CN217196245U - Flaw-piece discharging device, silicon rod squaring machine and silicon rod cutting and grinding all-in-one machine - Google Patents

Abstract

The application discloses flaw-piece discharge apparatus, silicon rod squaring machine and silicon rod surely grind all-in-one, flaw-piece discharge apparatus includes: the flaw-piece jacking mechanism is used for jacking the flaw-pieces; and the flaw-piece lifting unit is used for lifting the flaw-piece so that the top end of the flaw-piece protrudes out of the cut silicon rod. In this application flaw-piece discharge apparatus, utilize the flaw-piece to push up and hold in the palm mechanism, can push up and hold the flaw-piece that produces after cutting device treats the silicon rod of cutting and carries out the evolution cutting operation, avoid the flaw-piece to take place relative displacement with the silicon rod that has cut, prevent that the condition that the cutting coping saw among the cutting device appears collapsing the limit when wearing out the silicon rod that treats cutting, utilize the flaw-piece hoisting unit, can make the relative silicon rod that has cut of the flaw-piece that forms after the evolution of cutting displacement, make the top protrusion of flaw-piece in the silicon rod that has cut, be favorable to unloading of flaw-piece.

Description

Flaw-piece discharging device, silicon rod squaring machine and silicon rod cutting and grinding all-in-one machine

Technical Field

The application relates to the technical field of silicon workpiece processing, in particular to a flaw-piece discharging device, a silicon rod squaring machine and a silicon rod cutting and grinding all-in-one machine.

Background

At present, with the importance and the openness of the society on the utilization of green renewable energy sources, the field of photovoltaic solar power generation is more and more valued and developed. In the field of photovoltaic power generation, conventional crystalline silicon solar cells are fabricated on high quality silicon wafers that are cut and subsequently processed by multi-wire saw from a pulled or cast silicon ingot.

In the conventional silicon wafer manufacturing process, taking a single crystal silicon product as an example, the general working procedures may include: firstly, a silicon rod cutting machine is used for cutting the original long silicon rod to form a plurality of sections of short silicon rods; after the cutting is finished, cutting the cut short silicon rods by using a silicon rod cutting machine to form silicon rods with rectangular-like cross sections; then grinding the cut silicon rod to achieve the surface shaping of the silicon rod to meet the requirements of corresponding flatness and dimensional tolerance; and subsequently, slicing the silicon rod to obtain a silicon wafer.

In the related silicon rod cutting and squaring operation, a flaw-piece is formed after the silicon rod is subjected to squaring and cutting. In some cases, the design has certain problems because the lower position of the flaw-piece to be generated by the silicon rod to be cut has no corresponding support: the cutting wire saw in the cutting unit is broken due to the edge skin when finally penetrating out of the silicon rod to be cut; after a silicon rod to be cut on a rotary bearing table in a cutting area finishes an evolution cutting operation, the flaw-piece generated after cutting is likely to have risks of falling or overturning and the like because of no corresponding support; in addition, most of the flaw-piece discharging methods still have the flaw-pieces separated from the cut silicon rods and removed from the silicon rod extracting equipment by manual operation of operators, so that the efficiency is low, the flaw-pieces collide with the cut silicon rods in the conveying process to increase the risk of damage to the cut silicon rods, and the flaw-pieces are difficult to recycle.

Disclosure of Invention

In view of the above-mentioned various shortcomings of the related art, the present application aims to disclose a flaw-piece discharging device, a silicon rod squaring machine and a silicon rod cutting and grinding all-in-one machine, which are used for solving the problems of silicon rod breakage, low efficiency and the like in the silicon rod cutting in the prior art.

In order to achieve the above and other related objects, a first aspect of the present application discloses a flaw-piece discharging device for use in a silicon rod processing apparatus, the silicon rod processing apparatus including a base, a cutting device, and a silicon rod transfer device, the cutting device including a movably disposed cutting unit, the cutting unit having at least one cutting wire saw for forming a cut silicon rod and a flaw-piece after cutting the silicon rod to be cut; the silicon rod discharge apparatus includes: the flaw-piece jacking mechanism is used for jacking the flaw-pieces; a flaw-piece lifting unit for lifting a flaw-piece so that the flaw-piece tip protrudes out of the cut silicon rod.

In certain embodiments of the first aspect of the present application, the flaw-piece jacking mechanism comprises: the jacking component is provided with at least one jacking rod; and the jacking driving unit is used for driving at least one jacking rod in the jacking assembly to do lifting motion.

In certain embodiments of the first aspect of the present application, the jacking assembly comprises: the ejector rod seat is provided with a hollow accommodating space and an ejector rod hole; at least one ejector rod is arranged in the accommodating space of the ejector rod seat in a liftable mode through the ejector rod hole.

In certain embodiments of the first aspect of the present application, the top rod has a stressed bottom end and a top-supporting end, wherein the top-supporting end penetrates through the top rod hole, and the stressed bottom end drives the top-supporting end to move up and down relative to the top rod base after being stressed.

In certain embodiments of the first aspect of the present application, the jacking end of the jacking leg is further provided with a cushioning structure.

In certain embodiments of the first aspect of the present application, the jacking assembly further comprises: the elastic piece is sleeved on the ejector rod and positioned between the ejector rod and the ejector rod seat.

In certain embodiments of the first aspect of the present application, the resilient member comprises a compression spring.

In certain embodiments of the first aspect of the present application, the jacking drive unit comprises a driving cylinder or a driving hydraulic cylinder with a telescopic rod associated with the stressed bottom end of the jacking leg.

In certain embodiments of the first aspect of the present application, an action angle is provided between the axis of the telescopic rod and the axis of the ejector rod, and the action end of the telescopic rod and the stressed bottom end of the ejector rod are in a wedge-shaped configuration.

In some embodiments of the first aspect of this application, the atress bottom of ejector pin is designed for wedge structure perhaps a voussoir has been added to the atress bottom of ejector pin, the effect end of telescopic link is designed for wedge structure perhaps a voussoir has been added to the effect end of telescopic link, wherein, the wedge structure of the atress bottom of ejector pin or the wedge face with the wedge structure of the effect end of telescopic link or the wedge face of voussoir correspond the cooperation.

In certain embodiments of the first aspect of the present application, the pelt lifting unit is fixedly attached to the unit and comprises: the jacking piece is driven by the telescopic component to do telescopic motion.

In certain embodiments of the first aspect of the present application, the flaw-piece discharge apparatus further comprises a flaw-piece stabilizing unit comprising a support assembly and a drive member coupled to the support assembly.

In certain embodiments of the first aspect of the present application, the support assembly includes a mounting member and a curb stop disposed on the mounting member.

In certain embodiments of the first aspect of the present application, the mounting member includes a fixed portion and a movable portion movably coupled to the fixed portion, and the curb stop is disposed on the movable portion.

In certain embodiments of the first aspect of the present application, the edge skin barrier comprises an edge skin barrier wheel.

In certain embodiments of the first aspect of the present application, the contact portion of the edge dam wheel with the edge is provided with a slope or a circular arc.

In certain embodiments of the first aspect of the present application, the drive member comprises a drive cylinder or a drive hydraulic cylinder with a telescopic rod connected to a movable portion in the mounting member.

In certain embodiments of the first aspect of the present application, the flaw-piece discharging device further comprises a wire pulling mechanism disposed on the cutting unit for pulling the cutting wire saw to expand outward to avoid interference between the cutting wire saw and the cut silicon rod.

In certain embodiments of the first aspect of the present application, the flaw-piece discharging apparatus further comprises a flaw-piece transporting unit for transporting the flaw-piece away from the cutting zone and discharging the flaw-piece.

The present application discloses in a second aspect a silicon rod squarer, comprising: the base is provided with a silicon rod processing platform; the silicon rod processing platform comprises a cutting zone; the cutting device is arranged at a cutting position of the silicon rod processing platform; the cutting device comprises a movably arranged cutting unit, and the cutting unit is provided with at least one cutting wire saw; a flaw-piece discharge device as described above.

The third aspect of the present application discloses a silicon rod surely grinds all-in-one, includes: the base is provided with a silicon rod processing platform; the silicon rod processing platform comprises a cutting zone and a grinding zone; the cutting device is arranged at a cutting position of the silicon rod processing platform; the cutting device comprises a movably arranged cutting unit, and the cutting unit is provided with at least one cutting wire saw; a flaw-piece discharge device as described above; the grinding device is arranged at a grinding zone bit of the silicon rod processing platform; the grinding device comprises a movably arranged grinding tool; and the silicon rod conversion device is arranged on the silicon rod processing platform and used for bearing a silicon rod and converting the silicon rod among the functional regions.

The utility model discloses a flaw-piece discharge apparatus, silicon rod evolution machine and silicon rod surely grind all-in-one in the flaw-piece discharge apparatus, utilize the flaw-piece to push up and hold mechanism, can push up and hold the flaw-piece that produces after cutting device treats the silicon rod of cutting and carries out evolution cutting operation, avoid the flaw-piece to take place relative displacement with the silicon rod of cutting, prevent that the condition that the cutting coping saw among the cutting device from appearing collapsing the limit when wearing out the silicon rod of treating cutting, utilize the flaw-piece hoisting unit, can make the relative silicon rod of cutting of the flaw-piece that has formed after the cutting evolution and make the displacement that rises, make the top protrusion of flaw-piece in the silicon rod of cutting, be favorable to unloading of flaw-piece, the efficiency of unloading of flaw-piece has been improved, and the damage of flaw-piece and silicon rod has been avoided.

Drawings

The specific features of the invention to which this application relates are set forth in the appended claims. The features and advantages of the invention to which this application relates will be better understood by reference to the exemplary embodiments described in detail below and the accompanying drawings. The brief description of the drawings is as follows:

fig. 1 is a perspective view of a silicon rod slicing and grinding all-in-one machine according to an embodiment of the present application.

Fig. 2 shows a top view of the silicon rod slicing and grinding all-in-one machine of the present application in one embodiment.

Fig. 3 to 5 are schematic views showing the structure of a silicon rod carrying body in the silicon rod loading and unloading device according to an embodiment of the present invention.

Fig. 6 to 8 are schematic structural views of the silicon rod handling device according to the present application in different turning states in one embodiment.

Fig. 9 is a top view of a cutting device in a silicon rod slicing and grinding machine according to an embodiment of the present application.

Fig. 10 is a perspective view of a silicon rod slicing and grinding all-in-one machine according to the present application in another embodiment.

Fig. 11 is a top view of a silicon rod slicing and grinding all-in-one machine according to the present application in another embodiment.

Fig. 12 is a schematic view of a cutting device in a silicon rod cutting and grinding all-in-one machine according to another embodiment of the invention.

Fig. 13 is a top view of a cutting device in a silicon rod slicing and grinding all-in-one machine according to the present application in another embodiment.

Fig. 14 is a schematic view showing an application of the flaw-piece jacking mechanism in the silicon rod unloading device of the silicon rod slicing and grinding all-in-one machine according to an embodiment of the present invention.

Fig. 15 is a top view of fig. 14.

Fig. 16 is a schematic structural view illustrating a flaw-piece jacking mechanism in a silicon rod unloading device of the silicon rod slicing and grinding integrated machine according to the present application in one embodiment.

Fig. 17 is a schematic structural view of a flaw-piece lifting unit in the silicon rod unloading device of the silicon rod slicing and grinding integrated machine according to an embodiment of the present invention.

Figure 18 shows a schematic view of the construction of the pelt lifting unit of figure 17,

fig. 19 is a schematic view showing the structure of a stabilizing unit in a silicon rod unloading device in a silicon rod slicing and grinding all-in-one machine according to an embodiment of the present invention.

Fig. 20 is a top view of fig. 19.

Detailed Description

The following description of the embodiments of the present application is provided for illustrative purposes, and other advantages and capabilities of the present application will become apparent to those skilled in the art from the present disclosure.

In the following description, reference is made to the accompanying drawings that describe several embodiments of the application. It is to be understood that other embodiments may be utilized and that mechanical, structural, electrical, and operational changes may be made without departing from the spirit and scope of the present disclosure. The following detailed description is not to be taken in a limiting sense, and the scope of embodiments of the present application is defined only by the claims of the issued patent. The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the application. Spatially relative terms, such as "upper," "lower," "left," "right," "lower," "below," "lower," "above," "upper," and the like, may be used herein to facilitate describing one element or feature's relationship to another element or feature as illustrated in the figures.

Although the terms first, second, etc. may be used herein to describe various elements or parameters in some instances, these elements or parameters should not be limited by these terms. These terms are only used to distinguish one element or parameter from another element or parameter. For example, the first form silicon rods may be referred to as second form silicon rods, and similarly, the second form silicon rods may be referred to as first form silicon rods, and the first placement state may be referred to as a second placement state, and similarly, the second placement state may be referred to as a first placement state, without departing from the scope of the various described embodiments.

Also, as used herein, the singular forms "a", "an" and "the" are intended to include the plural forms as well, unless the context indicates otherwise. It will be further understood that the terms "comprises," "comprising," "includes" and/or "including," when used in this specification, specify the presence of stated features, steps, operations, elements, components, items, species, and/or groups, but do not preclude the presence, or addition of one or more other features, steps, operations, elements, components, species, and/or groups thereof. The terms "or" and/or "as used herein are to be construed as inclusive or meaning any one or any combination. Thus, "A, B or C" or "A, B and/or C" means "any of the following: a; b; c; a and B; a and C; b and C; A. b and C ". An exception to this definition will occur only when a combination of elements, functions, steps or operations are inherently mutually exclusive in some way.

In the related art for processing a silicon rod, several steps such as cutting, grinding, rounding, chamfering, and the like are involved.

Generally, most of conventional silicon rods have a cylindrical structure, and are cut by a silicon rod cutting device so that the silicon rods have a quasi-rectangular (including a quasi-square) cross section after cutting, while the cut silicon rods have a quasi-rectangular (including a quasi-cubic) shape as a whole. The quasi-rectangle comprises a rectangle with adjacent sides orthogonal or included angles within a preset angle range, a rectangle with round corners between the adjacent sides, a rectangle with short connecting edges between the adjacent sides, and the like.

