 5 by silicon rod from second processing position convert to pretreatment position, and again by silicon rod handler will be processed after silicon rod from The pretreatment position of silicon rod processing platform unloads.Certainly, before unloading silicon rod 100, if it is necessary, in pretreatment position, still Planar smoothness detection can be carried out to the silicon rod 100 after processed operation by flatness detector.Using flatness detector, On the one hand, it can be detected by the planar smoothness to silicon rod 100 to examine whether silicon rod meets production after each processing operation Product requirement, with the effect of each processing operation of determination；On the other hand, detected by planar smoothness to silicon rod 100, also can between The wear condition of processing component in each processing unit (plant) is obtained to obtain, so that real-time perfoming is calibrated or is corrected, or even maintenance or more It changes.

It need to supplement, in the application silicon rod Multi-position processing machine, may also include silicon rod burnishing device.The silicon rod is thrown Electro-optical device can be set on base, for carrying out polishing operation to silicon rod.

For silicon rod burnishing device, generally, processing operation of the silicon rod through the first processing unit (plant) and the second processing unit (plant) Afterwards, the surface of silicon rod can still have the out-of-flatnesses such as a little recess, protrusions, and therefore, it is necessary to carry out corresponding polishing to silicon rod to add Work industry, to improve the surface of silicon rod, obtains the effect of high flat degree and smooth finish surface.Silicon rod burnishing device mainly includes polishing Rack and at least a pair of of polishing unit, at least a pair of of polishing unit are arranged oppositely in polishing rack, for be located at polishing plus The silicon rod on silicon rod conversion equipment at the position of work area carries out polishing operation.

Further, each polishing unit further includes buff spindle and polishing hairbrush, wherein buff spindle and polishing The mounting surface of rack is equipped with and slides laterally guide mechanism and longitudinal sliding motion guide mechanism, and the guide mechanism that slides laterally can be used Such as sliding rail and the combination of sliding block etc., the longitudinal sliding motion guide mechanism can be used such as the combination of sliding rail and sliding block.It utilizes Slide laterally guide mechanism, can enable buff spindle or polishing hairbrush can opposite polishing rack make laterally advancing and retreating movement, using vertical To sliding guide mechanism, buff spindle can be enabled opposite to polish rack and longitudinally moved up and down.Polishing hairbrush is set to polishing The operation end of main shaft, in an alternative embodiment, the polishing hairbrush may be, for example, annular brush, and energy is controlled and rotates.

In the case of silicon rod is silicon single crystal rod, carrying out polishing operation to silicon single crystal rod by silicon rod burnishing device can be into One step includes: that silicon single crystal rod is transferred to the polishing position of silicon rod processing platform first with silicon rod conversion equipment, by silicon rod Positioning mechanism is positioned to silicon single crystal rod and is rotated silicon single crystal rod, the polishing hairbrush rotation at least a pair of of polishing unit of driving Turn, and polished by connection faceted pebble of the polishing hairbrush to silicon single crystal rod, wherein the polishing hairbrush at least a pair of of polishing unit Between spacing be the spacing being less than between two diagonal connection faceted pebbles；Then, by silicon rod positioning mechanism to monocrystalline silicon Stick carries out positioning adjustment, so that the first opposite side face of silicon single crystal rod corresponds to a pair of of polishing unit, by a pair of polishing unit Polishing hairbrush polishes first pair of side of silicon single crystal rod；Then, silicon single crystal rod is positioned by silicon rod positioning mechanism Adjustment, so that the second opposite side face of silicon single crystal rod corresponds to a pair of of polishing unit, by the polishing hairbrush pair in a pair of of polishing unit Second pair of side of silicon single crystal rod polishes.

Wherein, when the connection faceted pebble to silicon single crystal rod polishes: silicon single crystal rod is being rotating always, polishes hairbrush Always it being rotating, a pair of polishing hairbrush continues downwards, to polish next section of each connection faceted pebble of silicon single crystal rod, until It is polished to the bottom of silicon single crystal rod, completes the connection faceted pebble polishing of silicon single crystal rod single；A pair of of polishing hairbrush is driven again from the bottom up Movement is continued each connection faceted pebble for polishing silicon single crystal rod by polishing hairbrush；In this way, after being repeated several times, it can be by monocrystalline silicon Each connection faceted pebble of stick is polished to the effect of high flat degree and smooth finish surface；When the side to silicon single crystal rod polishes, The polishing of any pair of side can for example, silicon single crystal rod is motionless by the positioning of silicon rod positioning mechanism, provides an amount of feeding, drives Polishing hairbrush in a pair of polishing unit is moved from top to bottom to polish a pair of of side of silicon single crystal rod；A pair of polishing hairbrush polishing A pair of of polishing hairbrush is driven to be moved from the bottom up to polish monocrystalline after to silicon single crystal rod bottom and after silicon single crystal rod again Silicon rod；In this way, each side of silicon single crystal rod can be polished to the effect of high flat degree and smooth finish surface after being repeated several times Fruit.

In addition, as seen from the above description, in an alternative embodiment, the throwing that silicon rod burnishing device carries out silicon single crystal rod Light processes operation using the process of first connection faceted pebble polishing trailing flank polishing, but is not limited thereto, real in other changes It applies in example, connection faceted pebble is thrown after first side polishing can also be used in the polishing operation that silicon rod burnishing device carries out silicon single crystal rod The process of light answers technical effect having the same.

In the case of silicon rod is polycrystalline silicon rod, carrying out polishing operation to polycrystalline silicon rod by silicon rod burnishing device can be into One step includes: that polycrystalline silicon rod is transferred to the polishing position of silicon rod processing platform first with silicon rod conversion equipment, by silicon rod Positioning mechanism carries out positioning adjustment to polycrystalline silicon rod, so that the first opposite side face of polycrystalline silicon rod corresponds to a pair of of polishing unit, by Polishing hairbrush in a pair of polishing unit polishes first pair of side of polycrystalline silicon rod；Then, by silicon rod positioning mechanism pair Polycrystalline silicon rod carries out positioning adjustment, so that the second opposite side face of polycrystalline silicon rod corresponds to a pair of of polishing unit, it is single by a pair of polishing Polishing hairbrush in member polishes second pair of side of polycrystalline silicon rod.Wherein, the polishing of any pair of side can for example, Polycrystalline silicon rod is motionless by the positioning of silicon rod positioning mechanism, provides an amount of feeding, drive polishing hairbrush in a pair of of polishing unit from On down movement come polishing polycrystalline silicon stick a pair of of side；A pair of polishing hairbrush is polished to after polycrystalline silicon rod bottom and passes through more It drives a pair of of polishing hairbrush to move after crystalline silicon rod from the bottom up again and carrys out polishing polycrystalline silicon stick；In this way, after being repeated several times Each side of polycrystalline silicon rod is polished to the effect of high flat degree and smooth finish surface.

Further, in an alternative embodiment, in addition to each side to polycrystalline silicon rod carries out polishing operation Except, can also polishing operation be carried out to each fillet surface of polycrystalline silicon rod.When carrying out polishing operation to fillet surface, Positioning adjustment first is carried out to polycrystalline silicon rod by silicon rod positioning mechanism, so that first pair of fillet surface of polycrystalline silicon rod corresponds to a pair of throw Light unit polishes first pair of side of polycrystalline silicon rod by the polishing hairbrush in a pair of of polishing unit；Then, determined by silicon rod Position mechanism carries out positioning adjustment to polycrystalline silicon rod, so that the second opposite side face of polycrystalline silicon rod corresponds to a pair of of polishing unit, by one Polishing hairbrush in polishing unit polishes second pair of side of polycrystalline silicon rod.The specific work that diagonal plane is polished Industry process can be found in the aforementioned process description polished to side, and details are not described herein.

Further more, in an alternative embodiment, may also include silicon rod cleaning dress in the application silicon rod Multi-position processing machine It sets.The silicon rod cleaning device can be set on base, for carrying out and cleaning to silicon rod.For silicon rod cleaning device, one As, silicon rod is through the first processing unit (plant) and the second processing unit (plant) or the first processing unit (plant), the second processing unit (plant) and third processing unit (plant) Processing operation after, the cutting clast generated in operation process can be attached to silicon rod surface, therefore, when necessary, need to silicon rod Carry out necessary cleaning.Generally, the silicon rod cleaning device includes cleanninfg brushes and cooperates with the cleanninfg brushes clear Washing lotion flusher sprays cleaning solution against silicon rod by the cleaning solution flusher in cleaning, meanwhile, it is driven by motor Cleanninfg brushes act on silicon rod, complete washing and cleaning operation.In practical applications, the cleaning solution may be, for example, pure water, the cleaning Brush head may be, for example, rotary brush-head.