Taking a single crystal silicon rod as an example, in some related technologies, a process for forming the single crystal silicon rod may include: firstly, a silicon rod cutting machine is used for cutting the original long silicon rod to form a plurality of sections of short silicon rods; and after the cutting is finished, cutting the short silicon rod by using a silicon rod cutting machine to form the single crystal silicon rod with the rectangular-like cross section. Among them, patent publications such as CN105856445A, CN105946127A, and CN105196A can be referred to as a specific embodiment of forming a multi-stage short silicon rod by cutting an original long silicon rod with a silicon rod cutting machine, and patent publication such as CN105818285A can be referred to as a specific embodiment of forming a single crystal silicon rod having a rectangular-like cross section by cutting a short silicon rod with a silicon rod squarer. However, the process for forming the single crystal silicon rod is not limited to the foregoing technique, and in alternative examples, the process for forming the single crystal silicon rod may further include: firstly, using a full silicon rod squaring machine to perform squaring operation on an original long silicon rod to form a long monocrystalline silicon rod with a quasi-rectangular cross section; and after the cutting is finished, cutting off the cut long monocrystalline silicon rod by using a silicon rod cutting machine to form a short crystalline silicon rod. Among them, a specific embodiment of the above-described method for forming a long single crystal silicon rod having a substantially rectangular shape by squaring an initial long silicon rod using an all-silicon-rod squarer is disclosed in patent publication CN003443A, for example.

After the cylindrical silicon single crystal rod is cut by the squaring equipment to form the silicon rod with the rectangular-like cross section, the grinding equipment can be used for performing surface grinding, rounding/chamfering and other operations on the rectangular-like silicon rod. For a specific implementation manner of the grinding device for performing operations such as surface grinding, rounding and chamfering on the quasi-rectangular silicon rod, reference may be made to patent publication CN105835247A and the like.

The inventor of the present application finds that, in the related processing operation technology for silicon rods, taking the operation of extracting silicon rods as an example, processing silicon rods of different shapes and silicon rods of different placement manners is often involved, for example, a silicon rod to be processed needs to be loaded into a silicon rod processing device and a processed silicon rod needs to be unloaded from the silicon rod processing device, and a placement state of the silicon rod needs to be adjusted in the process of transferring the silicon rod, so as to achieve these functions at the same time, which increases the design difficulty of a silicon rod handling device, for example, some silicon rod handling devices may design two sets of silicon rod conversion devices, or more manual work is needed.

In view of the above, the present application provides a silicon rod handling device, a silicon rod squaring machine, a silicon rod cutting and grinding all-in-one machine, and a silicon rod processing method, wherein the silicon rod handling device includes a base and a supporting body, the supporting body is arranged on the base in a turnable manner through a turnover mechanism, and the supporting body includes a supporting seat, a first supporting member arranged on the supporting seat and used for supporting a first shape silicon rod, a second supporting member arranged on the supporting seat and used for supporting a second shape silicon rod, and a bottom supporting member; the supporting body is turned relative to the base through the turning mechanism so as to convert the borne first-form silicon rod or second-form silicon rod between a first placing state and a second placing state, so that loading operation of the silicon rod to be processed and unloading operation of the processed silicon rod can be realized simultaneously, the whole device is simple in structure, working efficiency is improved, and cost is saved.

The silicon rod handling device can be applied to silicon rod processing equipment, and the silicon rod processing equipment can at least carry out corresponding processing operation on a silicon rod.

In some embodiments, the silicon rod processing apparatus is a silicon rod squarer, and includes at least one cutting device, by which the silicon rod can be squared and cut, so that the silicon rod with a circular cross section originally forms a silicon rod with a quasi-rectangular cross section after being squared and cut.

In some embodiments, the silicon rod processing apparatus is a silicon rod cutting and grinding integrated machine, and includes at least one cutting device and at least one silicon rod grinding device, the silicon rod can be cut and processed by the at least one cutting device, so that the silicon rod with the original circular cross section can be cut and processed by the cutting and processing to form a silicon rod with a quasi-rectangular cross section, and the silicon rod grinding device can be used for grinding, such as surface grinding, rounding/chamfering, etc., on the cut and processed silicon rod.

In the embodiments provided herein, a three-dimensional space defined by a first direction, a second direction, and a third direction is defined for defining the direction and the operation mode between different structures, the first direction, the second direction, and the third direction are all linear directions and are mutually perpendicular to each other, wherein the first direction and the second direction may form a horizontal plane, and the third direction is a vertical direction perpendicular to the horizontal plane, which may also be referred to as a vertical direction, a weight line direction, an up-down direction, or a lifting direction.

In any of the embodiments provided herein, the ends of the silicon rod refer to two ends that are opposite along the length direction of the silicon rod, and the end surfaces of the ends refer to two surfaces that are opposite along the length direction of the silicon rod. For example, two end surfaces of a silicon rod to be processed are circular or similar to circular, and the side surface of the silicon rod is an arc surface; in the case of a processed silicon rod (for example, square cutting, grinding, etc.), the two ends of the silicon rod are rectangular or quasi-rectangular, i.e. the sides of the silicon rod, i.e. the four sides of the silicon rod in the longitudinal direction, which are generally rectangular.

The silicon rod handling device of the present application may be applied to a silicon rod processing apparatus, which may be, for example, a silicon rod squarer, a silicon rod cutting and grinding all-in-one machine, but not limited thereto, and in other embodiments, the silicon rod processing apparatus may also include a silicon rod cutting machine, a silicon rod grinding machine, and the like.

In an embodiment, the silicon rod may be, for example, a single crystal silicon rod, i.e., a rod-shaped single crystal silicon grown from a melt by using a czochralski method or a suspension float zone method, such as a single crystal silicon rod with a length of about 5000mm (e.g., a specification of 5360mm, etc.) or a single crystal silicon rod with a length of about 800mm, which is commonly used in silicon rod processing, or a polysilicon rod, i.e., a silicon rod with silicon deposited on the surface of a silicon core wire by using a deposition technique, such as a chemical vapor deposition technique, but is not limited thereto.

Referring to fig. 1 and 2, fig. 1 is a perspective view of an embodiment of a silicon rod slicing and grinding machine of the present application, and fig. 2 is a top view of the embodiment of the silicon rod slicing and grinding machine of the present application. As shown in fig. 1 and fig. 2, the silicon rod cutting and grinding all-in-one machine of the present application comprises: a machine base 1, a cutting device 2, a silicon rod grinding device 3, a silicon rod conversion device 4 and a silicon rod loading and unloading device 5.

The silicon rod processing apparatus of the present application will be described in detail below.

The base serves as a main body part of the silicon rod slicing and grinding all-in-one machine and is used for providing a silicon rod processing platform, and in some examples, the size and the weight of the base are large so as to provide a large mounting surface and firm stability of the whole machine. It should be understood that the machine base can be used as a seat body for different structures or components for performing processing operation in the silicon rod slicing and grinding all-in-one machine, and the specific structure of the machine base can be changed based on different functional requirements or structural requirements. In some examples, the machine base comprises a fixing structure or a limiting structure, such as a base, a rod body, a column body, a frame body and the like, which are used for receiving different parts in the silicon rod cutting and grinding all-in-one machine.

Also, in some examples, the housing may be a unitary base, and in some examples, the housing may include a plurality of separate bases.

The machine base is provided with a silicon rod processing platform, and the silicon rod processing platform can be divided into a plurality of functional areas according to the specific operation content of silicon rod processing operation. For example, the silicon rod processing platform comprises at least a waiting section, a cutting section and a grinding section. It should be noted that, in each example provided herein, the functional zone is defined by a stroke path and a range of the processing device at the functional zone, for example, the cutting device of the silicon rod cutting and grinding all-in-one machine is disposed at the cutting zone, and the range of the cutting zone is a range occupied by the cutting device in the process of completing the cutting operation; similarly, the grinding device of the silicon rod cutting and grinding all-in-one machine is arranged at the grinding position, and the range of the grinding position is the range occupied by the grinding device in the process of finishing the grinding operation. The shape of the silicon rod processing platform can be determined according to the machine base or can be determined according to the processing requirements of the machine base and the cutting device and the grinding device together. In the embodiment shown in fig. 1 and 2, a silicon rod processing platform is provided on the machine base 1, and the silicon rod processing platform is provided with functional zones such as a waiting zone, a cutting zone and a grinding zone. And the cutting position is provided with a cutting device for performing squaring and cutting operation on the silicon rod positioned at the cutting position so as to form the silicon rod with a rectangular-like section. And the grinding zone is provided with a grinding device for grinding the silicon rod positioned at the grinding zone.

The silicon rod conversion device is arranged on a silicon rod processing platform of the base and used for transferring the silicon rod, for example, the silicon rod conversion device can be used for converting the position of the silicon rod on each functional area. In the embodiment shown in fig. 1 and 2, a silicon rod transfer device 4 is provided in a central region of the silicon rod processing platform for transferring a silicon rod between a waiting zone, a cutting zone and a grinding zone on the silicon rod processing platform. The silicon rod transfer device further comprises a transfer body 41, a plurality of silicon rod positioning mechanisms disposed on the transfer body, and a transfer driving mechanism (not shown in the drawings). The silicon rod positioning mechanisms are arranged on the conversion main body and used for positioning the silicon rods, wherein the positioning center lines corresponding to the silicon rod positioning mechanisms are consistent with the plumb line, and it should be understood that the silicon rods positioned by the silicon rod positioning mechanisms are in a vertical state under the arrangement. Of course, in other embodiments, the positioning center lines of the plurality of silicon rod positioning mechanisms disposed on the conversion body are aligned with the horizontal line, and it should be understood that in this configuration, the silicon rods positioned by the silicon rod positioning mechanisms are in a horizontal state.

The conversion body can be arranged in the central area of the silicon rod processing platform, and each side surface of the conversion body can be used as a mounting surface for mounting a plurality of silicon rod positioning mechanisms. In the embodiment shown in fig. 1 and 2, silicon rod positioning means are mounted on each side of the conversion body 41, each of which can position at least one silicon rod. In a specific implementation manner, the conversion body is in a shape of a disk, a circular ring, a square disk or the like. The number of the silicon rod positioning mechanisms arranged on the conversion main body can be changed differently according to the layout of the silicon rod cutting and grinding all-in-one machine.

The conversion main body is driven by the conversion driving mechanism to enable the silicon rod positioning mechanism arranged on the conversion main body to be switched among different functional areas, so that the silicon rod positioned by the silicon rod positioning mechanism can be switched among different functional areas, and different processing procedures such as squaring, cutting and grinding can be completed on the silicon rod. Meanwhile, the silicon rod positioning mechanisms arranged on the conversion main body can be respectively positioned at different function regions, so that the silicon rods positioned by the different silicon rod positioning mechanisms can respectively perform corresponding processing procedures at different function regions at the same time, for example, a cutting device and a grinding device in the silicon rod cutting and grinding all-in-one machine can be simultaneously in a working state, and the processing efficiency can be improved.

For example, in certain embodiments, the silicon rod processing platform may comprise two functional zones, such as: a first functional zone and a second functional zone. In order to be adapted to these functional regions, the number of silicon rod positioning means on the conversion body may be two, and each silicon rod positioning means may position at least one silicon rod. Further, the angle provided between the two silicon rod positioning means also corresponds to the angular distribution between the two functional zones. Thus, when a certain silicon rod positioning mechanism corresponds to a certain functional zone, inevitably, another silicon rod positioning mechanism also corresponds to another functional zone. Thus, in the pipelining operation, when at least one silicon rod is positioned on each silicon rod positioning mechanism and the silicon rod positioning mechanisms correspond to the functional regions, the silicon rods are positioned at the corresponding functional regions to perform corresponding processing operations, for example: the silicon rod in the first functional area can be subjected to first processing operation, and the silicon rod in the second functional area can be subjected to second processing operation.

In certain embodiments, the silicon rod processing platform may comprise three functional zones, for example: a first function zone bit, a second function zone bit and a third function zone bit, or two first function zone bits and a second function zone bit; alternatively, a first functional zone and two second functional zones. In order to be adapted to these functional regions, the number of silicon rod positioning means on the conversion body can be three, and each silicon rod positioning means can position at least one silicon rod. Further, the angles set between every two silicon rod positioning mechanisms are consistent with the angle distribution between every two silicon rod positioning mechanisms at the three function areas. Thus, when one silicon rod positioning mechanism corresponds to one functional zone, inevitably, the other two silicon rod positioning mechanisms also correspond to the other two functional zones. Thus, in the pipelining operation, when at least one silicon rod is positioned on each silicon rod positioning mechanism and the silicon rod positioning mechanisms correspond to the functional regions, the silicon rods are positioned at the corresponding functional regions to perform corresponding processing operations, for example: the silicon rod at the first functional area can be subjected to first processing operation, the silicon rod at the second functional area can be subjected to second processing operation, and the silicon rod at the third functional area can be subjected to third processing operation; or, the silicon rods positioned in the two first functional areas can be subjected to first processing operation, and the silicon rods positioned in the second functional area can be subjected to second processing operation; alternatively, the silicon rod located in a first functional region may be subjected to a first processing operation, and the silicon rod located in two second functional regions may be subjected to a second processing operation. In an alternative example, the first functional region, the second functional region and the third functional region on the silicon rod processing platform are arranged at 120 ° with respect to one another, so that correspondingly, the three silicon rod positioning means on the changeover body are also arranged at 120 ° with respect to one another. Of course, the number of the silicon rod positioning mechanisms may vary according to actual requirements, but is not limited thereto, for example, the number of the silicon rod positioning mechanisms may be determined according to the number of the functional regions arranged on the silicon rod processing platform.

In certain embodiments, the silicon rod processing platform comprises four functional zones, for example: a first functional zone bit, a second functional zone bit, a third functional zone bit, and a fourth functional zone bit, or, two first functional zone bits and two second functional zone bits, or, two first functional zone bits, a second functional zone bit, and a third functional zone bit, or, a first functional zone bit, two second functional zone bits, and a third functional zone bit, or, a first functional zone bit, a second functional zone bit, and two third functional zone bits. In order to be adapted to these functional areas, the number of silicon rod positioning mechanisms on the conversion body can be four, and each silicon rod positioning mechanism can position at least one silicon rod. Further, the angle set between two adjacent silicon rod positioning mechanisms in the four silicon rod positioning mechanisms is consistent with the angle distribution between two adjacent functional regions in the four functional regions. Thus, when a certain silicon rod positioning mechanism corresponds to a certain functional zone, inevitably, other three silicon rod positioning mechanisms also correspond to other three functional zone respectively. Thus, in the pipelining operation, when at least one silicon rod is positioned on each silicon rod positioning mechanism and the silicon rod positioning mechanisms correspond to the functional regions, the silicon rods are positioned at the corresponding functional regions to perform corresponding processing operations, for example: the silicon rod in the first functional area can be subjected to first processing operation, the silicon rod in the second functional area can be subjected to second processing operation, the silicon rod in the third functional area can be subjected to third processing operation, and the silicon rod in the fourth functional area can be subjected to fourth processing operation; or the silicon rods positioned in the two first functional areas can be subjected to first processing operation, and the silicon rods positioned in the two second functional areas can be subjected to second processing operation; or, the silicon rods positioned in the two first function areas can be subjected to first processing operation, the silicon rods positioned in the second function area can be subjected to second processing operation, and the silicon rods positioned in the third function area can be subjected to third processing operation; or, the silicon rod in the first functional area can be subjected to first processing operation, the silicon rods in the two second functional areas can be subjected to second processing operation, and the silicon rod in the third functional area can be subjected to third processing operation; alternatively, the silicon rods located in a first functional zone may be subjected to a first processing operation, the silicon rods located in a second functional zone may be subjected to a second processing operation, and the silicon rods located in two third functional zones may be subjected to a third processing operation. In an alternative embodiment, two adjacent functional regions of the four functional regions on the silicon rod processing platform are arranged at 90 °, so that correspondingly, two of the four silicon rod positioning means on the conversion body are also arranged at 90 °. Of course, the number of the silicon rod positioning mechanisms may vary according to actual requirements, but is not limited thereto, for example, the number of the silicon rod positioning mechanisms may be determined according to the number of the functional regions arranged on the silicon rod processing platform.

In the embodiment as shown in fig. 1 and 2, the silicon rod processing platform may comprise four functional zones, for example, a waiting zone, a first cutting zone, a second cutting zone and a milling zone, which are distributed at 90 ° between each other, i.e. the waiting zone is 90 ° different from the first cutting zone, the first cutting zone is 90 ° different from the second cutting zone, the second cutting zone is 90 ° different from the milling zone, and the milling zone is 90 ° different from the waiting zone. Correspondingly, four silicon rod positioning mechanisms can be arranged on the conversion main body, the four silicon rod positioning mechanisms are distributed at 90 degrees between every two silicon rod positioning mechanisms, and each silicon rod positioning mechanism can position at least one silicon rod. In the running water operation, when one silicon rod positioning mechanism corresponds to one functional zone at any time, the other three silicon rod positioning mechanisms correspond to the other three functional areas, for example, when the first silicon rod positioning mechanism corresponds to the waiting area, a second silicon rod positioning mechanism corresponding to the first cutting region, a third silicon rod positioning mechanism corresponding to the second cutting region, and a fourth silicon rod positioning mechanism corresponding to the grinding region, the first silicon rod positioning mechanism can be controlled to load a new silicon rod or unload the silicon rod positioned by the first silicon rod positioning mechanism at the waiting position, performing a first cutting operation on the silicon rod positioned by the second silicon rod positioning mechanism at the first cutting position, and carrying out second cutting operation on the silicon rod positioned by the third silicon rod positioning mechanism in the second cutting position, and carrying out grinding operation on the silicon rod positioned by the fourth silicon rod positioning mechanism in the grinding position.

The conversion main body is driven by the conversion driving mechanism to rotate, and the silicon rod positioning mechanism on the conversion main body and the silicon rod positioned by the silicon rod positioning mechanism are converted between different functional areas through the rotation of the conversion main body. In some embodiments, the conversion body may be a structure of a disk or a ring, but not limited thereto, and in other embodiments, the conversion body may be a structure of a regular polygon or other shapes.

The conversion driving mechanism is used as a driving mechanism for converting the functional position where the silicon rod positioning mechanism is positioned on the conversion main body. In some embodiments, the changeover drive mechanism comprises a changeover rotating shaft and a rotary drive unit, so that the changeover body and the respective silicon rod positioning mechanisms arranged thereon can be shifted in position between the respective function areas by driving the changeover rotating shaft to rotate by a preset angle by the rotary drive unit.

In some embodiments, the indexing axis is located in a geometrically central region of the conversion body, and the indexing axis is disposed in an upright direction.

In some embodiments, the rotational drive unit further comprises: the conversion piece is provided with a tooth structure and is associated with the conversion main body or the transposition rotating shaft; a drive source and an interlocking structure connected with the drive source and driven by the drive source.

In some embodiments, the conversion member with a tooth structure may be, for example, a conversion toothed belt or a conversion rack, and the conversion body is, for example, a circular disk, the conversion toothed belt or the conversion rack may be disposed on the circumferential outer surface of the conversion body or disposed concentrically with the conversion body, and the conversion body is, for example, a circular ring, the conversion toothed belt or the conversion rack may be disposed on the circumferential outer surface or the circumferential inner surface of the conversion body or disposed concentrically with the conversion body. In some embodiments, the conversion member with the tooth structure may be, for example, a conversion gear, and the conversion gear is disposed on the shift spindle.

The linkage structure is associated with the drive source and the conversion member with the tooth structure. In some embodiments, the linkage arrangement comprises a drive gear or a drive gear set which engages with the conversion element with the toothed arrangement (e.g. a conversion toothed belt, a conversion rack or a conversion gear), and the linkage arrangement can be driven, for example, by a drive source to rotate the conversion body to bring about the conversion of the silicon rod positioning mechanism and the silicon rod thereon to other functional regions. The drive source may be, for example, a servo motor.

In practical applications, the drive source is a servo motor, the linkage structure is a drive gear, and the conversion member with the tooth structure is a conversion toothed belt, a conversion rack or a conversion gear. In some embodiments, each functional region is a sequentially arranged ring-shaped configuration, the driving gear is driven by the driving source to rotate in the forward direction, the position of the conversion body and each silicon rod positioning mechanism arranged on the conversion body is switched from the current functional region to the adjacent subsequent functional region or other functional regions behind the current functional region by meshing the driving gear with the conversion toothed belt, the conversion rack or the conversion gear to rotate in the forward direction by a preset angle, or the driving source is driven to rotate the driving gear in the reverse direction, and the position of the conversion body and each silicon rod positioning mechanism arranged on the conversion body are switched from the current functional region to the adjacent previous functional region or adjacent previous functional region by meshing the driving gear with the conversion toothed belt, the conversion rack or the conversion gear to rotate in the reverse direction by a preset angle Other functional zone before, other functional zone after, or adjacent to the next functional zone.

In the embodiment shown in fig. 1 and 2, the functional regions including the waiting region, the first cutting region, the second cutting region, and the grinding region are arranged in a ring shape. For example, taking the difference between two adjacent functional areas of 90 ° as an example, assuming that, in an initial state, a silicon rod is positioned by one silicon rod positioning mechanism in the silicon rod conversion device and the silicon rod positioning mechanism and the positioned silicon rod thereof correspond to the first functional area, the driving gear is driven by the driving source to rotate counterclockwise, and the transfer toothed belt, the transfer rack or the transfer gear and the associated conversion rotating shaft thereof are driven to rotate clockwise by a preset angle of 90 ° through the engagement between the driving gear and the transfer toothed belt, the transfer rack or the transfer gear, so that the one silicon rod positioning mechanism and the positioned silicon rod thereof in the silicon rod conversion device are transferred from the first functional area to the second functional area. Or, in another situation, in an initial state, a silicon rod is positioned by one silicon rod positioning mechanism in the silicon rod conversion device, the silicon rod positioning mechanism and the positioned silicon rod thereof correspond to the second function region, the driving source is used for driving the driving gear to rotate clockwise, and the conversion toothed belt, the conversion rack or the conversion gear and the associated conversion rotating shaft thereof are driven to rotate counterclockwise by a preset angle of 90 degrees by meshing the driving gear with the conversion toothed belt, the conversion rack or the conversion gear, so that the silicon rod positioning mechanism in the silicon rod conversion device and the positioned silicon rod thereof are transferred from the second function region to the first function region. The preset angle is not strictly limited, for example, the preset angle is not strictly limited to 90 °, and in an actual processing scene, the preset angle may allow a certain deviation from 90 °, for example, the preset angle may be 90 ° ± 5 °, and other angles.

In certain embodiments, the silicon rod transfer device may further comprise a locking mechanism for locking the transfer body.

In some embodiments, the locking mechanism may include a plurality of locking pins and a locking cylinder connected to the locking pins, wherein the number of the locking pins may be multiple and is uniformly distributed on the edge of the conversion body (for example, the number of the locking pins is four and is uniformly distributed in a 90 ° manner), and in practical applications, when a silicon rod needs to be converted from a certain processing region to another processing region, the locking cylinder drives the locking pins to contract to unlock the disc-shaped or circular conversion body, so that the conversion body can rotate; after the silicon rod is converted, namely the silicon rod is converted to a target processing position from a certain processing position, a locking cylinder in the locking mechanism drives a locking bolt to extend out and act on the conversion main body, and the conversion main body is locked.

In some embodiments, the locking mechanism may include a plurality of locking pins and a locking cylinder connected to the locking pins, wherein the number of the locking pins may be multiple and is uniformly distributed on the edge of the conversion body (for example, the number of the locking pins is four and is uniformly distributed in a 90 ° manner), and in practical applications, when a silicon rod needs to be converted from a certain processing region to another processing region, the locking cylinder drives the locking pins to contract to unlock the disc-shaped or circular conversion body, so that the conversion body can rotate; after the silicon rod is converted, namely the silicon rod is converted to a target processing position from a certain processing position, a locking cylinder in the locking mechanism drives a locking bolt to extend out and act on the conversion main body, and the conversion main body is locked.

In some embodiments, the locking mechanism may include corresponding teeth, for example, a first tooth plate may be disposed on the conversion body, a first tooth plate is disposed on the first tooth plate, a second tooth plate may be disposed on the silicon rod processing platform, and a second tooth plate is disposed on the second tooth plate, when the conversion body is to be rotated, the conversion body is lifted and driven to rotate, for example, rotate 90 ° or 120 °, the rotation is stopped, and the conversion body is lowered, so that the first tooth plate on the conversion body falls on the second tooth plate on the silicon rod processing platform, that is, the first tooth plate on the first tooth plate and the second tooth plate on the second tooth plate are engaged alternately, thereby locking the conversion body.

With regard to the silicon rod positioning mechanism on the silicon rod transfer device, the silicon rod positioning mechanism may further include: the device comprises a rotary bearing table, a rotary jacking device, a lifting driving device and a rotary driving device.

The rotary bearing table is used for bearing the silicon rod. In the embodiment shown in fig. 1 and 2, the rotary susceptor 431 is used to support the silicon rods 100, 200 such that the silicon rods 100, 200 are vertically disposed, i.e., the bottoms of the silicon rods 100, 200 are seated on the rotary susceptor 431, and in particular, the rotary susceptor 431 may also be configured to be capable of performing a self-rotation motion, for example, the rotary susceptor 431 has a rotating shaft with respect to the conversion body 41 to perform the self-rotation motion, so that the rotary susceptor 431 and the silicon rods 100, 200 thereon can rotate together after the rotary susceptor 431 supports the silicon rods 100, 200. Further, the contact surface of the rotary susceptor 431 for contacting the silicon rod has a damping to provide a certain friction force to drive the silicon rod. The rotary bearing platform 431 is adapted to the silicon rod 100, 200, and in some embodiments, the rotary bearing platform 431 may be a circular bearing platform adapted to the cross section of the silicon rod 100, 200, but is not limited thereto, and for example, the rotary bearing platform may also be a square bearing platform. In some examples, the table top size of the rotary bearing table 431 may be smaller than the cross-sectional size of the silicon rod, but not limited thereto, and in some examples, the table top size of the rotary bearing table 431 may also be equal to or larger than the cross-sectional size of the silicon rod.

And the silicon rod is jacked by the rotary jacking device. In the exemplary embodiment shown in fig. 1 and 2, the rotary pressing device 433 is arranged above the rotary support 431 in an opposing manner for pressing against the top of the silicon rods 100, 200 in order to press the silicon rods 100, 200. The rotary pressing device 433 may further include a support movably disposed and a pressing block disposed at the bottom of the support. The support is movably mounted on a central mounting bracket 45, which is located in the central region of the conversion body 41 and rotates with the conversion body 41. The movable pressing block is adapted to the silicon rod 100, 200, and in some embodiments, the movable pressing block may be a disk-shaped pressing block adapted to the cross-sectional dimension of the silicon rod 100 to be processed, but is not limited thereto, and for example, the movable pressing block may also be a square pressing block. Further, the pressing movable block of the rotary pressing device 433 is pivotally connected to the support and can rotate relative to the support.

As can be seen from the foregoing, the rotary stage 431 is configured to rotate and the pressing movable block of the rotary pressing device 433 is pivotally connected to the support, so that the rotary stage 431 or the pressing movable block can be linked to a rotary driving device. In one case, when the rotary platform 431 is coupled to a rotary driving device, the rotary platform 431 serves as a driving rotating member and the pressing movable block serves as a driven rotating member; in another case, when the pressing movable block is linked to a rotation driving device, the pressing movable block serves as a driving rotation member and the rotation platform 431 serves as a driven rotation member.

In practical applications, the rotary pressing device 433 may cooperate with the rotary supporting platform 431 therebelow, and specifically, after the silicon rod 100 to be processed is vertically placed on the rotary supporting platform 431, the lifting driving device drives the support to move down along the central mounting frame 45 until the pressing movable block on the support presses against the top of the silicon rod 100. Subsequently, when the silicon rod 100 (or 200) needs to be rotated, the rotary bearing platform 431 or the jacking movable block which are linked are driven by the rotary driving device to rotate, and the silicon rod 100 (or 200) is also driven to rotate together by utilizing the friction force among the rotary bearing platform 431, the silicon rod 100 (or 200) and the jacking movable block, so that the adjustment of the operation surface or the operation area in the silicon rod 100 (or 200) is realized, and the processing operation is carried out on the adjusted operation surface or the operation area in the silicon rod 100 (or 200). The rotation speed and the rotation angle of the silicon rod 100 (or 200) may be controlled by the rotation driving means. In a specific implementation manner, the lifting driving device may be, for example, an air cylinder or a lifting motor, and the rotation driving device may be, for example, a rotating motor.