In particular, it should be pointed out that if silicon rod Multi-position processing machine is additionally arranged corresponding processing apparatus for work, then silicon rod The quantity and its positional relationship of function position on processing platform and the silicon rod positioning mechanism on conveying ontology are both needed to make corresponding Adjustment.It is assumed that silicon rod Multi-position processing machine is additionally arranged a processing apparatus for work (such as: silicon rod burnishing device), silicon rod processing Also function position (such as: polishing position) can be accordingly added on platform and conveying ontology also increase accordingly a silicon rod Positioning mechanism.Further, it is preferable to which ground, this four silicon rod positioning mechanisms angle set between any two are also and four functions The angular distribution of position between any two is consistent.In this way, when some silicon rod positioning mechanism corresponds to some function position, Other three silicon rod positioning mechanisms are also corresponding with other three function positions respectively.In this way, in continuous productive process, Ren Yishi It carves, when a silicon rod being located on each silicon rod positioning mechanism and silicon rod positioning mechanism is corresponding with function position, Then these silicon rods, which are located at corresponding a certain function position, executes corresponding processing operation.In an alternative embodiment, Four function positions on the silicon rod processing platform be between any two 90 ° distribution, therefore, correspondingly, be disc or Four silicon rod positioning mechanisms on the conveying ontology of circular ring shape are between any two also in 90 ° of distributions.

The application silicon rod Multi-position processing machine, has gathered multiple processing unit (plant)s, can be by silicon rod using silicon rod handler Quickly, steadily and with no damage loaded and unloaded, using silicon rod conversion equipment can by silicon rod between each processing unit (plant) orderly and The multiple procedures for realizing silicon rod processing are seamlessly shifted and are automated, multiple processing unit (plant)s can be simultaneously to corresponding silicon Stick carries out corresponding processing operation, improves the quality of production efficiency and product processing operation.

The application separately discloses a kind of silicon rod multiplexing position processing method, for carrying out the processing operation of multistation to silicon rod. In one embodiment, silicon rod multiplexing position processing method is to be applied to silicon rod Multi-position processing machine, the silicon rod multistation processing Machine includes silicon rod processing platform, silicon rod handler, the first processing unit (plant), the second processing unit (plant) and silicon rod conversion equipment, Wherein, the silicon rod processing platform has pretreatment position, the first processing position and the second processing position.

Referring to Fig. 7, being the flow diagram in one embodiment of the application silicon rod multiplexing position processing method.Such as figure Shown in 7, the application silicon rod multiplexing position processing method the following steps are included:

Step S101 is the pre-treatment step of the first silicon rod: silicon rod handler being enabled to be loaded into the first silicon rod to be processed The pretreatment position of silicon rod processing platform, and the first silicon rod being located at the pretreatment position is pre-processed.Pass through step Rapid S101, the loading of achievable first silicon rod and pretreatment.

Step S103 is the pre-treatment step that the first silicon rod carries out the first processing operation and the second silicon rod: enabling silicon rod converting means The first predetermined angle of rotation is set will complete pretreated first silicon rod by pre-processing position and convert to the first processing position；Enable One processing unit (plant) carries out the first processing operation to the first silicon rod on the first processing position and enables silicon rod handler in this stage Second silicon rod to be processed is loaded into pretreatment position and is pre-processed.By step S103, to conversion to the first processing First silicon rod of position carries out the first processing operation, meanwhile, complete loading and the pretreatment of the second silicon rod.

Step S105 is that the first silicon rod carries out the pre- of the second processing operation, the first processing of the second silicon rod and third silicon rod Processing step: silicon rod conversion equipment is enabled to rotate the second predetermined angle will complete the first silicon rod of the first processing operation and be added by first The conversion of work area position processes position and will complete pretreated second silicon rod and converted by pre-processing position to the first processing to second Position；It enables the second processing unit (plant) carry out the second processing operation to the first silicon rod on the second processing position and enables first in this stage Processing unit (plant) carries out the first processing operation to the second silicon rod on the first processing position and enables silicon rod handler will be to be processed Third silicon rod be loaded into pretreatment and position and pre-processed.By step S105, to the of conversion to the second processing position One silicon rod carries out the second processing operation, carries out the first processing operation to the second silicon rod of conversion to the first processing position, meanwhile, it is complete Loading and pretreatment at third silicon rod.

From the foregoing, it will be observed that (can refer to the first silicon rod) for silicon rod processes operation, silicon rod can orderly and seamless connection Loading, the first processing operation and the second processing operation are executed, multiple manufacturing procedures can be complete in a Multi-position processing machine At, improve conscientiously silicon rod processing operation globality and production efficiency, it is ensured that product processing operation quality.In addition, more A silicon rod can execute corresponding processing operation on different processing positions simultaneously, respectively independent and mutually noiseless, form stream The processing operation of waterline greatly improves the efficiency of silicon rod processing operation.

In fact, the application silicon rod multiplexing position processing method may also include other subsequent steps, referring to Fig. 8, the application Silicon rod multiplexing position processing method after abovementioned steps in addition to may also include that

Step S107 is that the first silicon rod carries out discharging, the second processing operation of the second silicon rod, the first processing of third silicon rod Job step: silicon rod conversion equipment rotation third predetermined angle is enabled will complete the first silicon rod of the second processing operation and be added by second The conversion of work area position is converted by the first processing position to the to pretreatment position and by the second silicon rod that operation is processed in completion first Two processing positions and will complete pretreated third silicon rod by pre-process position convert to first processing position；Enable silicon rod handling dress It sets and the first silicon rod pre-processed on position is subjected to unloading and the 4th silicon rod to be processed is loaded into pretreatment position and right The 4th silicon rod at the pretreatment position is pre-processed, and in this stage, enables the second processing unit (plant) to the second processing district The second silicon rod on position carry out the second processing operation and enable the first processing unit (plant) to the third silicon rod on the first processing position into Row first processes operation.By step S107, given after the first silicon rod that operation is processed in completion second is converted to pretreatment position With unloading, the second processing operation is carried out to the second silicon rod of conversion to the second processing position, to conversion to the first processing position Third silicon rod carries out the first processing operation, meanwhile, loading and pretreatment, each processing position for completing the 4th silicon rod are in good order Ground executes corresponding processing operation.

In practical applications, specifically, for the silicon rod of different kenels, by the first processing unit (plant) to silicon rod into Row first, which processes operation and also has different variations to silicon rod progress the second processing operation by the second processing unit (plant), combines example.Example Such as: if silicon rod 100 is silicon single crystal rod, the first processing unit (plant) 3 can be the circle of contact and corase grinding device and the second processing unit (plant) 4 can be with It is round as a ball and fine grinding device；If silicon rod 100 is polycrystalline silicon rod, the first processing unit (plant) 3 can be corase grinding device and second processes Device can be chamfering and fine grinding device.

Below in conjunction with Fig. 7 above-mentioned, to the silicon rod multiplexing position processing method in aforementioned embodiments for silicon single crystal rod and The different processing job mix of polycrystalline silicon rod are illustrated.

By taking silicon single crystal rod as an example:

In step s101, the first silicon rod being located at the pretreatment position is pre-processed, comprising: enable flatness Detector carries out planar smoothness detection to the first silicon rod.

In step s 103, it enables the first processing unit (plant) carry out the first processing to the first silicon rod on the first processing position to make Industry, comprising: enable the circle of contact and roughly grind device to the first silicon rod progress circle of contact on the first processing position and roughly grind processing operation.The circle of contact And corase grinding processing operation further comprises: first with the circle of contact and corase grinding device to the company in the first silicon rod on the first processing position It connects faceted pebble and carries out circle of contact processing operation, so that the connection between each connection faceted pebble and adjacent side forms preliminary arc and connects It connects；Corase grinding processing processing operation is carried out to the side in the first silicon rod using the circle of contact and corase grinding device afterwards.

In step s105, it enables the second processing unit (plant) carry out the second processing to the first silicon rod on the second processing position to make Industry, comprising: round as a ball and fine grinding device is enabled to carry out round as a ball and fine grinding operation to the first silicon rod on the second processing position.It is round as a ball And fine grinding operation further comprises: round as a ball processing operation is carried out to the first silicon rod first with round as a ball and fine grinding device, to the Connection faceted pebble in one silicon rod is ground, so that the connection faceted pebble in the first silicon rod and side rounding off；Afterwards using round as a ball And fine grinding device carries out fine grinding operation to the side of the first silicon rod.

By taking polycrystalline silicon rod as an example:

In step s101, the first silicon rod being located at the pretreatment position is pre-processed, comprising: enable flatness Detector carries out planar smoothness detection to the first silicon rod.

In step s 103, it enables the first processing unit (plant) carry out the first processing to the first silicon rod on the first processing position to make Industry, comprising: corase grinding device is enabled to carry out corase grinding processing operation to the first silicon rod on the first processing position.

In step s105, it enables the second processing unit (plant) carry out the second processing to the first silicon rod on the second processing position to make Industry, comprising: chamfering and fine grinding device is enabled to carry out chamfering and fine grinding operation to the first silicon rod on the second processing position.Chamfering And fine grinding operation further comprises: round as a ball processing operation is carried out to the first silicon rod first with chamfering and fine grinding device, to the Corner angle in one silicon rod are ground to form fillet surface；Essence is carried out to the side of the first silicon rod using chamfering and fine grinding device afterwards Mill processing operation.