The silicon rod loading and unloading device is arranged adjacent to the silicon rod processing platform and used for bearing the silicon rod to be processed or the processed silicon rod and turning over the silicon rod to be processed or the processed silicon rod so as to switch the borne silicon rod to be processed or the processed silicon rod between a first placing state and a second placing state. In different silicon rod processing apparatuses, "to be processed" and "processed" have different meanings here. For example, in an embodiment in which the silicon rod processing apparatus is a silicon rod squarer, "to-be-processed" means "to-be-cut" and "processed" means "cut"; in the embodiment that the silicon rod processing equipment is a silicon rod cutting and grinding all-in-one machine, the 'to-be-processed' means 'to-be-cut', and the 'processed' means 'cut' or 'ground'.

In the embodiment shown in fig. 1 and 2, the silicon rod handling device 5 is disposed adjacent to the waiting location of the silicon rod processing platform, and is configured to load the silicon rod to be processed into the waiting location of the silicon rod processing platform and unload the processed silicon rod from the waiting location of the silicon rod processing platform. Specifically, the silicon rod loading and unloading device 5 is used for loading the silicon rod to be processed to the waiting position of the silicon rod processing platform and unloading the processed silicon rod from the waiting position of the silicon rod processing platform, and specifically means for loading the silicon rod to be processed on the rotary carrying table 431 corresponding to the waiting position of the silicon rod processing platform in the conversion body 41 and unloading the processed silicon rod from the rotary carrying table 431 corresponding to the waiting position of the silicon rod processing platform in the conversion body 41.

As shown in fig. 1 and 2, the silicon rod handling device 5 includes: the silicon rod placing device comprises a base 51 and a supporting body 53, wherein the supporting body 53 is arranged on the base 51 in a turnable manner, so that the silicon rod can be placed in a state of being turned over.

The base is adjacently arranged at a waiting position of the silicon rod processing equipment.

The base serves as a main body part of the silicon rod loading and unloading device, and in some examples, the base is large in size and weight so as to provide a large mounting surface and firm overall stability. It should be understood that the configuration of the base may vary based on different functional or structural requirements. In certain implementations, as shown in fig. 1 and 2, the base 51 may be mounted directly on the machine base 1 of the silicon rod processing apparatus (e.g., a silicon rod slicing and grinding machine). In some implementations, the base may further include a support structure, such as a rod, a post, a shelf, etc., by which the base may be disposed adjacent to the silicon rod processing apparatus.

The supporting body is arranged on the base in a turnover mode through the turnover mechanism and used for supporting the silicon rod. The supporting body is turned over relative to the base through the turning mechanism, so that the silicon rod can be switched between a first placing state and a second placing state, namely, the supporting body is turned over relative to the base through the turning mechanism so as to be switched between a first position and a second position. For example, in some implementations, the supporting body is turned over relative to the base by the turning mechanism for the first time to change from the first position to the second position, so that the supported silicon rod is changed from the first placement state to the second placement state, or the supporting body is turned over relative to the base by the turning mechanism for the second time to change from the second position to the first position, so that the supported silicon rod is changed from the second placement state to the first placement state.

The silicon rods that the carrier may carry may comprise a plurality of configurations, for example, the carrier may carry a first configuration silicon rod and a second configuration silicon rod. In some embodiments, the carrier includes a carrier seat, a first carrier, a second carrier, and a bottom bracket. Therefore, in some implementations, the supporting body can support the first-form silicon rod through the first supporting member, and the supporting body can be turned over relative to the base through the turning mechanism, so that the supported first-form silicon rod can be switched between the first placement state and the second placement state. In some implementations, the supporting body can support the second silicon rod in the second shape through the second supporting member, and the supporting body can be turned over relative to the base through the turning mechanism, so that the supported second silicon rod in the second shape can be switched between the first placement state and the second placement state. In the embodiment, after the silicon rod is processed by the silicon rod processing equipment, the shape of the silicon rod may be changed, and here, the silicon rod to be processed may be used as a first shape silicon rod, and the processed silicon rod may be used as a second shape silicon rod.

FIG. 3 is a schematic view of a carrier of the silicon rod handling apparatus shown in FIG. 1. Referring to fig. 1 and 3, the carrier 53 includes a carrier 531, a first carrier 533 disposed on the carrier 531 for carrying the first form silicon rod, a second carrier 535 disposed on the carrier 531 for carrying the second form silicon rod, and a bottom supporting member 537 disposed at the end of the carrier 531. The first shape silicon rod carried by the first carrier 533 may be, for example, a silicon rod with a circular cross section, and the second shape silicon rod carried by the second carrier 535 may be, for example, a silicon rod with a rectangular-like cross section. The first placement state may be, for example, a horizontal placement state, in which the axis of the silicon rod is placed along the horizontal line or substantially along the horizontal line, and the second placement state may be, for example, a vertical placement state, in which the axis of the silicon rod is placed vertically or substantially vertically.

In the silicon rod handling device of this application, the supporting body is located through a flip structure with overturning the base.

Fig. 3 to 8 are schematic views showing a structure of the silicon rod handling device according to an embodiment of the present invention, wherein fig. 3 to 5 are schematic views showing a structure of a supporting body carrying a silicon rod in the silicon rod handling device according to an embodiment of the present invention, and fig. 6 to 8 are schematic views showing a structure of the silicon rod handling device according to an embodiment of the present invention in different turning states. Referring to fig. 3 to 8, the silicon rod handling device 5 includes: the supporting body 53 further includes a supporting base 531, a first supporting member 533, a second supporting member 535, and a bottom supporting member 537, and the supporting body 53 can be reversibly disposed on the base 51 by a turning mechanism.

The turnover mechanism comprises: the turnover driving device comprises a first switching structure, a turnover driving rod, a second switching structure, a driving source and a transmission piece. As shown in fig. 7, the first pivot structure 521 is provided at the reverse end of the base 51. In this embodiment, to accommodate the silicon rod to be carried, the base 51 may be an elongated structure, which may include a first end portion and a second end portion, and of course, may also be referred to as a leading end (portion) and a trailing end (portion), or may also be referred to as a leading end (portion) and a trailing end (portion). Here, the second end (or, the trailing end (portion), the rear end (portion)) of the base 51 may be assumed as the flip end. In a specific implementation, the first adapting structure 521 may be, for example, a rotating shaft structure, and the rotating shaft structure may include a first adapting seat and a first rotating shaft, wherein the first adapting seat may be disposed on the base 51, and the first rotating shaft is disposed on the first adapting seat and is associated with the bearing seat 531.

The overturning driving rod is used for controllably driving the bearing seat. As shown in fig. 7, the reverse driving rod 523 has a force-bearing end and a driving end, wherein the driving end of the reverse driving rod 523 can be connected to the bearing seat 531 of the carrier 53 through the second connecting structure 525. In a specific implementation, the second adapting structure 525 may be, for example, a rotating shaft structure, and the rotating shaft structure may include a second rotating shaft, and the second rotating shaft is associated with the bearing seat 531 and the driving end of the turning driving rod 523. The second switching structure and the first switching structure have a preset distance therebetween.

The driving source and the transmission piece are arranged on the base, wherein the transmission piece is associated with the driving source and the stress end of the turnover driving rod. The driving source and the transmission piece can be used for driving the overturn driving rod to actuate.

In some embodiments, the transmission member includes a driving rack and a transmission gear engaged with the driving rack, the transmission gear is coupled to the driving source, the transmission gear is associated with the force-bearing end of the turnover driving rod, and the driving source can be, for example, a servo motor. Generally, the servo motor drives the transmission gear to rotate, the rotating transmission gear rolls back and forth along the length direction of the corresponding transmission rack to drive the force bearing end of the turnover driving rod associated with the transmission gear to move back and forth, so that the driving end of the turnover driving rod rotates relative to the bearing seat through the second switching structure under the action of the force bearing end and drives the bearing seat, and thus, the bearing seat is turned relative to the base through the first switching structure under the drive of the turnover driving rod. For example, the servo motor drives the transmission gear to rotate forward, and the transmission gear rotating forward rolls forward (i.e., toward the waiting position) along the length direction of the corresponding transmission rack to drive the stressed end of the turnover driving rod associated with the transmission gear to move forward (i.e., toward the waiting position), so that the driving end of the turnover driving rod rotates relative to the bearing seat through the second adapter structure under the action of the stressed end and pushes against the bearing seat, and thus, the bearing seat rotates forward (i.e., toward the waiting position) relative to the base through the first adapter structure under the pushing of the turnover driving rod. Or, the servo motor drives the transmission gear to rotate reversely, the transmission gear which rotates reversely rolls backwards (i.e. deviates from the waiting zone bit) along the length direction of the corresponding transmission rack, and the stressed end of the turnover driving rod associated with the transmission gear is driven to move backwards (i.e. deviates from the waiting zone bit), so that the driving end of the turnover driving rod rotates and pulls the bearing seat through the second switching structure relatively under the action of the stressed end, and thus, the bearing seat is reversed (i.e. deviates from the waiting zone bit) relative to the base through the first switching structure under the pulling action of the turnover driving rod.

In certain embodiments, the drive member comprises a drive chain. As shown in fig. 7, the transmission member includes a transmission chain 5271, the transmission chain 5271 is wound around two transmission sprockets which are oppositely arranged, and the force-bearing end of the turnover driving rod 523 is directly or through a connection structure associated with the transmission chain 5271, for example, the force-bearing end of the turnover driving rod 523 is associated with the transmission chain 5271 through a third switching structure 529. In a specific implementation, the third adapting structure 529 can be, for example, a rotating shaft structure, and the rotating shaft structure can include a third rotating shaft, and the third rotating shaft is associated with the force-bearing ends of the transmission chain 5271 and the turnover driving rod 523. At least one of the two drive sprockets 5273 (also referred to as a drive sprocket) is journaled to the drive source (the other drive sprocket 5275 can be a driven sprocket), which can be, for example, a servo motor. Generally, the servo motor drives the coupled driving sprocket 5273 to rotate, and the rotating driving sprocket drives the driving chain 5271 to roll back and forth, so as to drive the force-bearing end of the turning driving rod 523 associated with the driving chain 5271 to move back and forth, so that the driving end of the turning driving rod 523 rotates relative to the bearing seat 531 through the second adapter structure 525 under the action of the force-bearing end, and drives the bearing seat 531, and thus, the bearing seat 531 turns relative to the base through the first adapter structure 521 under the drive of the turning driving rod 523. For example, the servo motor drives the one of the transmission sprockets of the shaft joint to rotate forward, and the transmission sprocket rotating forward drives the transmission chain to roll forward (i.e., toward the waiting position), and drives the force bearing end of the turnover driving rod associated with the transmission chain to move forward (i.e., toward the waiting position), so that the driving end of the turnover driving rod rotates relative to the bearing seat through the second switching structure under the action of the force bearing end and pushes against the bearing seat, and thus, the bearing seat rotates forward (i.e., toward the waiting position) relative to the base through the first switching structure under the pushing of the turnover driving rod. Or, the servo motor drives the transmission sprocket connected to the shaft to rotate reversely, the transmission sprocket rotating reversely drives the transmission chain to roll backwards (i.e. to deviate from the waiting position), and the force bearing end of the turnover driving rod associated with the transmission chain is driven to move backwards (i.e. to deviate from the waiting position), so that the driving end of the turnover driving rod rotates and pulls the bearing seat through the second switching structure relatively under the action of the force bearing end, and thus, the bearing seat is pulled by the turnover driving rod to turn reversely (i.e. deviate from the waiting position) relative to the base through the first switching structure.

As mentioned above, with the turning mechanism in different implementations, the supporting body can be driven to turn over with respect to the base, that is, the supporting body is turned over with respect to the base by the turning mechanism to switch between the first position and the second position, which are at a predetermined angle, so as to switch the supported first form silicon rod or the supported second form silicon rod between the first placement state and the second placement state. Still taking the aforesaid silicon rod loading and unloading device as an example, assuming that in the current state, as shown in fig. 6, the carrier 53 is at the first position (for example, the first position is a horizontal position), at this time, the first form silicon rod or the second form silicon rod carried by the carrier 53 is at the first placement state (for example, the first placement state is a horizontal placement state), subsequently, the driving source in the turnover mechanism drives the turnover driving rod 523 through the transmission member, that is, the force receiving end of the turnover driving rod 523 moves towards the waiting area under the driving of the driving source and the transmission member, the driving end of the turnover driving rod 523 rotates and pushes the carrier 53 through the second adapter 525 under the action of the force receiving end, the carrier 53 rotates and pushes the carrier 53 through the first adapter 521 relative to the base 51 under the pushing of the turnover driving rod 523 (as shown in fig. 7, shown as a schematic diagram of the carrier 53 being turned over relative to the base 51 by the first adapting mechanism 521), until the carrier 53 is turned over by a predetermined angle, the carrier 53 can be finally transferred from the initial first position to the second position (for example, the second position is a vertical position, and the predetermined angle is, for example, 90 °), as shown in fig. 8, which is a schematic diagram of the carrier 53 being turned over relative to the base 51 by the first adapting mechanism 521 and then being transferred to the second position, at this time, the first configuration silicon rod or the second configuration silicon rod carried by the carrier 53 is in the second placement state (for example, the second placement state is a vertical placement state). As can be seen from fig. 6 to 8, the supporting body 53 is turned over relative to the base 51 by the turning mechanism and then is transferred from the original first position to the second position, so that the supported first form silicon rod or the supported second form silicon rod is transferred from the original first placement state to the second placement state, for example, the first position is a horizontal position and the second position is a vertical position, and then the supporting body 53 is turned over by 90 ° or about 90 ° forward relative to the base 51 by the turning mechanism and is transferred from the horizontal position to the vertical position, so that the supported first form silicon rod or the supported second form silicon rod is transferred from the first placement state (for example, the first placement state is a horizontal placement state) to the second placement state (for example, the second placement state is a vertical placement state). Correspondingly, the turning mechanism may also be configured to turn the supporting body 53 relative to the base 51 from the original second position to the first position so as to convert the supported first form silicon rod or the supported second form silicon rod from the original second placement state to the first placement state, for example, the second position is a vertical position and the first position is a horizontal position, the second placement state is a vertical placement state and the first placement state is a horizontal placement state, and the supporting body 53 is turned by about 90 ° or 90 ° in a reverse direction relative to the base 51 by the turning mechanism and converted from the vertical placement state to the horizontal placement state so as to convert the supported first form silicon rod or the supported second form silicon rod from the vertical placement state to the horizontal placement state.

It should be noted that, as can be seen from the above, the tilting mechanism in different implementations may be utilized to drive the carrier to be tilted with respect to the base, that is, the carrier is tilted with respect to the base by the tilting mechanism to be switched between a first position and a second position, the first position may be, for example, a horizontal position and the second position may be, for example, a vertical position, but not limited thereto, and in other embodiments, the first position may also be a horizontal deviation angle with respect to the horizontal line, the horizontal deviation angle may range from 0 ° to 15 ° with respect to the horizontal line, the second position may also be a vertical deviation angle with respect to the weight line, and the vertical deviation angle may range from 85 ° to 95 ° with respect to the horizontal line.

The silicon rod that the supporting body can carry can include multiple forms, for example, the supporting body includes a bearing seat, a first bearing member, a second bearing member, and a bottom support member, wherein the first bearing member is used for bearing the first form silicon rod, and the second bearing member is used for bearing the second form silicon rod. In the embodiment shown in fig. 4 and 5, the first configuration silicon rod may be, for example, a silicon rod to be processed, i.e., a silicon rod having a circular cross-section, and the second configuration silicon rod may be, for example, a processed silicon rod, i.e., a silicon rod having a quasi-rectangular cross-section.

In the embodiment shown in fig. 3, the first carrier 533 includes two support frames 5331 disposed opposite to each other, and the two support frames 5331 cooperate to carry the first form silicon rod.

Regarding the supporting frames 5331, each supporting frame 5331 is provided with a plurality of rollers. As shown in fig. 3, the plurality of rollers on the support frame 5331 are arranged along the length direction of the support frame 5331, and the plurality of rollers are disposed on the top of the support frame 5331, i.e., the surfaces of the rollers are protruded from the support frame 5331 for contacting and supporting the first form silicon rod. Thus, when the first form silicon rods are placed on the rollers of the two support frames 5331, the first form silicon rods can be driven to move along the length direction of the support frames 5331 through the plurality of rollers.

In some implementations, when a first form silicon rod is placed on the two support frames 5331 of the first carrier 533 in the first placement state, the rollers on the support frames 5331 are in contact with the first form silicon rod, and at this time, a force may be applied to the first form silicon rod to drive the first form silicon rod to move along the length direction of the support frames 5331 through the plurality of rollers. The manner of applying force to the first shape silicon rod may include manual or mechanical means (e.g., a pushing mechanism or a pushing and pulling mechanism), and the manner of placing the first shape silicon rod on the two support frames 5331 of the first carrier 533 in the first placement state may include manual or mechanical means (e.g., a robot).

In some implementations, when the first form silicon rod is placed on the two support frames 5331 of the first carrier 533 in the first placement state, the rollers on the support frames 5331 are in contact with the first form silicon rod, and at this time, the rollers can be controlled to roll to drive the first form silicon rod to move along the length direction of the support frames 5331 through the rollers. The manner of controlling the plurality of rollers may include configuring corresponding motor assemblies for the plurality of rollers, and controlling some or all of the plurality of rollers to roll by using the motor assemblies, for example, at least one motor assembly is disposed in a middle region of the support frame 5331 and is associated with at least one roller, or at least one motor assembly is disposed in each of two end regions and a middle region of the support frame 5331 and is associated with at least one roller, and when in use, the associated at least one roller is driven by the motor assemblies, and the rolling rollers drive the first-form silicon rod to move along the length direction of the support frame 5331 through the plurality of rollers by friction between the rollers and the first-form silicon rod. In addition, the manner of placing the first form silicon rods on the two support frames 5331 of the first carrier 533 in the first placement state may include a manual manner or a mechanical device (e.g., a robot).

In the silicon rod loading and unloading device, two support frames in the first bearing piece can be movably arranged on the bearing seat. In the embodiment shown in fig. 3, the two supporting frames 5331 of the first carrier 533 are pivotally connected to the carrier 531. Through the coupling manner, the swing positions of the two supporting frames 5331 relative to the bearing seat 531 can be flexibly adjusted, so as to adjust the supporting space between the two supporting frames 5331.

In some embodiments, the first supporting member may further include a swinging mechanism, and the swinging mechanism may provide swinging of the supporting frames relative to the supporting base to adjust the supporting space between the two supporting frames.

In some implementations, the swing mechanism may include a third adapting structure, and the supporting frame is adapted to the carrying seat through the third adapting structure. In the embodiment shown in fig. 3, the swinging structure includes a third adapting structure 541, and the third adapting structure 541 is disposed at a side of the carrying seat 531. In a specific implementation, the third adapting structure 541 may be, for example, a rotating shaft structure, and the rotating shaft structure may include a third adapting seat and a third rotating shaft, where the third adapting seat may be disposed on the bearing seat 531, and the third rotating shaft is disposed on the third adapting seat and associated with the supporting frame 5331. For any one support frame 5331, the number of the third adapting structures 541 can be varied according to the size specification of the first form silicon rod, the length of the support frame 5331, and the like. For example, a third adapting structure 541 can be disposed at each of the front and rear ends of the supporting frame 5331. Alternatively, a third adapter structure is disposed at the front end, the middle end, and the rear end of the support frame 5331. Therefore, by utilizing the third switching structure, the support frames can be swung relative to the bearing seat to adjust the bearing space between the two support frames. For example, the two support frames swing inwards relative to the bearing seat, so that the bearing space between the two support frames can be reduced, and the support device is suitable for supporting the first-form silicon rod with smaller dimension and specification; the two support frames swing outwards relative to the bearing seat, so that the bearing space between the two support frames can be enlarged, and the silicon rod bearing device is suitable for supporting the first-form silicon rod with larger size and specification.

In some implementations, the swing mechanism may include a third adapting structure, through which the supporting frame is adapted to the carrying seat, and a driving unit associated with the supporting frame and the carrying seat. In the embodiment shown in fig. 3, the third adapting structure 541 and the driving unit are disposed at the side of the carrying seat 531. In a specific implementation, the third adapting structure 541 may be, for example, a rotating shaft structure, and the rotating shaft structure may include a third adapting seat and a third rotating shaft, where the third adapting seat may be disposed on the bearing seat 531, and the third rotating shaft is disposed on the third adapting seat and associated with the supporting frame 5331. For any one support frame 5331, the number of the third adapting structures 541 can be varied according to the size specification of the first form silicon rod, the length of the support frame 5331, and the like. For example, a third adapter 541 can be disposed at each of the front and rear ends of the support 5331. Alternatively, a third adapter 541 is disposed at the front end, the middle end, and the rear end of the supporting frame 5331. The driving unit may be, for example, a swing cylinder or a swing hydraulic cylinder with an expansion link, and the swing cylinder or the swing hydraulic cylinder is, for example, disposed on the support frame 5331, and the expansion link of the swing cylinder or the swing hydraulic cylinder is associated with (e.g., connected by a rotating shaft, a hook, or other structures). The number of the swing cylinders or swing cylinders may be varied according to the size of the first form silicon rod, the length of the support 5331, and the like. Therefore, the driving unit can be used for driving the support frames, so that the support frames can swing relative to the bearing seat, and the bearing space between the two support frames can be adjusted. For example, the driving units respectively drive the corresponding support frames to enable the two support frames to swing inwards relative to the bearing seat, so that the bearing space between the two support frames can be reduced, and the silicon rod support device is suitable for supporting the first-form silicon rod with smaller dimension and specification; the driving units respectively drive the corresponding support frames to enable the two support frames to swing outwards relative to the bearing seat, so that the bearing space between the two support frames can be enlarged, and the silicon rod bearing device is suitable for supporting a first-form silicon rod with a larger size and specification.

In the embodiment shown in fig. 3, the second carrier 535 comprises a carrying platform disposed on the carrying seat 531, and the carrying platform can carry the second silicon rod. As previously mentioned, the first configuration silicon rod may for example be a silicon rod to be processed, i.e. a silicon rod with a circular cross-section, and the second configuration silicon rod may for example be a processed silicon rod, i.e. a silicon rod with an approximately rectangular cross-section. The cutting device of the silicon rod processing equipment can be used for cutting the first-form silicon rod with a circular cross section into a second-form silicon rod with a rectangular-like cross section, so that the second-form silicon rod has four side tangential planes, and the cross section of the second-form silicon rod formed after cutting operation is generally smaller than or equal to that of the first-form silicon rod. As shown in fig. 3, the carrying platform can be used for carrying the second silicon rod, and when carrying, the carrying platform is in contact with one of the side tangential planes of the second silicon rod.

In addition, to facilitate the transportation of the second form of silicon rods, in the embodiment shown in fig. 3, the second carrier 535 further comprises a transportation device provided on the carrier platform. In some implementations, as shown in fig. 3, the conveying device is a conveyor belt device, which includes a conveyor belt wound around two conveying rollers (not shown in the drawings) disposed opposite to each other in front and back, and at least one of the two conveying rollers is pivoted to a conveying driving source, which may be a servo motor, for example. Generally, the servo motor drives the coupled conveying roller to rotate, and the rotating conveying roller drives the conveying belt to roll back and forth, so as to drive the second shape silicon rod borne on the conveying belt to move back and forth. For example, the servo motor drives the coupled conveying roller to rotate forward, the forward rotating conveying roller drives the conveying belt to move forward (i.e., towards the waiting area), and the second form silicon rod carried on the conveying belt is driven to move forward (i.e., towards the waiting area). Or the servo motor drives the coupled conveying roller to rotate reversely, the reversely rotating conveying roller drives the conveying belt to move backwards (i.e. depart from the waiting position), and the second-form silicon rod borne on the conveying belt is driven to move backwards (i.e. depart from the waiting position).

With reference to fig. 3 and the above description of the first carrier, the first carrier may swing relative to the carrier by a swing mechanism, for example, swing toward the outside of the carrier, so as to expose the second carrier 535, so that the second carrier 535 can carry the second silicon rod.

In the silicon rod loading and unloading device of the application, the silicon rod loading and unloading device further comprises a forward and backward mechanism for driving the base and the bearing bodies on the base to move forward and backward, namely, the forward and backward mechanism is utilized to drive the base and the bearing bodies on the base to move forward and backward relative to the waiting area.

Different implementations are possible with respect to the advancing and retracting mechanism.

In certain implementations, the advancing and retracting mechanism includes: a forward and backward rack provided on the base along a forward and backward direction (in a Y-axis direction as shown in fig. 2), a forward and backward gear provided on a mounting structure and engaged with the forward and backward rack, and a forward and backward driving source associated with the forward and backward gear. The mounting structure may be provided below the base. In some implementations, the mounting structure is a support structure for supporting the base, which may be, for example, a rod, a column, a frame, and the like. The advancing-retreating rack, the advancing-retreating gear, and the advancing-retreating drive source in the advancing-retreating mechanism may be at least one set. Taking a pair of advancing and retracting mechanisms as an example, the pair of advancing and retracting mechanisms can be arranged in the central area of the supporting structure. Taking two pairs of advancing and retreating mechanisms as an example, the two advancing and retreating mechanisms are respectively arranged on two opposite sides of the support structure, wherein the advancing and retreating racks in the two advancing and retreating mechanisms are oppositely arranged, namely, the teeth in the two advancing and retreating racks face to the central area of the support structure. The forward direction is a moving direction towards the waiting zone bit, and the backward direction is a moving direction away from the waiting zone bit. The drive source may be, for example, a servo motor.

Generally, the servo motor drives the advancing and retreating gear to rotate, and the advancing and retreating rack is driven by the rotation of the meshed gears to advance and retreat back and forth along the advancing and retreating direction, so as to drive the base, the bearing body on the base and the silicon rod to advance and retreat. For example, the servo motor drives the advancing and retreating gear to rotate forward, and the advancing and retreating gear rotating forward drives the advancing and retreating rack to move forward (i.e. towards the waiting position) along the advancing and retreating direction, and drives the base and the bearing body thereon and the silicon rod to move forward (i.e. towards the waiting position). The servo motor drives the advance and retreat gear to rotate reversely, the advance and retreat gear which rotates reversely drives the advance and retreat rack to move backwards (i.e. depart from the waiting area) along the advance and retreat direction, and the base, the bearing body on the base and the silicon rod are driven to move backwards (i.e. depart from the waiting area).

In certain implementations, the advancing and retracting mechanism includes: the driving and reversing mechanism comprises a forward and reverse rack, a forward and reverse gear and a forward and reverse driving source, wherein the forward and reverse rack is arranged on a mounting structure along a forward and reverse direction, the forward and reverse gear is arranged on the base and meshed with the forward and reverse rack, and the forward and reverse driving source is associated with the forward and reverse gear. The mounting structure may be provided below the base. In some implementations, the mounting structure is a support structure for supporting the base, which may be, for example, a rod, a column, a frame, and the like. The advancing-retreating rack, the advancing-retreating gear, and the advancing-retreating drive source in the advancing-retreating mechanism may be at least one set. Taking a pair of advancing and retracting mechanisms as an example, the pair of advancing and retracting mechanisms can be arranged in the central area of the supporting structure. Taking two pairs of advancing and retreating mechanisms as an example, the two advancing and retreating mechanisms are respectively arranged on two opposite sides of the supporting structure, wherein the advancing and retreating racks in the two advancing and retreating mechanisms are oppositely arranged, namely, the teeth in the two advancing and retreating racks face to the central area of the supporting structure or are back to the central area of the supporting structure. The forward direction is a moving direction towards the waiting zone bit, and the backward direction is a moving direction away from the waiting zone bit. The drive source may be, for example, a servo motor.