The application silicon rod multiplexing position processing method, can be silicon rod is quick, steady and not damaged using silicon rod handler Ground is loaded and unloaded, and can orderly and seamlessly be carried out silicon rod shift simultaneously certainly between each processing unit (plant) using silicon rod conversion equipment Dynamicization realizes that multiple procedures of silicon rod processing, multiple processing unit (plant)s can carry out corresponding processing to corresponding silicon rod simultaneously and make Industry improves the quality of production efficiency and product processing operation.

Below in conjunction with Fig. 9 to Figure 24, silicon rod multistation is executed in some instances to the application silicon rod Multi-position processing machine Processing operation is described in detail.In the following example, first make following setting: it can also be polysilicon that silicon rod, which is chosen as silicon single crystal rod, Stick, in which: silicon single crystal rod to be processed is the silicon cube that section is substantially in class rectangle, and there are four side, two neighboring sides for tool Between be formed with connection faceted pebble in the angle R；Polycrystalline silicon rod to be processed is the silicon cube of rectangular in cross-section, tool there are four side and Four corner angle.Used silicon rod Multi-position processing machine includes silicon rod processing platform, silicon rod handler, the first processing dress It sets, the second processing unit (plant) and silicon rod conversion equipment, certainly, silicon rod Multi-position processing machine may also include height testing instrument, smooth Spend detector etc..In addition, silicon rod processing platform is equipped with pretreatment position, the first processing position and the second processing position, in advance Processing position, the first processing position and the second processing position process the process of operation according to silicon rod and sequence is arranged, right therewith Ying Di, silicon rod conversion equipment also are provided with three silicon rod positioning mechanisms, wherein pretreatment position, the first processing position and second Processing position is in 120 ° of distributions between any two, and therefore, three silicon rod positioning mechanisms are between any two also in 120 ° of distributions.Herein, Assuming that being forward direction according to the trend of the sequence of pretreatment position, the first processing position and the second processing position, with the forward direction The trend of opposite sequence is reverse.

Step 1, the first silicon rod to be processed is placed on the Workpiece carrier platform of silicon rod handler.In the present embodiment In, the first silicon rod 101 is to erect to be placed on silicon rod plummer 21, and the first silicon rod 101 is placed in silicon rod handling position The operation of silicon rod plummer 21 manual work can be used corresponding jig can also be used to implement, the jig may be, for example, silicon Stick transfer tool.In addition, when necessary, the first silicon rod on silicon rod plummer 21 can be adjusted by rotation silicon rod plummer 21 101 angle, the angle may be, for example, 45 ° of placements, that is, two diagonal lines of the first silicon rod 101 correspond respectively to sidesway side To (X-direction) and translation direction (Y direction).Implement aforesaid operations after silicon rod Multi-position processing machine state for details, reference can be made to Fig. 9, Fig. 9 are shown as silicon rod and are straightened the status diagram being placed on silicon rod plummer.

Step 2, the first silicon rod to be processed is loaded into the pretreatment position of silicon rod processing platform.In the present embodiment, It is by silicon rod handler 2 by the pretreatment position that the first silicon rod 101 to be processed is loaded into silicon rod processing platform 11 What silicon rod clamper 25 was implemented.Specifically, first, it is ensured that the silicon rod clamper 25 in silicon rod handler 2 corresponds to silicon rod loading place Position, for example, commutation movement can be made by driving commutation carrier 23, so that the conversion of silicon rod clamper 25 to the silicon rod of commutation carrier 23 fills Unload position；Then, it drives the clamp arm 254 in silicon rod clamping piece 253 to make decentralization to act to be transferred to clamping state simultaneously by releasing orientation It is able to clamp the first silicon rod 101, for details, reference can be made to Figure 10, Figure 10 for the state of silicon rod Multi-position processing machine after implementation aforesaid operations It is shown as the status diagram that silicon rod is clamped by silicon rod clamper；Then, the first silicon rod 101 is detached from and loads and unloads position in silicon rod.It should It is detached from operation, in an alternative embodiment, 253 retaining clip conjunction state of silicon rod clamping piece utilizes the silicon in silicon rod handling position Stick plummer 21 makees descending motion, so that the first silicon rod 101 is detached from silicon rod plummer 21；In another alternative embodiment, By driving the ascending motion (silicon rod clamping piece 253 is movable design) of silicon rod clamping piece 253 to drive the first silicon rod 101 de- From in silicon rod plummer 21；Then, driving commutation carrier 23 makees commutation movement (such as 180 ° of rotation), so that on commutation carrier 23 Silicon rod clamper 25 by silicon rod handling position convert to pretreatment position；Then, the first silicon rod 101 is placed in pretreatment On the rotation plummer 531 of the first silicon rod positioning mechanism 53 at position, and rotatably compressing by the first silicon rod positioning mechanism 53 Device 533 makees descending motion by lifting drive to compress the first silicon rod 101 and realize positioning, implements silicon rod after aforesaid operations The state of Multi-position processing machine for details, reference can be made to Figure 11, Figure 11 be shown as silicon rod by commutation carrier be placed in pretreatment position shape State schematic diagram.

It should be noted that in an alternative embodiment, it, can also benefit before clamping the first silicon rod using silicon rod clamper 25 The height of the first silicon rod 101 is detected with height testing instrument 7, in this way, the silicon rod clamping piece 253 in silicon rod clamper 25 can be according to height The testing result of detector 7 is moved up or is moved down to adjust the folder between multiple silicon rod clamping pieces 253 subsequent Spacing is held, for details, reference can be made to Figure 12, Figure 12 to be shown as height detection for the state of silicon rod Multi-position processing machine after implementation aforesaid operations Instrument detection is located at the status diagram of silicon rod height on handling plummer.

Step 3, planar smoothness detection is carried out to the first silicon rod at pretreatment position.Silicon rod is more after implementing aforesaid operations For details, reference can be made to Figure 13 and Figure 14 for the state of station processing machine, are shown as the shape of flatness detector detection silicon rod planar smoothness State schematic diagram.

In the present embodiment, carrying out planar smoothness detection to the first silicon rod 101 at pretreatment position is by smooth Spend what detector was implemented.Specifically, driving commutation carrier 23 makees commutation movement (such as 180 ° of rotation), so that on commutation carrier 23 Flatness detector converted by silicon rod handling position to pretreatment position, wherein silicon rod clamper 25 and flatness detector point It is not configured at the first mounting surface and the second mounting surface in commutation carrier 23 backwards to setting and when necessary, passes through driving in this stage The rotary compacting device 533 of first silicon rod positioning mechanism 53 rotates to adjust the angle of the first silicon rod 101, such as drives First silicon rod 101 rotates 45 °, so that the first silicon rod 101 corresponds respectively to sidesway direction (X-direction) by original two diagonal lines It is adjusted to two adjacent sides with translation direction (Y direction) and corresponds respectively to sidesway direction and translation direction, that is, wherein A side be right against commutation carrier 23 on flatness detector；Then, using flatness detector to the first silicon rod 101 Four sides carry out planar smoothness detection, any one side planar smoothness detection further includes: by detection control Device control detector shift mechanism drives contacting gauge 61 to shift and control contacting gauge 61 and sequentially detects the first silicon Each test point in stick 101 on current side to be measured.

Specifically, on the one hand, include: to be controlled by detection for the detection of each test point in any one tested surface Device control detector shift mechanism (including first direction shift mechanism, second direction shift mechanism and third direction shifting machine Structure) drive contacting gauge in plane of motion internal shift so that contacting gauge corresponds to current detection point to be measured； By detection controller control detector shift mechanism (mainly second direction shift mechanism) drive contacting gauge face to The current detection point of survey is mobile until silicon rod is touched, at this point, detection controller will receive and be transmitted across from contacting gauge Next Continuity signal (or cut-off signal) simultaneously suspends detection controller control detection according to the Continuity signal (or cut-off signal) The operation of instrument shift mechanism, and by benchmark information and detector shift mechanism (mainly second direction shift mechanism) the Moving distance on two directions extrapolates the test point in the tested surface that contacting gauge is currently touched relative to base Relative distance on schedule；Contacting gauge is driven to deviate from current inspection to be measured by detection controller control detector shift mechanism Measuring point is mobile to reset, and completes the detection of a test point.

On the other hand, it for the detection of multiple test points on tested surface, certainly will need to carry out position between test point Switching, therefore, after the detection for completing a upper test point, to reset contacting gauge by detector shift mechanism It is displaced to the position of next test point by detector shift mechanism again later, wherein belong to the more of a side to be measured The dot matrix way arrangement of rule can be used in a test point.It should be noted that putting down when a side for completing the first silicon rod 101 After whole degree detection, it is also necessary to switch to next side and carry out flatness detection.The switching of side can be by shifting the first silicon Stick 101 is realized, for example, can pass through the rotary compacting device of the first silicon rod positioning mechanism 53 of driving in workpiece filling structure 533 rotate to adjust the angle of the first silicon rod 101 (such as the first silicon rod 101 is driven to rotate 90 °) and switch to neighbouring Next side.