Generally, the servo motor drives the advancing and retreating gear to rotate, and the rotating advancing and retreating gear advances and retreats back and forth along the advancing and retreating rack in the advancing and retreating direction to drive the base, the bearing body on the base and the silicon rod to move forwards and backwards. For example, the servo motor drives the advancing and retreating gear to rotate forward, the advancing and retreating gear rotating forward moves forward (i.e. towards the waiting position) along the advancing and retreating rack in the advancing and retreating direction, and drives the base and the bearing body thereon and the silicon rod to move forward (i.e. towards the waiting position). The servo motor drives the advancing and retreating gear to rotate reversely, the advancing and retreating gear which rotates reversely moves backwards (namely deviates from the waiting area) along the advancing and retreating rack in the advancing and retreating direction, and the base, the bearing body on the base and the silicon rod are driven to move backwards (namely deviates from the waiting area).

In certain implementations, the advancing and retracting mechanism includes: the driving mechanism comprises a transmission screw and a forward and backward driving source, wherein the transmission screw is arranged along a forward and backward direction and is associated with the base, and the forward and backward driving source is associated with the transmission screw. The drive source may be, for example, a servo motor.

Generally, the servo motor drives the transmission screw to rotate, and the rotating transmission screw drives the associated base, the bearing body on the base and the silicon rod to move forward and backward along the advancing and retreating direction. For example, the servo motor drives the transmission screw to rotate forward, and the transmission screw rotating forward drives the base and the supporting body thereon and the silicon rod to move forward (i.e. towards the waiting position). The servo motor drives the transmission screw rod to rotate reversely, and the transmission screw rod rotating reversely drives the base, the bearing body on the base and the silicon rod to move backwards (i.e. away from the waiting zone bit).

In addition, in some embodiments, the advancing and retreating mechanism may further include an auxiliary structure, for example, a guide rail may be further provided on the mounting structure, or a guide rail may be further provided on the mounting structure and a slider engaged with the guide rail may be provided on the base. In certain implementations, the sliders are disposed on opposite sides of the base and cooperate with guide rails on the mounting structure.

In the silicon rod handling device of the application, the supporting body is including locating the end of bearing the weight of the base spare, hold in the palm the end spare and be used for when first form silicon rod or second form silicon rod are in the second and place the state bearing first form silicon rod or second form silicon rod. In this embodiment, the second placement state is a vertical placement state, and therefore, the bottom supporting member is used for supporting the first or second silicon rod when the first or second silicon rod is in the second placement state, which means that the bottom supporting member is used for supporting the bottom of the first or second silicon rod when the first or second silicon rod is in the vertical placement state.

In some embodiments, the bottom supporting member includes a bottom supporting base and a bottom supporting structure provided on the bottom supporting base for supporting an end portion of the first form silicon rod and an end portion of the second form silicon rod, and the bottom supporting structure can be used for supporting the end portion of the first form silicon rod or the end portion of the second form silicon rod in a vertical position in different scenes.

In some implementations, the support base may include two support forks arranged oppositely, the support base structure includes a support rib arranged on the support forks, and the support rib on the two support forks is in contact with the end portion of the first form silicon rod or the end portion of the second form silicon rod when the support base is used to support the end portion of the first form silicon rod or the second form silicon rod which is vertically placed. The support fork and the support base rib are only exemplary, and in other implementations, the support base and the support base structure may still adopt other forms, for example, the support base may include a support base plate, and the support base rib may include a support base bump or a support base bump array.

In addition, the bottom support in the silicon rod loading and unloading device can be designed to be telescopic.

In some examples, two of the support forks in the bottom piece can share a telescopic mechanism or each support fork can be individually configured with a telescopic mechanism, so as to realize the telescopic action of the two support forks in the bottom piece and the support ribs thereon relative to the bearing seat. The telescopic mechanism may include a cylinder with a telescopic rod, for example, the cylinder is disposed on the carrying seat, and the telescopic rod connects the cylinder and the fork.

The telescopic action of the two support forks in the support bottom piece and the support bottom ribs on the support forks relative to the bearing seat specifically comprises the telescopic action of the support forks relative to the bearing seat along the length direction of the bearing seat, for example, the stretching action of the support forks far away from the bearing seat along the length direction of the bearing seat and the contraction action of the support forks close to the bearing seat along the length direction of the bearing seat. In this way, the supporting fork and the supporting bottom rib thereon can have at least two adjusting positions, for example, a first adjusting position and a second adjusting position, the first adjusting position is closer to the bearing seat than the second adjusting position, that is, when the bearing body is in the second adjusting position, for example, the vertical position, the first adjusting position is higher than the second adjusting position.

In practical applications, taking the silicon rod loading as an example, when the silicon rod loading and unloading device is used to load a silicon rod to be processed to a waiting position of the silicon rod processing platform, a first shape silicon rod (for example, a silicon rod with a circular cross section) is placed on the first bearing member in a first placement state (for example, a horizontal placement state); the supporting body is turned over by the turning mechanism, so that the supporting body is turned over relative to the base by the turning mechanism to convert the supported first-form silicon rod in a first placing state (for example, a horizontal placing state) into a second placing state (for example, a vertical placing state), when the first-form silicon rod is converted to the second placing state, the first-form silicon rod is supported by a bottom supporting piece arranged at the tail end of the supporting seat, at the moment, a supporting fork and a supporting bottom rib in the bottom supporting piece are positioned at a first adjusting position, wherein the height of a support fork and a support rib in the support bottom part at the first adjusting position is higher than the height of a table top of a rotary bearing table in the silicon rod positioning mechanism at the waiting position, namely, a first-form silicon rod supported by a support fork and a support bottom rib in the support bottom part at a first adjusting position is positioned above the table top of a rotary bearing table in the silicon rod positioning mechanism at a waiting position; and driving a support fork and a support bottom rib in the support bottom part to extend away from the bearing seat along the length direction of the bearing seat by using the telescopic mechanism so as to move towards a second adjusting position (the height of the second adjusting position is lower than the height of a table top of a rotary bearing table in the silicon rod positioning mechanism at the waiting position), namely, descending a first-form silicon rod supported by the support fork and the support bottom rib so that the first-form silicon rod is positioned on the table top of the rotary bearing table in the silicon rod positioning mechanism at the waiting position.

Correspondingly, when the silicon rod loading and unloading device is used for unloading the processed silicon rod from the waiting position of the silicon rod processing platform, a second-shape silicon rod (for example, a silicon rod with a rectangular-like cross section) is placed on a rotary bearing table in the silicon rod positioning mechanism at the waiting position in a second placing state (for example, a vertical placing state), and a first bearing piece in the bearing body is exposed after swinging outwards; moving a silicon rod loading and unloading device to a waiting position, wherein a bearing body of the silicon rod loading and unloading device is located at a second position such as a vertical position, and a bottom supporting part of the bearing body in the silicon rod loading and unloading device is located at a second adjusting position and is located below the rotary bearing table; the supporting body is directly turned over by the turning mechanism, so that the supporting body is turned over relative to the base by the turning mechanism, so that the bottom end of the second silicon rod is supported by the bottom supporting piece in the turning process, and the second silicon rod is leaned against the supporting body, or the telescopic mechanism is firstly utilized to drive the supporting fork and the supporting rib in the bottom supporting piece to do contraction motion close to the bearing seat along the length direction of the bearing seat, so that the supporting fork and the supporting rib in the bottom supporting piece tend to a first adjusting position from a second adjusting position (the height of the first adjusting position is higher than that of a second adjusting position in the vertical direction and the height of the table top of the rotary bearing table in the silicon rod positioning mechanism at a waiting position) until the supporting of the second silicon rod on the rotary bearing table is abutted against the supporting (in some implementation manners, the second silicon rod on the rotary bearing table can also be ejected and lifted so as to be separated from the rotary bearing table) Then, the supporting body is turned over through the turning mechanism, so that the supporting body is turned over relative to the base through the turning mechanism, and the second-form silicon rod leans against a conveying device of a second supporting member in the supporting body; finally, the carrier is turned over relative to the base by the turning mechanism, and the second position (for example, a vertical position) is converted into the first position (for example, a horizontal position), and the second silicon rod carried by the carrier is unloaded from the rotary carrier and is converted from the second placement state (for example, a vertical placement state) into the first placement state (for example, a horizontal placement state), and is unloaded by the conveying device of the second carrier.

In some examples, the bottom ribs of the two forks in the bottom supporting member can be respectively provided with a telescopic mechanism so as to realize the telescopic action of the bottom ribs of the two forks in the bottom supporting member relative to the bearing seat. The telescopic mechanism may include a cylinder having a telescopic rod, for example, the cylinder is disposed on the support fork, and the telescopic rod connects the cylinder and the support bottom rib.

The last support end rib of towing fork is relative tow fork do flexible action specifically include support end rib on the support fork is along the length direction of bearing the seat is relative the support fork does flexible action, for example, along the length direction who bears the seat keeps away from the action of stretching out of support fork (be close to bear the seat promptly) and along the length direction who bears the seat is close to the shrink action of support fork (be close to bear the seat promptly). In this way, the base rib of the fork can have at least two adjustment positions, for example, a first adjustment position and a second adjustment position, by means of the telescopic mechanism, the first adjustment position being closer to the carrier than the second adjustment position (i.e., the first adjustment position being further from the fork than the second adjustment position).

In practical applications, taking the silicon rod loading as an example, when the silicon rod loading and unloading device is used to load a silicon rod to be processed to a waiting position of the silicon rod processing platform, a first shape silicon rod (for example, a silicon rod with a circular cross section) is placed on the first bearing member in a first placement state (for example, a horizontal placement state); the supporting body is turned over by the turning mechanism, so that the supporting body is turned over relative to the base by the turning mechanism to convert the supported first-form silicon rod in a first placing state (for example, a horizontal placing state) into a second placing state (for example, a vertical placing state), when the first-form silicon rod is converted to the second placement state, the first-form silicon rod is supported by a bottom supporting rib in a bottom supporting piece arranged at the tail end of the bearing seat, at the moment, the bottom supporting rib in the bottom supporting piece is positioned at a first adjusting position, wherein the height of the bottom supporting rib in the bottom supporting piece at the first adjusting position is higher than the height of the table top of the rotary bearing table in the silicon rod positioning mechanism at the waiting position, namely, the first-form silicon rod supported by the bottom supporting rib in the bottom supporting piece at the first adjusting position is positioned above the table top of the rotary bearing table in the silicon rod positioning mechanism at the waiting position; and driving a support bottom rib in the support bottom part to perform contraction action close to the support fork (namely, to be far away from the bearing seat) along the length direction of the bearing seat by utilizing the telescopic mechanism so as to move towards a second adjusting position (the height of the second adjusting position is lower than the height of a table top of a rotary bearing table in the silicon rod positioning mechanism at the waiting position), namely, descending a first-form silicon rod supported by the support bottom rib so that the first-form silicon rod is positioned on the table top of the rotary bearing table in the silicon rod positioning mechanism at the waiting position.

Correspondingly, when the silicon rod loading and unloading device is used for unloading the processed silicon rod from the waiting position of the silicon rod processing platform, a second-shape silicon rod (for example, a silicon rod with a rectangular-like cross section) is placed on a rotary bearing table in the silicon rod positioning mechanism at the waiting position in a second placing state (for example, a vertical placing state), and a first bearing piece in the bearing body is exposed after swinging outwards; moving a silicon rod loading and unloading device to a waiting position, wherein a supporting body of the silicon rod loading and unloading device is located at a second position, such as a vertical position, and a bottom supporting rib of a bottom supporting piece in the supporting body is located at a second adjusting position and is located below the rotary bearing table; the supporting body is directly turned over by the turning mechanism, so that the supporting body is turned over relative to the base by the turning mechanism, so that the bottom supporting rib of the bottom supporting member supports the bottom end of the second-state silicon rod in the turning process and the second-state silicon rod leans against the supporting body, or the telescopic mechanism is firstly utilized to drive the bottom supporting rib in the bottom supporting member to perform a stretching action far away from the supporting fork (i.e. close to the supporting seat) along the length direction of the supporting seat so that the bottom supporting rib in the bottom supporting member tends to a first adjusting position from a second adjusting position (the height of the first adjusting position is higher than the height of the second adjusting position in the vertical direction and the height of the table top of the rotary supporting table in the silicon rod positioning mechanism at the waiting position) until the bottom supporting rib abuts against the second-state silicon rod on the rotary supporting table (in some implementation manners, the second shape silicon rod on the rotary bearing table can be ejected and lifted to be separated from the rotary bearing table), and then the bearing body is turned over through the turning mechanism, so that the bearing body is turned over relative to the base through the turning mechanism, and the second shape silicon rod leans against a conveying device of a second bearing piece in the bearing body; finally, the carrier is turned over relative to the base by the turning mechanism from the second position (e.g., vertical position) to the first position (e.g., horizontal position), and the second form of the silicon rods carried by the carrier is unloaded from the rotary carrier and is changed from the second resting state (e.g., vertical resting state) to the first resting state (e.g., horizontal resting state), and is unloaded by the conveying device of the second carrier.

In some embodiments, as shown in fig. 3, the bottom supporting member 537 comprises a bottom supporting base 5371, and a first bottom supporting structure 5373 and a second bottom supporting structure 5375, which are disposed on the bottom supporting base, for supporting the end of the first configuration silicon rod and the end of the second configuration silicon rod, i.e., the first bottom supporting structure 5373 is used for supporting the end of the vertically disposed first configuration silicon rod, and the second bottom supporting structure 5375 is used for supporting the end of the vertically disposed second configuration silicon rod.

In some implementations, the support base may include two support forks disposed opposite to each other, the first support base structure may include two first support base ribs, and the two first support base ribs are respectively disposed on the two support forks. In this embodiment, the first shape silicon rod may be, for example, a silicon rod with a circular cross section, and the second shape silicon rod may be, for example, a silicon rod with a rectangular cross section, which is formed after the silicon rod with a circular cross section is subjected to the open-side cutting operation, that is, the cross-sectional dimension of the silicon rod with a circular cross section is greater than that of the silicon rod with a rectangular cross section, so that the two first support bottom ribs as the first support bottom structures are located outside the two second support bottom ribs as the second support bottom structures. When the bottom supporting piece is used for supporting the end part of the vertically placed first-form silicon rod, the first bottom supporting ribs on the two supporting forks are in contact with the end part of the first-form silicon rod, and when the bottom supporting piece is used for supporting the end part of the vertically placed second-form silicon rod, the second bottom supporting ribs on the two supporting forks are in contact with the end part of the second-form silicon rod. The support fork, the first support bottom rib, and the second support bottom rib are merely exemplary illustrations, and in other implementations, the support base, the first support bottom rib, and the second support bottom rib may still adopt other forms, for example, the support base may include a support chassis, the first support bottom rib may include a first support bottom bump or a first support bottom bump array, and the second support bottom rib may include a second support bottom bump or a second support bottom bump array.