Extraly, in step 3, it is carried out in addition to pre-processing the first silicon rod 101 at position using 7 pairs of flatness detector Except planar smoothness detection, first silicon rod 101 can also be carried out by the cooperation of flatness detector 7 and silicon rod clamper 25 Correction operation.

It in the present embodiment, is mainly by the center of the first silicon rod 101 and rotation generally in the correction operation The center of vicarious microscope carrier 531 is corresponding to be overlapped.The concrete operations of the correction operation can include: rotated by 7 Duis of flatness detector The first silicon rod 101 carried on plummer 531 carries out planar smoothness detection, to obtain the integral position of the first silicon rod 101 Overview；The integral position overview of first silicon rod 101 of acquisition and the position of rotation plummer 531 are compared, in turn Obtain the deviation information between the center of the first silicon rod 101 and the center of rotation plummer 531；The carrier 23 that commutates rotates 180 ° of works Commutation movement, the first silicon rod 101 corresponded on rotation plummer 531 by the silicon rod clamper 25 on commutation carrier 23 simultaneously clamp First silicon rod 101；Utilize the first direction shift mechanism and/or second direction in detection controller control detector shift mechanism Shift mechanism driving commutation carrier 23 in a first direction and/or second party moves up, thus drive silicon rod clamper 25 and by The 101 relative rotation plummer 531 of the first silicon rod that silicon rod clamper 25 clamps makees position adjustment, is finally able to the first silicon rod 101 Center with rotation the center of plummer 531 it is corresponding be overlapped, complete for the first silicon rod 101 correction operation.

In addition, being directed to the silicon rod of different kenels, difference in detail is deposited in the correction operation.

By taking silicon single crystal rod as an example, Figure 15 is please referred to, is shown as carrying out silicon single crystal rod in the schematic diagram of correction operation.Such as Figure 15 Shown, silicon single crystal rod to be processed is the silicon cube that section is substantially in class rectangle, and tool is there are four side, between two neighboring side It is formed with the connection faceted pebble in the angle R.Therefore, it may particularly include for the correction operation of silicon single crystal rod: by flatness detector pair Four sides of the silicon single crystal rod carried on rotation plummer carry out planar smoothness detection, to obtain by four side institute structures At silicon single crystal rod side center O1；Four connections by flatness detector to the silicon single crystal rod carried on rotation plummer Faceted pebble carries out planar smoothness detection, to obtain the center for connecting the silicon single crystal rod connection faceted pebble that faceted pebble is constituted by four O2；The size of the silicon single crystal rod finished product after silicon single crystal rod is processed through multistation is calculated；According to the ruler of silicon single crystal rod finished product The center O2 of very little, silicon single crystal rod side center O1, silicon single crystal rod connection faceted pebble, extrapolate the center O3 of silicon single crystal rod finished product； The center O3 of the silicon single crystal rod finished product of acquisition and the center O of rotation plummer are compared, and then the deviation letter of the two Breath；The carrier that commutates makees commutation movement, and silicon single crystal rod and folder on rotation plummer are corresponded to by the silicon rod clamper on commutation carrier Silicon single crystal rod is handled, the first direction shift mechanism and/or second party in detection controller control detector shift mechanism are utilized Commutation carrier is driven in a first direction to shift mechanism and/or second party moves up, to drive silicon rod clamper and by silicon Rod clamp clamping silicon single crystal rod relative rotation plummer make position adjustment, be finally able to by the center O3 of silicon single crystal rod finished product with Rotate the corresponding correction operation for being overlapped, completing to be directed to silicon single crystal rod of center O of plummer.

By taking polycrystalline silicon rod as an example, Figure 16 is please referred to, is shown as carrying out polycrystalline silicon rod in the schematic diagram of correction operation.Such as Figure 16 Shown, polycrystalline silicon rod to be processed is the silicon cube of rectangular in cross-section, and there are four side and four corner angle for tool.Therefore, for more The correction operation of crystalline silicon rod may particularly include: four sides by flatness detector to the polycrystalline silicon rod carried on rotation plummer Face carries out planar smoothness detection, to obtain the center O1 for the polycrystalline silicon rod being made of four sides；By the polycrystalline of acquisition The center O1 of silicon rod and the center O of rotation plummer are compared, and then the deviation information of the two；Commutation carrier commutates Movement, the polycrystalline silicon rod corresponded on rotation plummer by the silicon rod clamper on commutation carrier simultaneously clamp polycrystalline silicon rod, utilize Detect the first direction shift mechanism in controller control detector shift mechanism and/or the driving commutation of second direction shift mechanism Carrier is in a first direction and/or second party moves up, thus the polysilicon for driving silicon rod clamper and being clamped by silicon rod clamper Stick relative rotation plummer makees position adjustment, is finally able to the center O1 of polycrystalline silicon rod is corresponding with the rotation center O of plummer It is overlapped, completes the correction operation for being directed to polycrystalline silicon rod.

Step 4, the first silicon rod for completing planar smoothness detection is converted by pre-processing position to the by pretreatment position One processing position simultaneously carries out the first processing operation to the first silicon rod on the first processing position, in this stage, by be processed the Two silicon rods are loaded into pretreatment position and are pre-processed.The state of silicon rod Multi-position processing machine specifically may be used after implementation aforesaid operations Referring to Figure 17, it is shown as the status diagram for the first processing operation being carried out to the first silicon rod and the second silicon rod is loaded.

In the present embodiment, the first silicon rod for completing planar smoothness detection is turned by pretreatment position by pretreatment position Shifting to the first processing position is to implement to complete by enabling silicon rod conversion equipment rotate the first predetermined angle, as previously mentioned, pre- place Reason position, the first processing position and the second processing position are in 120 ° of distributions between any two, and three silicon rod positioning mechanisms 53 are two-by-two Between also in 120 ° of distributions, therefore, enabling silicon rod conversion equipment 5 rotate the first predetermined angle is actually to enable silicon rod conversion equipment 5 rotate forward 120 °, and the first silicon rod 101 of the first silicon rod positioning mechanism 53 and its positioning that are initially positioned on pretreatment position is just In conversion to the first processing position.

Carrying out the first processing operation to the first silicon rod 101 on the first processing position is implemented by the first processing unit (plant) 3 's.In the case of the first silicon rod 101 is silicon single crystal rod, the first processing unit (plant) 3 is the circle of contact and corase grinding device.By the circle of contact and corase grinding Device, which carries out the circle of contact and corase grinding processing operation to silicon single crystal rod, to be generally comprised: the circle of contact processes operation and corase grinding processing operation.

Circle of contact processing operation further comprises: first silicon rod 101 being transferred to the first processing first with silicon rod conversion equipment 5 Position carries out positioning adjustment to the first silicon rod 101 by the first silicon rod positioning mechanism 53；Initially, in silicon rod conversion equipment 5 by When one silicon rod 101 transfers to the first processing position, the side of the first silicon rod 101 corresponds to the circle of contact and roughly grinds a pair in device First grinding tool 33, therefore, carrying out positioning adjustment to the first silicon rod 101 by the first silicon rod positioning mechanism 53 can be for example including driving the Positive (or reverse) 45 ° of the rotation of one silicon rod 101, so that first pair of connecting edge face in the first silicon rod 101 is corresponding to the circle of contact and slightly The first grinding tool of a pair 33 in mill apparatus enables opposite first rack 31 of the first grinding tool 33 make traverse feed according to the amount of feeding, rotates The first grinding wheel 34 and the first grinding tool 33 of driving in first grinding tool 33 move up and down to first pair of connection in the first silicon rod 101 Faceted pebble slightly cut for the first time；It drives the first silicon rod 101 to rotate forward 5 ° by the first silicon rod positioning mechanism 53, rotates the first grinding tool The first grinding wheel 34 and the first grinding tool 33 of driving in 33 move up and down to carry out to first pair of connection faceted pebble in the first silicon rod 101 It slightly cuts for the second time；The first silicon rod 101 is driven to rotate forward 80 ° by the first silicon rod positioning mechanism 53, so that in the first silicon rod 101 Second pair of connecting edge face corresponds to the circle of contact and roughly grinds the first grinding tool of a pair 33 in device, rotates the first sand in the first grinding tool 33 Wheel 34 simultaneously drives the first grinding tool 33 to move up and down slightly cut for the first time to second pair of connection faceted pebble in the first silicon rod 101； The first silicon rod 101 is driven to rotate forward 5 ° by the first silicon rod positioning mechanism 53, the first grinding wheel 34 in the first grinding tool 33 of rotation is simultaneously The first grinding tool 33 is driven to move up and down slightly to be cut for the second time to second pair of connection faceted pebble in the first silicon rod 101；By first Silicon rod positioning mechanism 53 drives the first silicon rod 101 to rotate forward 5 °, rotates the first grinding wheel 34 in the first grinding tool 33 and drives the One grinding tool 33 moves up and down to carry out third time to second pair of connection faceted pebble in the first silicon rod 101 and slightly cut；Determined by the first silicon rod Position mechanism 53 drives the first silicon rod 101 to rotate forward 80 °, rotates the first grinding wheel 34 in the first grinding tool 33 and drives the first grinding tool 33 move up and down to carry out third time to first pair of connection faceted pebble in the first silicon rod 101 and slightly cut.List as the first silicon rod 101 The state that crystalline silicon rod implements above-mentioned circle of contact processing operation is shown as silicon single crystal rod for details, reference can be made to Figure 18, Figure 18 and processes work in the circle of contact State change schematic diagram in industry.

It should be strongly noted that driving the first silicon rod by the first silicon rod positioning mechanism 53 in aforementioned circle of contact processing operation 101 rotation respective angles, such as: the first silicon rod positioning mechanism 53 drives the first silicon rod 101 to rotate forward 5 °, is not unique Implementation is suitable for adjusting the angle in other alternative embodiments, for example, 3 ° to 7 °, including 3 °, 4 °, 5 °, 6 °, 7 ° or Other angles, correspondingly, the case where driving the first silicon rod 101 to rotate forward 80 ° by the first silicon rod positioning mechanism 53 then adaptability It adjusts the angle.Following table one is please referred to, table one is shown as the sample situation of rotational angle each numerical value within the scope of 3 ° to 7 °.

Table one

Above-mentioned circle of contact processing operation process is only the embodiment in circle of contact processing operation, but is not limited thereto, such as: First silicon rod 101 is transferred into the first processing position first with silicon rod conversion equipment 5, drives the by the first silicon rod positioning mechanism 53 One silicon rod 101 rotates forward 40 °, so that first pair of connecting edge face in the first silicon rod 101 corresponds in the circle of contact and corase grinding device The first grinding tool of a pair 33, rotate the first grinding tool 33 in the first grinding wheel 34 and drive the first grinding tool 33 move up and down to first First pair of connection faceted pebble in silicon rod 101 slightly cut for the first time；First silicon rod 101 is being driven just by the first silicon rod positioning mechanism 53 To 5 ° of rotation, rotates the first grinding wheel 34 in the first grinding tool 33 and the first grinding tool 33 is driven to move up and down to the first silicon rod 101 In first pair of connection faceted pebble slightly cut for the second time；The first silicon rod 101 is driven to rotate forward by the first silicon rod positioning mechanism 53 It 5 °, rotates the first grinding wheel 34 in the first grinding tool 33 and the first grinding tool 33 is driven to move up and down to the in the first silicon rod 101 A pair of connection faceted pebble carries out third time and slightly cuts；The first silicon rod 101 is driven to rotate forward 80 ° by the first silicon rod positioning mechanism 53, rotation Turn the first grinding wheel 34 in the first grinding tool 33 and the first grinding tool 33 is driven to move up and down to second pair of company in the first silicon rod 101 Faceted pebble is connect slightly cut for the first time；The first silicon rod 101 is driven to rotate forward 5 ° by the first silicon rod positioning mechanism 53, the first mill of rotation Tool 33 in the first grinding wheel 34 and drive the first grinding tool 33 move up and down with to second pair of connection faceted pebble in the first silicon rod 101 into Row is slightly cut for the second time；It drives the first silicon rod 101 to rotate forward 5 ° by the first silicon rod positioning mechanism 53, rotates in the first grinding tool 33 First grinding wheel 34 simultaneously drives the first grinding tool 33 to move up and down to carry out third time to second pair of connection faceted pebble in the first silicon rod 101 Slightly cut.

Corase grinding processing operation further comprises: first silicon rod 101 being transferred to the first processing first with silicon rod conversion equipment 5 Position carries out positioning adjustment to the first silicon rod 101 by the first silicon rod positioning mechanism 53, so that first pair in the first silicon rod 101 Side corresponds to the circle of contact and roughly grinds the first grinding tool of a pair 33 in device, enables opposite first rack 31 of the first grinding tool 33 according to feeding Amount makees traverse feed, rotates the first grinding wheel 34 in the first grinding tool 33 and the first grinding tool 33 is driven to move up and down to the first silicon rod It roughly grinds first pair of side in 101；Positive (or reverse) rotation of first silicon rod 101 is driven by the first silicon rod positioning mechanism 53 90 °, so that the second opposite side face in the first silicon rod 101 corresponds to the circle of contact and roughly grinds the first grinding tool of a pair 33 in device, rotation The first grinding wheel 34 and the first grinding tool 33 of driving in first grinding tool 33 move up and down to second pair of side in the first silicon rod 101 It is roughly ground.Silicon single crystal rod as the first silicon rod 101 implements the state of above-mentioned corase grinding processing operation, and for details, reference can be made to Figure 19, figures 19 are shown as state change schematic diagram of the silicon single crystal rod in corase grinding processing operation.

In the case of the first silicon rod 101 is polycrystalline silicon rod, the first processing unit (plant) 3 is corase grinding device.By corase grinding device pair Polycrystalline silicon rod, which carries out corase grinding processing operation, to be generally comprised: first silicon rod 101 being transferred to first first with silicon rod conversion equipment 5 Position is processed, positioning adjustment is carried out to the first silicon rod 101 by the first silicon rod positioning mechanism 53, so that the in the first silicon rod 101 A pair of of side corresponds to the first grinding tool of a pair 33 in corase grinding device 3, enables opposite first rack 31 of the first grinding tool 33 according to feeding Amount makees traverse feed, rotates the first grinding wheel 34 in the first grinding tool 33 and the first grinding tool 33 is driven to move up and down to the first silicon rod It roughly grinds first pair of side in 101；Positive (or reverse) rotation of first silicon rod 101 is driven by the first silicon rod positioning mechanism 53 90 °, so that the second opposite side face in the first silicon rod 101 corresponds to the first grinding tool of a pair 33 in corase grinding device 3, the first mill of rotation The first grinding wheel 34 and the first grinding tool 33 of driving in tool 33 move up and down thick to carry out to second pair of side in the first silicon rod 101 Mill.Polycrystalline silicon rod as the first silicon rod 101 implements the state of above-mentioned corase grinding processing operation, and for details, reference can be made to Figure 20, Figure 20 to show For state change schematic diagram of the polycrystalline silicon rod in corase grinding processing operation.

In step 4, by the second silicon rod to be processed be loaded into pretreatment position and carry out pretreated implementation process can Referring to the description in abovementioned steps 2 and step 3, details are not described herein.

Step 5, by completion first process operation the first silicon rod by first processing position convert to second processing position with And pretreated second silicon rod will be completed and converted by pre-processing position to the first processing position；To first on the second processing position Silicon rod carries out the second processing operation, in this stage, enable to the second silicon rod on the first processing position carry out the first processing operation with And third silicon rod to be processed is loaded into pretreatment position and is pre-processed.Silicon rod multistation is processed after implementing aforesaid operations The state of machine shows the silicon rod Multi-position processing machine of the application for details, reference can be made to Figure 21, Figure 21 while processing to three silicon rods The status diagram of operation.

In the present embodiment, the first silicon rod 101 that completion first is processed to operation is converted by the first processing position to second Processing position and completing pretreated second silicon rod 102 by pre-processing position and converting to the first processing position is by enabling silicon Stick conversion equipment 5 rotates the second predetermined angle and implements completion, as previously mentioned, pretreatment position, the first processing position, Yi Ji Two processing positions are in 120 ° of distributions between any two, and three silicon rod positioning mechanisms 53 also in 120 ° of distributions, therefore, enable silicon between any two It is actually that silicon rod conversion equipment 5 is enabled to rotate forward 120 ° that stick conversion equipment 5, which rotates the second predetermined angle, is initially positioned at first Process the first silicon rod 101 of the first silicon rod positioning mechanism 53 on position and its positioning just in conversion to the second processing position and Second silicon rod 102 of the second silicon rod positioning mechanism 53 and its positioning being initially positioned on pretreatment position is just converted to the first processing On position.

Carrying out the second processing operation to the first silicon rod 101 on the second processing position is implemented by the second processing unit (plant) 4 's.In the case of the first silicon rod 101 is silicon single crystal rod, the second processing unit (plant) 4 is round as a ball and fine grinding device.By round as a ball and fine grinding Device, which carries out round as a ball and fine grinding operation to silicon single crystal rod, to be generally comprised: round as a ball processing operation and fine grinding operation.Rolling Circle processing operation further comprises: the first silicon rod 101 as silicon single crystal rod being transferred to silicon rod using silicon rod conversion equipment 5 and is added Second processing position of work platform, positions the first silicon rod 101 by the first silicon rod positioning mechanism 53 and rotates the first silicon rod 101, it enables opposite second rack 41 of the second grinding tool 43 make traverse feed according to the amount of feeding, rotates the second grinding wheel in the second grinding tool 43 44 and drive the second grinding tool 43 up and down motion grind with each connection faceted pebble to the first silicon rod 101 it is round as a ball so that first The connection faceted pebble of silicon rod 101 is ground to preset size and whole rounding, that is, connection faceted pebble and side rounding off.As The silicon single crystal rod of one silicon rod 101 implements the above-mentioned round as a ball state for processing operation, and for details, reference can be made to Figure 22, Figure 22 to be shown as monocrystalline silicon Status diagram of the stick in round as a ball processing operation.