In addition, the bottom support in the silicon rod loading and unloading device can be designed to be telescopic.

In some examples, the first support ribs of the two support forks of the bottom support member may be respectively configured with a telescopic mechanism to realize the telescopic action of the first support ribs of the two support forks of the bottom support member relative to the load-bearing seat. Wherein, telescopic machanism can include the cylinder that has the telescopic link, for example, the cylinder is located hold in the palm on the fork, the telescopic link is connected the cylinder with first support end rib.

First support end rib on two support forks in the support end piece is relative bear the seat and do flexible action specifically include first support end rib on the support fork is along the length direction who bears the seat is relative the support fork does flexible action, for example, along the length direction who bears the seat keeps away from the support fork (i.e. be close to bear the seat) stretch out the action and along the length direction who bears the seat is close to the shrink action (i.e. keep away from) that holds in the palm the fork. As such, a first support base rib on the support fork can have at least two adjustment positions, e.g., a first adjustment position and a second adjustment position, by a telescoping mechanism, the first adjustment position being closer to the load-bearing seat than the second adjustment position (i.e., the first adjustment position being farther from the support fork than the second adjustment position), and the second support base rib being between the first adjustment position and the second adjustment position, i.e., the first support base rib being protruded from the second support base rib at the first adjustment position and the first support base rib being recessed in the second support base rib at the second adjustment position.

In practical applications, taking the silicon rod loading as an example, when the silicon rod loading and unloading device is used to load a silicon rod to be processed to a waiting position of the silicon rod processing platform, a first shape silicon rod (for example, a silicon rod with a circular cross section) is placed on a first bearing member in a first placement state (for example, a horizontal placement state) (at this time, a bearing member of the silicon rod loading and unloading device is in a first position, for example, a horizontal position); the supporting body is turned over through the turning mechanism, so that the supporting body is turned over relative to the base through the turning mechanism to convert the supported first-form silicon rod in a first placing state (for example, a horizontal placing state) into a second placing state (for example, a vertical placing state), when the first-form silicon rod is converted into the second placing state, the first-form silicon rod is supported and supported by a first supporting rib in a supporting piece arranged at the tail end of the supporting seat, at the moment, a first supporting rib in the supporting piece is positioned at a first adjusting position and protrudes out of a second supporting rib, wherein the height of the first supporting rib in the supporting piece at the first adjusting position is higher than the table top height of a rotary supporting table in a silicon rod positioning mechanism at a waiting position (the height of the second supporting rib is lower than the table top height of the rotary supporting table), namely, a first-form silicon rod supported by a first support bottom rib in the support bottom part at a first adjusting position is positioned above a table top of a rotary bearing table in a silicon rod positioning mechanism at a waiting position; the telescopic mechanism is utilized to drive a first support bottom rib in the support bottom part to perform a contraction action (namely, to be far away from the bearing seat) close to the support fork along the length direction of the bearing seat so as to move towards a second adjusting position (the height of the second adjusting position is lower than the height of a table top of a rotary bearing table in the silicon rod positioning mechanism at the waiting position), namely, a first-form silicon rod supported by the first support bottom rib is descended so that the first-form silicon rod is positioned on the table top of the rotary bearing table in the silicon rod positioning mechanism at the waiting position.

Correspondingly, when the silicon rod loading and unloading device is used for unloading the processed silicon rod from the waiting position of the silicon rod processing platform, a second-shape silicon rod (for example, a silicon rod with a rectangular-like cross section) is placed on a rotary bearing table in the silicon rod positioning mechanism at the waiting position in a second placing state (for example, a vertical placing state), and a first bearing piece in the bearing body is exposed after swinging outwards; moving the silicon rod handling device to a waiting position, wherein a supporting body of the silicon rod handling device is at a second position, such as a vertical position, a first bottom supporting rib of a bottom supporting part in the supporting body is at a second adjusting position and is located below the rotary bearing table together with the first bottom supporting rib, and at the moment, the height of the second bottom supporting rib is higher than that of the first bottom supporting rib at the second adjusting position but lower than the table top height of the rotary bearing table; directly overturning the supporting body through the overturning mechanism, so that the supporting body is overturned relative to the base through the overturning mechanism, so that the second bottom supporting rib of the bottom supporting piece supports the bottom end of the second silicon rod in the overturning process, and the second silicon rod in the second shape leans against a conveying device of a second supporting piece in the supporting body; finally, the carrier is turned over relative to the base by the turning mechanism, and the second position (for example, a vertical position) is converted into the first position (for example, a horizontal position), and the second silicon rod carried by the carrier is unloaded from the rotary carrier and is converted from the second placement state (for example, a vertical placement state) into the first placement state (for example, a horizontal placement state), and is unloaded by the conveying device of the second carrier.

Utilize silicon rod handling device in this application, including the base with can overturn and locate the supporting body of base, the supporting body has first carrier and the second carrier, usable first carrier and the second carrier come to bear the silicon rod of different forms respectively to do the upset through the drive supporting body and place the conversion between the state with the silicon rod that bears at present between the difference, thereby can realize the operation of loading of the silicon rod of treating processing and the uninstallation operation of the silicon rod of processing simultaneously, device overall structure is simple, improve work efficiency and save cost.

The silicon rod processing equipment at least comprises a cutting device, and is used for performing squaring and cutting operation on a silicon rod so as to cut the silicon rod with a circular cross section into a silicon rod with a rectangular-like cross section.

In certain embodiments, the silicon rod processing apparatus is a silicon rod squarer for squaring and cutting silicon rods, whereby, in the silicon rod squarer, the silicon rod processing platform comprises a cutting zone, wherein the cutting zone may comprise one or more zones.

In certain embodiments, the silicon rod processing platform comprises a cutting zone and the silicon rod squarer comprises a cutting device comprising a cutting unit for squaring and cutting a silicon rod at the respective cutting zone, wherein the cutting unit may comprise four cutting wire saws or two cutting wire saws.

Taking four cutting wires as an example, two adjacent cutting wires are perpendicular to each other and two opposite cutting wires are parallel to each other. Specifically, the four cutting wires can be, for example, a first cutting wire saw, a second cutting wire saw, a third cutting wire saw, and a fourth cutting wire saw, wherein the first cutting wire saw and the third cutting wire saw are parallel to each other, the second cutting wire saw and the fourth cutting wire saw are parallel to each other, and the first cutting wire saw and the third cutting wire saw are perpendicular to the second cutting wire saw and the fourth cutting wire saw. From the above, the first cutting wire saw, the second cutting wire saw, the third cutting wire saw and the fourth cutting wire saw are matched to form the cutting wire net in the shape of a Chinese character jing. When adopting four cutting coping saws among the above-mentioned implementation to carry out the operation of evolution cutting to the silicon rod, the order cutting twine net that is formed by four cutting coping saws in the cutting unit is at the cutting silicon rod of removal in-process, makes the silicon rod forms the silicon rod that the cross-section is similar to the rectangle after being cut and is located four flaw-edges around the silicon rod, wherein, each cutting coping saw forms a side section and a flaw-edge on the silicon rod after cutting the silicon rod.

Taking two cutting wire saws as an example, in one example, the two cutting wire saws are parallel to each other, and the two parallel cutting wire saws are used for cutting the silicon rod to be cut at the cutting position so as to form two parallel side cutting surfaces. The two mutually parallel cutting wires cooperate to form a cutting wire web in the form of an "═" or "|". When the silicon rod is cut by the two parallel cutting wire saws in the implementation mode, the cutting wire net which is formed by the two parallel cutting wire saws in the cutting unit cuts the silicon rod in the moving process so as to form two parallel side cutting surfaces and two side edges which are opposite. In another example, the two cutting wires are crossed with each other, and the crossing angle of the two cutting wires is 90 °, that is, the two cutting wires are orthogonal to each other, and the two orthogonal cutting wires cooperate to form a cutting wire net in a "+" shape or a "Γ" shape. When the two crossed cutting wire saws are used for cutting the silicon rod in the cutting mode, the silicon rod is cut by the crossed cutting wire nets formed by the two crossed cutting wire saws in the cutting unit in the moving process, so that two opposite crossed side cutting surfaces and two side edges are formed on the silicon rod.

In certain embodiments, in the silicon rod squarer, the silicon rod processing platform comprises a first cutting zone and a second cutting zone, the silicon rod squarer comprises a cutting device comprising a first cutting unit and a second cutting unit corresponding to the first cutting zone and the second cutting zone, respectively, or the silicon rod squarer comprises a first cutting device and a second cutting device comprising a first cutting unit corresponding to the first cutting zone and a second cutting unit corresponding to the second cutting zone, wherein the cutting unit comprises two cutting wire saws. In the silicon rod squarer, the silicon rod processing platform includes a waiting position, a first cutting position and a second cutting position, the number of the silicon rod positioning mechanisms on the conversion main body of the silicon rod conversion device can be three, which is consistent with the number of the functional positions, and the waiting position, the first cutting position and the second cutting position are uniformly distributed between two positions, for example, 120 degrees, that is, the three silicon rod positioning mechanisms on the conversion main body are also distributed between two positions at 120 degrees, so that the rotation angle range of the silicon rod conversion device is +/-240 degrees.

In one example, the two cutting wires are parallel to each other, and the two parallel cutting wires are used for cutting the silicon rod to be cut at the cutting position to form two parallel side cutting surfaces. The two mutually parallel cutting wires cooperate to form a cutting wire web in the form of an "═" or "|". When the two parallel cutting wire saws in the implementation mode are used for cutting the silicon rod in an evolution mode, the ═ or | | | "type cutting wire net formed by the two parallel cutting wire saws in the cutting unit cuts the silicon rod in a moving process, so that two parallel side cutting surfaces and two side edges are formed on the silicon rod. In another example, the two cutting wires are crossed with each other, and the crossing angle of the two cutting wires is assumed to be 90 °, that is, the two cutting wires are orthogonal to each other, and the two orthogonal cutting wires cooperate to form a cutting wire web in a shape of "+" or "Γ". When the two crossed cutting wire saws in the implementation mode are adopted to perform squaring and cutting operation on the silicon rod, the silicon rod is cut by the crossed cutting wire nets formed by the two crossed cutting wire saws in the cutting unit in the moving process, so that two opposite crossed side cutting surfaces and two edge skins are formed on the silicon rod.

In some embodiments, the silicon rod processing apparatus is a silicon rod cutting and grinding all-in-one machine for cutting and grinding a silicon rod, and therefore, in the silicon rod cutting and grinding all-in-one machine, the silicon rod processing platform comprises a cutting area and a grinding area.

The cutting location can comprise one or more locations.

In some embodiments, the silicon rod processing platform comprises a cutting zone and the silicon rod slicing and grinding all-in-one machine comprises a cutting device, the cutting device comprises a cutting unit, the cutting unit is used for conducting cutting operation of the silicon rod at the corresponding cutting zone, wherein the cutting unit can comprise four cutting wire saws or two cutting wire saws. In one example, the four cutting wire saws are matched to form a cutting wire net in a shape like a Chinese character 'jing', and are used for cutting the silicon rod to form a silicon rod with a rectangular-like cross section and four side skins positioned on the periphery of the silicon rod. In another example, the two cutting wires are parallel to each other and cooperate to form a cutting wire web of the type "═" or "|", in order to form two parallel side cutting planes and two edges on the silicon rod after cutting the silicon rod. In a further example, the two cutting wires are orthogonal to each other and cooperate to form a cutting wire web in a "+" or "Γ" shape for forming two opposing intersecting side cuts and two sidebands on the silicon rod after cutting the silicon rod.

In certain embodiments, the silicon rod processing platform comprises a first cutting area and a second cutting area, the silicon rod cutting and grinding all-in-one machine comprises a cutting device, the cutting device comprises a first cutting unit and a second cutting unit corresponding to the first cutting area and the second cutting area respectively, or the silicon rod cutting and grinding all-in-one machine comprises a first cutting device and a second cutting device, the first cutting device comprises a first cutting unit corresponding to the first cutting area, the second cutting device comprises a second cutting unit corresponding to the second cutting area, and the cutting units are used for cutting and squaring the silicon rod at the corresponding cutting areas. Wherein the cutting unit may include two cutting wires. In one example, the two cutting wires are parallel to each other, and the two parallel cutting wires are used for cutting the silicon rod to be cut at the cutting position to form two parallel side cutting surfaces. The two mutually parallel cutting wires cooperate to form a cutting wire web in the form of an "═" or "|". When the silicon rod is cut by the two parallel cutting wire saws in the implementation mode, the cutting wire net which is formed by the two parallel cutting wire saws in the cutting unit cuts the silicon rod in the moving process so as to form two parallel side cutting surfaces and two side edges which are opposite. In another example, the two cutting wires are crossed with each other, and the crossing angle of the two cutting wires is 90 °, that is, the two cutting wires are orthogonal to each other, and the two orthogonal cutting wires cooperate to form a cutting wire net in a "+" shape or a "Γ" shape. When the two crossed cutting wire saws are used for cutting the silicon rod in the cutting mode, the silicon rod is cut by the crossed cutting wire nets formed by the two crossed cutting wire saws in the cutting unit in the moving process, so that two opposite crossed side cutting surfaces and two side edges are formed on the silicon rod.

The milling zone can comprise one or more zones.

In certain embodiments, the silicon rod processing platform comprises a grinding zone and the silicon rod cutting and grinding machine comprises a grinding device comprising a grinding unit for grinding the silicon rod at the respective grinding zone.

In certain embodiments, the silicon rod processing platform comprises a first grinding zone and a second grinding zone, the silicon rod cutting and grinding all-in-one machine comprises a grinding device and the grinding device comprises a first grinding unit and a second grinding unit corresponding to the first grinding zone and the second grinding zone respectively, or the silicon rod cutting and grinding all-in-one machine comprises a first grinding device and a second grinding device and the first grinding device comprises a first grinding unit corresponding to the first grinding zone and the second grinding device comprises a second grinding unit corresponding to the second grinding zone, and the silicon rod at the corresponding grinding zone is ground by the grinding units.