Fine grinding operation further comprises: positioning adjustment is carried out to the first silicon rod 101 by the first silicon rod positioning mechanism 53, So that the first opposite side face in the first silicon rod 101 corresponds to the second grinding tool of a pair 43 in round as a ball and fine grinding device 4, the second mill is enabled Opposite second rack 41 of tool 43 makees traverse feed according to the amount of feeding, rotates the second grinding wheel 44 in the second grinding tool 43 and drives second Grinding tool 43 moves up and down to refine to first pair of side in the first silicon rod 101；It is driven by the first silicon rod positioning mechanism 53 Positive (or reverse) 90 ° of the rotation of first silicon rod 101, so that the second opposite side face in the first silicon rod 101 corresponds to round as a ball and fine grinding The second grinding tool of a pair 43 in device 4 rotates the second grinding wheel 44 in the second grinding tool 43 and the second grinding tool 43 is driven to move up and down To be refined to second pair of side in the first silicon rod 101.Silicon single crystal rod as the first silicon rod 101 is implemented above-mentioned fine grinding and is added For details, reference can be made to Figure 23, Figure 23 to be shown as status diagram of the silicon single crystal rod in fine grinding operation for the state for the industry that works.

In the case of the first silicon rod 101 is polycrystalline silicon rod, the second processing unit (plant) 4 is chamfering and fine grinding device.By chamfering And fine grinding device carries out chamfering and fine grinding operation to polycrystalline silicon rod and can generally comprise: chamfer machining operation and fine grinding are made Industry.

Chamfer machining operation further comprises: will be as 101 turns of the first silicon rod of polycrystalline silicon rod using silicon rod conversion equipment 5 It send to the second of silicon rod processing platform and processes position, positioning adjustment is carried out to the first silicon rod 101 by the first silicon rod positioning mechanism 53, Such as the first silicon rod 101 is driven to rotate 45 °, so that first pair of corner angle in the first silicon rod 101 correspond to chamfering and fine grinding device In the second grinding tool of a pair 43, enable opposite second rack 41 of the second grinding tool 43 make traverse feed, the second mill of rotation according to the amount of feeding The second grinding wheel 44 and driving the second grinding tool 43 up and down motion in tool 43 are ground with first pair of corner angle to the first silicon rod 101 It cuts, so that first pair of corner angle of the first silicon rod 101 form fillet surface through grinding；First is driven by the first silicon rod positioning mechanism 53 Positive (or reverse) 90 ° of the rotation of silicon rod 101, so that second pair of corner angle in the first silicon rod 101 correspond to chamfering and fine grinding device 4 In the second grinding tool of a pair 43, rotate the second grinding wheel 44 in the second grinding tool 43 and the second grinding tool 43 driven to move up and down to the Second pair of corner angle of one silicon rod 101 are ground, so that second pair of corner angle of the first silicon rod 101 form fillet surface through grinding. Polycrystalline silicon rod as the first silicon rod 101 implements the state of above-mentioned chamfer machining operation, and for details, reference can be made to Figure 24, Figure 24 to be shown as Status diagram of the polycrystalline silicon rod in chamfer machining operation.

Fine grinding operation further comprises: by 53 pairs of the first silicon rod positioning mechanism polysilicons as the first silicon rod 101 Stick carries out positioning adjustment, such as the first silicon rod 101 is driven to rotate 45 °, so that the first opposite side face in the first silicon rod 101 corresponds to The second grinding tool of a pair 43 in chamfering and fine grinding device, enable opposite second rack 41 of the second grinding tool 43 according to the amount of feeding make laterally into It gives, rotate the second grinding wheel 44 in the second grinding tool 43 and the second grinding tool 43 is driven to move up and down with first to the first silicon rod 101 Side is refined；Positive (or reverse) 90 ° of the rotation of first silicon rod 101 is driven by the first silicon rod positioning mechanism 53, so that the The second opposite side face in one silicon rod 101 corresponds to the second grinding tool of a pair 43 in chamfering and fine grinding device 4, rotates the second grinding tool 43 In the second grinding wheel 44 and drive the second grinding tool 43 up and down motion refined with second pair of side to the first silicon rod 101.Make Implement the state of above-mentioned fine grinding operation for the polycrystalline silicon rod of the first silicon rod 101 for details, reference can be made to Figure 25, Figure 25 to be shown as more Status diagram of the crystalline silicon rod in fine grinding operation.

In steps of 5, the second silicon rod for completing planar smoothness detection is converted by pretreatment position by pretreatment position It can refer to the first processing position and to the implementation process of the second silicon rod 102 progress the first processing operation on the first processing position The description of abovementioned steps 4, and third silicon rod to be processed is loaded into pretreatment position and carries out pretreated implementation and can refer to The description of abovementioned steps 2 and step 3, details are not described herein.

Step 6, by completion second process operation the first silicon rod by second processing position convert to pretreatment position and The second silicon rod that operation is processed in completion first is converted to the second processing position and will be completed pretreated by the first processing position Third silicon rod is converted by pre-processing position to the first processing position；The first silicon rod pre-processed on position is unloaded and incited somebody to action 4th silicon rod to be processed is loaded into pretreatment position and pre-processes to the 4th silicon rod being located at the pretreatment position, In this stage, the second processing operation is carried out to the second silicon rod on the second processing position and to the third on the first processing position Silicon rod carries out the first processing operation.For details, reference can be made to Figure 26, Figure 26 for the state of silicon rod Multi-position processing machine after implementation aforesaid operations It is shown as completing the status diagram of the silicon rod discharging of processing operation.

In the present embodiment, the first silicon rod 101 that completion second is processed to operation is converted by the second processing position to pre- Reason position and the second silicon rod that operation is processed in completion first is converted by the first processing position to the second processing position and will be complete Being converted by pretreatment position to the first processing position at pretreated third silicon rod is by enabling silicon rod conversion equipment 5 rotate third Predetermined angle implements completion, as previously mentioned, pretreatment position, the first processing position and the second processing position are between any two It is distributed in 120 °, therefore three silicon rod positioning mechanisms 53, enable the rotation of silicon rod conversion equipment 5 the between any two also in 120 ° of distributions Three predetermined angles are actually to enable 240 ° of 5 backwards rotation of silicon rod conversion equipment or silicon rod conversion equipment 5 is enabled to rotate forward 120 ° It can be realized, the first silicon rod 101 of the first silicon rod positioning mechanism 53 being initially positioned on the second processing position and its positioning just turns Second silicon rod of the second silicon rod positioning mechanism 53 and its positioning that shift on pretreatment position, are initially positioned on the first processing position 102 process on position and are initially positioned at the third silicon rod positioning mechanism 53 on pretreatment position with regard to conversion to second and its determine The third silicon rod 103 of position is just in conversion to the first processing position.

Particularly, it is used for silicon rod on silicon rod processing platform in pretreating zone for 5 rotary setting of silicon rod conversion equipment It is converted between position, the first processing position and the second processing position, it is necessary to be described in detail.

Figure 27 is please referred to, being shown as the application silicon rod Multi-position processing machine is the state signal that three stations are processed in operation Figure.As shown in figure 27, in this embodiment, the pretreatment position on the silicon rod processing platform, the first processing position, Yi Ji Two processing positions are set in sequence, wherein silicon rod handler are correspondingly provided at pretreatment position, the first processing position is correspondingly provided with First processing unit (plant), second processing position is correspondingly provided with the second processing unit (plant), and, pretreatment position, first processing position and Second processing position is in 120 ° of distributions between any two, correspondingly, for three silicon on round or circular ring shape conveying ontology Stick positioning mechanism is between any two also in 120 ° of distributions.

It is assumed herein that being according to the trend of the sequence of pretreatment position, the first processing position and the second processing position The trend of forward direction, the sequence opposite with the forward direction is reverse.Correspondingly, the process for executing the processing of silicon rod multistation can be wrapped substantially It includes: under initial conditions, enabling silicon rod handler 2 that first silicon rod 101 to be processed is loaded into the pre- place of silicon rod processing platform Position is managed, and the first silicon rod 101 being located at the pretreatment position is pre-processed；Enable silicon rod conversion equipment 5 is positive to turn Dynamic 120 ° are converted with that will complete pretreated first silicon rod 101 by pre-processing position to the first processing position, and the first processing is enabled to fill It sets the first silicon rod 101 on 3 pair of first processing position and carries out the first processing operation, in this stage, enable silicon rod handler 2 will be to Second silicon rod 102 of processing is loaded into pretreatment position and is pre-processed；Silicon rod conversion equipment 5 is enabled to rotate forward 120 ° to incite somebody to action The first silicon rod 101 for completing the first processing operation is converted to the second processing position by the first processing position and will complete to pre-process The second silicon rod 102 by pre-process position convert to first processing position, enable the second processing unit (plant) 4 to second processing position on First silicon rod 101 carries out the second processing operation, in this stage, enables the first processing unit (plant) 3 to the second silicon on the first processing position Stick 102 carries out the first processing operation and enables silicon rod handler 5 that third silicon rod 103 to be processed is loaded into pretreatment position And it is pre-processed；Silicon rod conversion equipment 5 is enabled to rotate forward 120 ° or 240 ° of backwards rotation so that the second processing operation will be completed Second silicon rod 102 of operation is converted to pretreatment position by the second processing position and processed completion first to first silicon rod 101 It is converted by the first processing position to the second processing position and pretreated third silicon rod 103 will be completed by pretreatment position turn The first processing position is shifted to, the first silicon rod 101 pre-processed on position is unloaded.

In view of the cables such as the power supply line laid in the silicon rod Multi-position processing machine or signal wire will not be converted because of silicon rod Device it is excessive rotation and drive those cables excessively wind in turn result in those cables around break.In a specific embodiment, originally The technical solution consideration that application provides limits the maximum rotation angle of the silicon rod conversion equipment, that is, is enabling silicon rod convert May include following two situation during device is converted the first silicon rod 101 to pretreatment position by the second processing position:

The first situation is that the rotation angle range of silicon rod conversion equipment 5 is ± 240 °, in particular to makes silicon rod converting means It sets 5 and original position is returned to after 120 ° and 240 ° primary of backwards rotation by rotating forward twice, operation is processed into completion second The first silicon rod 101 by second processing position convert to pretreatment position.This kind of situation bring beneficial effect further includes being The internal structure design of entire silicon rod Multi-position processing machine provides more flexible design space, such as, it may be considered that the Two processing districts to be arranged between pretreating zone other components without regard to hinder silicon rod conversion equipment rotation the case where.

Second situation is that the rotation angle range of the silicon rod conversion equipment is ± 360 °, and silicon rod conversion equipment 5 is made to exist It rotates a circle and converts the first silicon rod 101 that operation is processed in completion second to pretreatment position by the second processing position after 360 °, Then, the cable that another mistake is wound during rotating in the forward direction to 360 ° of releases that rotate a circle.

In short, above two rotating manner may achieve essentially identical effect, but the setting of silicon rod conversion equipment still and with This is limited, as long as the silicon rod that can allow to carry out processing operation can be smooth, steady and expeditiously completes every processing operation, then The conversion regime (such as rotation direction and rotational angle etc.) of silicon rod conversion equipment can make other variations.

Certainly, if not considering the risk or set in the second processing district between pretreating zone that above-mentioned cable is excessively wound The problem of setting other components, the silicon rod conversion equipment can also continue to use this unidirectional unlimited rotary mode.

Due to execute silicon rod handling, planar smoothness detection, first processing operation, second processing operation it is aforementioned It is described, details are not described herein.

Herein, think separately to remark additionally, in other alternative embodiments, if silicon rod Multi-position processing machine is additionally arranged Corresponding processing apparatus for work, then the function position on silicon rod processing platform and the silicon rod positioning mechanism on conveying ontology Quantity and its positional relationship are both needed to be adjusted accordingly, subsequent, are being carried out using silicon rod Multi-position processing machine to silicon rod to be processed During multistation is processed, a predetermined angle is rotated to realize that silicon rod is converted in function position using silicon rod conversion equipment Also corresponding adjustment is had.It is assumed that silicon rod Multi-position processing machine is additionally arranged a third processing unit (plant), then, on silicon rod processing platform Also a third processing position can be added and silicon rod conversion equipment also can increase a silicon rod positioning mechanism on conveying ontology.

In specific embodiment, the third processing unit (plant) such as silicon rod burnishing device.The silicon rod burnishing device can On base, for carrying out polishing operation to silicon rod, specific implementation can refer to aforementioned for silicon rod polishing dress The description set.

In an alternative embodiment, the pretreatment position on the silicon rod processing platform, the first processing position, second add Work area position and third processing position are set in sequence, wherein silicon rod handler are correspondingly provided at pretreatment position, first adds Work area position is correspondingly provided with the first processing unit (plant), and the second processing position is correspondingly provided with the second processing unit (plant), and it is corresponding that third processes position Equipped with third processing unit (plant), and, pretreatment position, the first processing position, the second processing position and third processing position are two-by-two In 90 ° of distributions between adjacent, correspondingly, two-by-two for four silicon rod positioning mechanisms on round or circular ring shape conveying ontology Also in 90 ° of distributions between adjacent.

Figure 28 is please referred to, being shown as the application silicon rod Multi-position processing machine is the state signal that four stations are processed in operation Figure.As shown in figure 28, the process for executing the processing of silicon rod multistation can generally comprise: under initial conditions, enable silicon rod handler 2 First silicon rod 101 to be processed is loaded into the pretreatment position of silicon rod processing platform, and at the pretreatment position The first silicon rod 101 pre-processed；Silicon rod conversion equipment 5 is enabled to rotate forward 90 ° so that pretreated first silicon rod 101 will be completed By pre-process position convert to first processing position, enable the first processing unit (plant) 3 to first processing position on the first silicon rod 101 into Row first processes operation, in this stage, enables silicon rod handler 2 that second silicon rod 102 to be processed is loaded into pretreatment position And it is pre-processed；Silicon rod conversion equipment 5 is enabled to rotate forward 90 ° so that the first silicon rod 101 of the first processing operation will be completed by the It converts to the second processing position and pretreated second silicon rod 102 will be completed converted by pre-processing position to the in one processing position One processing position enables the second processing unit (plant) 4 carry out the second processing operation to the first silicon rod 101 on the second processing position, herein Stage enables the first processing unit (plant) 3 carry out the first processing operation to the second silicon rod 102 on the first processing position and silicon rod is enabled to fill Third silicon rod 103 to be processed is loaded into pretreatment position and pre-processed by handler 5；Enable silicon rod conversion equipment 5 positive Rotation 90 ° with will complete second processing operation the first silicon rod 101 by second processing position convert to third processing position and The second silicon rod 102 that operation is processed in completion first is converted by the first processing position to the second processing position and will complete to pre-process Third silicon rod 103 by pre-process position convert to first processing position, enable third processing unit (plant) 8 to third processing position on First silicon rod 101 carries out third and processes operation, in this stage, enables the second processing unit (plant) 4 to the second silicon on the second processing position Stick 102 carries out the second processing operation and the first processing unit (plant) 3 is enabled to carry out first to the third silicon rod 103 on the first processing position It processes operation and enables silicon rod handler 5 that the 4th silicon rod 104 to be processed is loaded into pretreatment position and pre-process；It enables Silicon rod conversion equipment 5 rotates forward 90 ° or 270 ° of backwards rotation will complete the first silicon rod 101 of third processing operation by third It converts to pretreatment position and converts the second silicon rod 102 that operation is processed in completion second by the second processing position in processing position The third silicon rod 103 that operation is processed to third processing position, by completion first is converted by the first processing position to the second processing district Position and will complete pretreated 4th silicon rod 104 by pre-process position convert to first processing position, will pretreatment position on First silicon rod 101 is unloaded.

In view of the cables such as the power supply line laid in the silicon rod Multi-position processing machine or signal wire will not be converted because of silicon rod Device it is excessive rotation and drive those cables excessively wind in turn result in those cables around break.In a specific embodiment, originally The technical solution consideration that application provides limits the maximum rotation angle of the silicon rod conversion equipment, that is, is enabling silicon rod convert May include following two situation during device is converted the first silicon rod 101 to pretreatment position by third processing position:

The first situation is that the rotation angle range of silicon rod conversion equipment 5 is ± 270 °, in particular to makes silicon rod converting means It sets 5 and original position is returned to after 90 ° and 270 ° primary of backwards rotation by rotating forward three times, third processing operation will be completed First silicon rod 101 is converted by third processing position to pretreatment position.This kind of situation bring beneficial effect further include can be whole The internal structure design of a silicon rod Multi-position processing machine provides more flexible design space, such as, it may be considered that in third Processing district to be arranged between pretreating zone other components without regard to hinder silicon rod conversion equipment rotation the case where.

Second situation is that the rotation angle range of the silicon rod conversion equipment is ± 360 °, and silicon rod conversion equipment 5 is made to exist It rotates a circle and converts the first silicon rod 101 for completing third processing operation to pretreatment position by third processing position after 360 °, Then, the cable that another mistake is wound during rotating in the forward direction to 360 ° of releases that rotate a circle.

In short, above two rotating manner may achieve essentially identical effect, but the setting of silicon rod conversion equipment still and with This is limited, as long as the silicon rod that can allow to carry out processing operation can be smooth, steady and expeditiously completes every processing operation, then The conversion regime (such as rotation direction and rotational angle etc.) of silicon rod conversion equipment can make other variations.

Pass through above-mentioned each step, it can be seen that Each performs its own functions for the processing unit (plant) on each processing stations, each processing dress Multiple procedures that are orderly and seamlessly being shifted and automated realization silicon rod processing, form pipelining between setting, Improve the quality of production efficiency and product processing operation.

The principles and effects of the application are only illustrated in above-described embodiment, not for limitation the application.It is any ripe Know the personage of this technology all can without prejudice to spirit herein and under the scope of, carry out modifications and changes to above-described embodiment.Cause This, those of ordinary skill in the art is complete without departing from spirit disclosed herein and institute under technical idea such as At all equivalent modifications or change, should be covered by claims hereof.

Claims (21)

1. a kind of silicon rod Multi-position processing machine characterized by comprising

Base has silicon rod processing platform；

Silicon rod handler, set on the pretreatment position of the silicon rod processing platform, for loading silicon rod to be processed to institute State silicon rod processing platform pretreatment position and will be processed after silicon rod from the pretreatment position of the silicon rod processing platform Unloading；

First processing unit (plant), first set on the silicon rod processing platform processes position, adds for carrying out first to the silicon rod Work industry；

Second processing unit (plant), second set on the silicon rod processing platform processes position, for filling to by first processing The the first post-job silicon rod of processing set carries out the second processing operation；And

Silicon rod conversion equipment, rotary setting on the silicon rod processing platform, for by the silicon rod the pretreatment position, It is converted between first processing position and the second processing position.

2. the silicon rod Multi-position processing machine stated according to claim 1, which is characterized in that the silicon rod handler includes:

Silicon rod loads and unloads position, equipped with the silicon rod plummer for erectting placement for carrying the silicon rod；

Commutate carrier, for making commutation movement；And

Silicon rod clamper, set on the first mounting surface of the commutation carrier；

Wherein, by driving the commutation carrier to make commutation movement, so that the silicon rod clamper of the commutation carrier is in the silicon rod It loads and unloads and converts between position and the pretreatment position to transfer the silicon rod.

3. the silicon rod Multi-position processing machine stated according to claim 2, which is characterized in that the silicon rod clamper includes:

Fixture installation part is set on the commutation carrier；And

At least two silicon rod clamping pieces are arranged along the fixture installation part spacing；Each described silicon rod clamping piece includes:

Clamp arm mounting base is set on the fixture installation part；

At least two clamp arm are movably arranged in the clamp arm mounting base；And

Clamp arm driving mechanism, for driving at least two clamp arm to make opening and closing movement.

4. silicon rod Multi-position processing machine according to claim 3, which is characterized in that in at least two silicon rods clamping piece At least one silicon rod clamping piece be equipped with guiding driving mechanism, for driving it along fixture installation part movement, to adjust The spacing of at least two silicon rod clamping piece.

5. silicon rod Multi-position processing machine according to claim 4, which is characterized in that the silicon rod handler further include: Height testing instrument is set on the commutation carrier, for detecting the height of the silicon rod.

6. silicon rod Multi-position processing machine according to claim 2, which is characterized in that further include flatness detector, be set to Second mounting surface of the commutation carrier, for carrying out planar smoothness detection to the silicon rod.

7. silicon rod Multi-position processing machine according to claim 6, which is characterized in that the flatness detector includes:

Contact measurement structure；

Detector shift mechanism；And

Controller is detected, is connect with the contact measurement structure and the detector shift mechanism, for controlling the detection Instrument shift mechanism drives the contact measurement structural shift and the control contact measurement structure sequentially to detect the silicon In stick on tested surface each test point relative distance.

8. silicon rod Multi-position processing machine according to claim 1, which is characterized in that the silicon rod conversion equipment includes:

The conveying ontology of disc or circular ring shape；

Silicon rod positioning mechanism is set on the conveying ontology, for positioning to the silicon rod；And

Driving mechanism is converted, is turned for driving the conveying ontology to rotate with the silicon rod for driving the silicon rod positioning mechanism to be positioned Change place.

9. silicon rod Multi-position processing machine according to claim 8, which is characterized in that the silicon rod positioning mechanism includes:

Plummer is rotated, on the conveying ontology of the disc or circular ring shape, for carrying the silicon rod；

Rotary compacting device is relatively arranged on the top of the rotation plummer, for compressing the silicon rod；

Lifting drive, for driving the rotary compacting device to make elevating movement along the vertical direction；And

Rotation drive device, for driving the rotary compacting device and the rotary compacting device being driven to rotate.

10. silicon rod Multi-position processing machine according to claim 1, which is characterized in that first processing unit (plant) includes:

First rack；And

At least a pair of first grinding tool is arranged oppositely in first rack, for the silicon rod being located at the first processing position Silicon rod on conversion equipment carries out the first processing operation.

11. silicon rod Multi-position processing machine according to claim 10, which is characterized in that first grinding tool includes:

First main shaft；And

At least one first grinding wheel is set to the operation end of first main shaft；First grinding wheel has the first of the first granularity Frosted particle.

12. silicon rod Multi-position processing machine according to claim 1, which is characterized in that second processing unit (plant) includes:

Second rack；And

At least a pair of second grinding tool is arranged oppositely in second rack, for the silicon rod being located at the second processing position Silicon rod on conversion equipment carries out the second processing operation.

13. silicon rod Multi-position processing machine according to claim 12, which is characterized in that second grinding tool includes:

Second main shaft；And

At least one second grinding wheel is set to the operation end of second main shaft；Second grinding wheel has the second of the second granularity Frosted particle.

14. silicon rod Multi-position processing machine according to claim 1, which is characterized in that further include protective door, for that will locate in advance Reason position is isolated with the first processing position and second processing position.

15. silicon rod Multi-position processing machine according to claim 1, which is characterized in that pre- on the silicon rod processing platform Processing position, the first processing position and the second processing position are in 120 ° of distributions, the rotation of the silicon rod conversion equipment between any two Gyration range is ± 240 °.

16. silicon rod Multi-position processing machine according to claim 1, which is characterized in that further include third processing unit (plant), be set to The third of the silicon rod processing platform processes position；Pretreatment position on the silicon rod processing platform, the first processing position, the Two processing positions and third processing district it is adjacent two-by-two between in 90 ° of distributions, the rotation angle range of the silicon rod conversion equipment It is ± 270 °.

17. according to claim 1, silicon rod Multi-position processing machine described in 15 or 16, it is characterised in that:

The rotation angle range of the silicon rod conversion equipment is ± 360 °；Or

The silicon rod conversion equipment uses unidirectional unlimited rotary mode.

18. a kind of silicon rod multiplexing position processing method, which comprises the following steps:

Enable silicon rod handler that the first silicon rod to be processed is loaded into the pretreatment position of silicon rod processing platform, and to positioned at institute The first silicon rod at pretreatment position is stated to be pre-processed；

Pretreated first silicon rod will be completed by the conversion of pretreatment position to rotate the first predetermined angle by enabling silicon rod conversion equipment To the first processing position；The first processing unit (plant) is enabled to carry out the first processing operation to the first silicon rod on the first processing position, herein Stage enables silicon rod handler that the second silicon rod to be processed is loaded into pretreatment position and pre-processes；And

Silicon rod conversion equipment is enabled to rotate the second predetermined angle so that the first silicon rod of the first processing operation will be completed by the first processing district Position conversion processes position and will complete pretreated second silicon rod and converted by pre-processing position to the first processing position to second； It enables the second processing unit (plant) carry out the second processing operation to the first silicon rod on the second processing position and enables the first processing in this stage Device carries out the first processing operation to the second silicon rod on the first processing position and enables silicon rod handler by be processed the Three silicon rods are loaded into pretreatment position and are pre-processed.

19. silicon rod multiplexing position processing method according to claim 18, which is characterized in that on the silicon rod processing platform Pretreatment position, the first processing position and the second processing position are in 120 ° of distributions between any two；When according to the pretreating zone When the trend of the sequence of position, the first processing position and the second processing position is defined as forward direction, silicon rod conversion equipment is enabled to rotate The first predetermined angle be rotate forward 120 °；Enabling silicon rod conversion equipment rotate the second predetermined angle is to rotate forward 120 °.

20. silicon rod multiplexing position processing method according to claim 18, which is characterized in that further comprise the steps of:

Silicon rod conversion equipment rotation third predetermined angle is enabled so that the first silicon rod of the second processing operation will be completed by the second processing district Position, which converts extremely pretreatment position and converts the second silicon rod that operation is processed in completion first to second by the first processing position, to be added Work area position and will complete pretreated third silicon rod by pre-process position convert to first processing position；Enable silicon rod handler will The first silicon rod on pretreatment position carries out unloading and the 4th silicon rod to be processed is loaded into pretreatment position and to being located at The 4th silicon rod at the pretreatment position is pre-processed, and in this stage, enables the second processing unit (plant) on the second processing position The second silicon rod carry out the second processing operation and the first processing unit (plant) enabled to carry out the to the third silicon rod on the first processing position One processing operation.

21. silicon rod multiplexing position processing method according to claim 20, which is characterized in that on the silicon rod processing platform Pretreatment position, the first processing position and the second processing position are in 120 ° of distributions between any two；When according to the pretreating zone When the trend of the sequence of position, the first processing position and the second processing position is defined as forward direction, described enables silicon rod converting means The first predetermined angle for setting rotation is to rotate forward 120 °；Described enables silicon rod conversion equipment rotate the second predetermined angle as forward direction 120 ° of rotation；The silicon rod conversion equipment rotation third predetermined angle that enables is to rotate forward 120 ° or 240 ° of backwards rotation.