In the embodiment as shown in fig. 1 and 2, the silicon rod processing device is a silicon rod cutting and grinding all-in-one machine, wherein the silicon rod processing platform comprises a waiting zone, a first cutting zone, a second cutting zone and a grinding zone, and therefore the silicon rod cutting and grinding all-in-one machine comprises a cutting device and a grinding device. The number of the silicon rod positioning mechanisms on the conversion main body of the silicon rod conversion device can be four, the number of the silicon rod positioning mechanisms is consistent with that of the functional zone bits, the waiting zone bits, the first cutting zone bits, the second cutting zone bits and the grinding zone bits are uniformly distributed between every two silicon rod positioning mechanisms, for example, the silicon rod positioning mechanisms are distributed at 90 degrees, namely, the four silicon rod positioning mechanisms on the conversion main body are distributed at 90 degrees between every two silicon rod positioning mechanisms, and therefore, the rotation angle range of the silicon rod conversion device is +/-270 degrees.

The cutting device is arranged at the cutting position of the silicon rod processing platform and used for performing squaring and cutting operation on the silicon rod so as to cut the silicon rod with a circular cross section into a square silicon rod with a rectangular-like cross section.

As mentioned above, the cutting device may comprise mutually parallel cutting wires or mutually orthogonal cutting wires. In the following description, the cutting device includes two cutting wires, and the two cutting wires are perpendicular to each other.

In certain embodiments, the silicon rod slicing and grinding all-in-one machine comprises a cutting device comprising a cutting unit, and correspondingly, the silicon rod processing platform comprises a cutting zone. When the cutting device is used for conducting cutting operation on the silicon rod, the cutting unit is firstly utilized to conduct first folding cutting on the silicon rod to be cut at the cutting position to form two orthogonal side faces, then the position of the silicon rod to be cut is converted or the position of the cutting unit is converted, then the cutting unit is utilized to conduct second folding cutting on the silicon rod to be cut at the cutting position to form two orthogonal side faces, and therefore the cross section of the silicon rod to be cut is rectangular.

In some embodiments, the silicon rod cutting and grinding all-in-one machine comprises two cutting devices, wherein each cutting device comprises at least one cutting unit, for example, the silicon rod cutting and grinding all-in-one machine comprises a first cutting device and a second cutting device, wherein the first cutting device comprises a first cutting unit, the second cutting device comprises a second cutting unit, and correspondingly, the silicon rod processing platform comprises a first cutting area corresponding to the first cutting device and a second cutting area corresponding to the second cutting device. When the silicon rod is subjected to squaring and cutting operation, a first cutting unit in a first cutting device is used for carrying out first folding cutting on the silicon rod to be cut at a first cutting position to form two orthogonal side faces, then the position of the silicon rod to be cut is converted to a second cutting position from the first cutting position, and then a second cutting unit in a second cutting device is used for carrying out second folding cutting on the silicon rod to be cut at the second cutting position to form two orthogonal side faces, so that the section of the silicon rod to be cut is rectangular.

In certain embodiments, the silicon rod cutting and grinding all-in-one machine comprises a cutting device, the cutting device comprises a first cutting unit and a second cutting unit, and correspondingly, the silicon rod processing platform comprises a first cutting area corresponding to the first cutting unit and a second cutting area corresponding to the second cutting unit. When the silicon rod is subjected to squaring and cutting operation, the first cutting unit is firstly utilized to perform first folding cutting on the silicon rod to be cut at the first cutting position to form two orthogonal side faces, then the position of the silicon rod to be cut is converted to the second cutting position from the first cutting position, and then the second cutting unit is utilized to perform second folding cutting on the silicon rod to be cut at the second cutting position to form two orthogonal side faces, so that the section of the silicon rod to be cut is in a similar rectangular shape.

The embodiment of the cutting device including two cutting wires parallel to each other is similar to the structure and usage of the cutting wires perpendicular to each other, and therefore, the description thereof is omitted.

In the embodiment shown in fig. 1, the silicon rod processing platform of the silicon rod cutting and grinding all-in-one machine comprises a first grinding location and a second grinding location, the silicon rod cutting and grinding all-in-one machine comprises a cutting device 2, and the cutting device 2 further comprises a first cutting unit and a second cutting unit. The cutting device 2 is arranged on the base 1 and is used for performing first folding cutting on the silicon rod 100 in a first cutting area of the silicon rod processing platform and performing second folding cutting on the silicon rod 100 in a second cutting area of the silicon rod processing platform to form a silicon rod with a rectangular-like cross section. Wherein either of the first and second facet cuts are cuts made to the silicon rod to form two orthogonal sides.

Referring to fig. 1 and 2, in the silicon rod slicing and grinding all-in-one machine, a cutting device 2 includes: a cutting frame 21, a cutting support 22, a first cutting unit 23, and a second cutting unit 25.

The cutting frame 21 is arranged on the machine base 1. In the present embodiment, the cutting frame 21 is a column structure or a frame structure, and serves as a support body of the cutting device 2, and can provide support for other components in the cutting device 2. As shown in fig. 2, the cutting frame 21 is located between the first cutting location and the second cutting location.

The cutting support 22 is arranged on the cutting frame 21 in a lifting manner by a lifting mechanism. In some embodiments, the lifting mechanism may include a mechanism that can realize the vertical movement of the cutting support 22, such as a lifting motor and a lifting rail, wherein the lifting rail is vertically disposed on the cutting frame 21, and in order to realize the stable lifting of the cutting support 22 on the mounting structure of the machine base 1, a dual-rail design may be adopted, that is, two lifting rails are adopted, and the two lifting rails are disposed in parallel. The cutting support 22 can be moved up and down relative to the cutting frame 21 and the machine base 1 by means of a lifting guide rail, driven by the lifting motor (which can be, for example, a servo motor). In some embodiments, the lifting mechanism may further include a lifting block that may be disposed on the back of the cutting support 22 and cooperate with a lifting rail.

In the present embodiment, since the cutting support 22 may be provided with the first cutting unit 23 and the second cutting unit 25, that is, the first cutting unit 23 and the second cutting unit 25 share the cutting support 22. Thus, in the present embodiment, on the one hand, the cutting carriage 21 and the cutting support 22 in the cutting device 2 are provided in a central position between the first cutting location and the second cutting location. On the other hand, the cutting support 22 is specially designed. The cutting support 22 in this embodiment may include a support body and first and second support wings located on opposite lateral sides of the support body.

Referring to fig. 9, a top view of a cutting device of a silicon rod slicing and grinding all-in-one machine according to an embodiment of the present disclosure is shown.

Referring to fig. 1, 2 and 9, the first cutting unit 23 is disposed at a first side of the cutting support 22, and is configured to perform a first folding cutting on the silicon rod at a first cutting location of the silicon rod processing platform.

In the present embodiment, as described above, the cutting holder 22 includes a holder main body and first and second holder side wings located on opposite sides of the holder main body, and thus the first cutting unit 23 is mounted at the first holder side wings of the cutting holder 22. Specifically, the first cutting unit 23 includes a first wire frame 231 disposed on a side of the first holder, a plurality of first cutting wheels 233 disposed on the first wire frame 231, and a first cutting wire 235, wherein the first cutting wire 235 sequentially winds the plurality of first cutting wheels 233 to form two orthogonal first cutting wires.

In practical applications, the first cutting unit 23 may comprise at least four first cutting wheels 233, and the four first cutting wheels 233 may be combined into two orthogonal first cutting wheel sets, that is, one first cutting wheel set is formed by arranging two first cutting wheels along the M axis, and one first cutting wheel set is formed by two first cutting wheel sets along the N axis, wherein the M axis is orthogonal to the N axis. In particular, the first cutting unit 23 comprises two orthogonal sets of first cutting wheels, wherein one set of first cutting wheels comprises two first cutting wheels 233 arranged along the M axis and the other set of first cutting wheels comprises two first cutting wheels 233 arranged along the N axis.

The first cutting lines 235 are sequentially wound around the first cutting wheels 233 of the first cutting unit 23 to form a first wire mesh. In practical applications, the first cutting wire 235 sequentially winds around the four first cutting wheels 233 in the first cutting unit 23 to form two mutually orthogonal first cutting wire saws, which form a first cutting wire web. Specifically, the first cutting wire 235 forms one first cutting wire saw by being wound around two first cutting wheels 233 arranged along the M axis in one first cutting wheel set, and the first cutting wire 235 forms another second cutting wire saw by being wound around two first cutting wheels 233 arranged along the N axis in the other first cutting wheel set. Thus, the two mutually orthogonal first cutting wire saws are matched to form a first cutting wire net in a shape of a plus or a T.

Of course, the first cutting unit 23 is not limited to the embodiments shown in fig. 1, fig. 2 and fig. 9, and other variations can be made in other embodiments.

In the present embodiment, the first cutting unit 23 may further include a transition wheel 234 for implementing transition guiding of the first cutting line 235. The transition wheels 234 may not be limited to one, and may be disposed on the first bobbin 231 and/or the first holder wing, for example, in some embodiments, some of the transition wheels 234 may be disposed on the first bobbin 231, in some embodiments, some of the transition wheels 234 may be disposed on the first holder wing, in some embodiments, some of the transition wheels 234 may be disposed on the first bobbin 231, and some of the transition wheels 234 may be disposed on the first holder wing.

In addition, in some embodiments, the first cutting unit 23 may further include a tension pulley provided on the first string frame 231 and/or the first holder side wing for performing tension adjustment of the first cutting string 235.

The second cutting unit 25 is disposed at a second side of the cutting support 22, and is configured to perform a second plane-folding cutting on the silicon rod 100 at a second processing location of the silicon rod processing platform.

In the present embodiment, as previously described, the cutting support 22 includes a support body and first and second support wings located on opposite sides of the support body, and thus the second cutting unit 25 is mounted at the second support wing of the cutting support 22. Specifically, the second cutting unit 25 includes a second wire rack 251 disposed on the second support wing, a plurality of second cutting wheels 253 disposed on the second wire rack 251, and a second cutting wire 255, and the second cutting wire 255 sequentially winds around the plurality of second cutting wheels 253 to form two orthogonal second cutting wire saws.

In practical applications, the second cutting unit 25 may include at least four second cutting wheels 253, and the four second cutting wheels 253 can be combined into two orthogonal second cutting wheel sets, that is, two second cutting wheel sets are oppositely disposed along the M axis to form one second cutting wheel set, and two second cutting wheel sets are oppositely disposed along the N axis to form one second cutting wheel set, wherein the M axis is orthogonal to the N axis. In particular, the second cutting unit 25 comprises two orthogonal sets of second cutting wheels, one set comprising two second cutting wheels 253 arranged along the M axis and the other set comprising two second cutting wheels 253 arranged along the N axis.

The second cutting lines 255 sequentially wind around each of the second cutting wheels 253 of the second cutting unit 25 to form a second cutting line net. In practical applications, the second cutting line 255 sequentially winds around the four second cutting wheels 253 of the second cutting unit 25 to form two second cutting wire saws orthogonal to each other, thereby forming a second cutting wire web. Specifically, the second cutting line 255 forms one second cutting wire saw around two second cutting wheels 253 arranged along the M axis in one second cutting wheel group, and the second cutting line 255 forms another second cutting wire saw around two second cutting wheels 253 arranged along the N axis in another second cutting wheel group. Thus, the two mutually orthogonal second cutting wire saws cooperate to form a second cutting wire web in a shape of a plus or a reverse.

Of course, the second cutting unit 25 is not limited to the embodiments shown in fig. 1, fig. 2 and fig. 9, and other variations can be made in other embodiments.

In this embodiment, the second cutting unit 25 may further include a transition wheel 254 for achieving transition guidance of the second cutting line 255. The transition wheels 254 may not be limited to one, and may be disposed on the first spool 231 and/or the first support wing, for example, in some embodiments, some of the transition wheels 254 may be disposed on the second spool 251, in some embodiments, some of the transition wheels 254 may be disposed on the second support wing, in some embodiments, some of the transition wheels 254 may be disposed on the second spool 251, and some of the transition wheels 254 may be disposed on the second support wing.

In addition, in some embodiments, the second cutting unit 25 may further comprise a tension wheel provided on the second string carrier 251 and/or on the second abutment flank for performing tension adjustment of the second cutting string 255.

In certain embodiments, the first cut line and the second cut line are the same cut line. The cutting device further comprises a take-up and pay-off unit. For example, the take-up and pay-off unit may include a take-up drum and a pay-off drum, which may be disposed on the base or the cutting frame.

In the embodiment shown in fig. 1, 2 and 9, the first cutting line 235 in the first cutting unit 23 and the second cutting line 255 in the second cutting unit 25 may be the same cutting line. In this case, the common cutting line is sequentially wound around the plurality of first cutting wheels 233 (and the transition wheels) provided in the first cutting unit 23 to form two orthogonal first cutting wire saws, and then transferred to the second cutting unit at the side to sequentially wind around the plurality of second cutting wheels 253 (and the transition wheels) provided in the second cutting unit 25 to form two orthogonal second cutting wire saws. In this embodiment, therefore, the cutting support 22 is also provided with one or more transition wheels between the first cutting unit 23 and the second cutting unit 25, around which the common cutting line is wound. Specifically, in the embodiment shown in fig. 4, an intermediate transition wheel 26 around which the common cutting line is wound is provided on the holder body 221 between the first cutting unit 23 and the second cutting unit 25 in the cutting holder 22.

In addition, in the embodiment shown in fig. 1, 2 and 9, the cutting device further includes a take-up and pay-off unit. For example, the wire winding and unwinding unit may include a wire winding drum and a wire winding drum, which may be disposed on the base 1 and located at opposite sides of the cutting frame 21, for winding and unwinding the common cutting wire.

The first cutting unit 23 and the second cutting unit 25 share the same cutting line, so that the structure of the cutting unit can be simplified (for example, a set of paying-off cylinder and a set of winding cylinder are omitted), the integrity is good, the winding process is simplified, the efficiency is improved, and the line tension and the like of the two cutting units can be better controlled.

In some embodiments, the first cutting unit and the second cutting unit in the cutting device are independent components, and then the cutting device further includes a first take-up and pay-off unit matched with the first cutting unit and a second take-up and pay-off unit matched with the second cutting unit, wherein the first take-up and pay-off unit includes a first pay-off drum and a first take-up drum which are arranged on the base or the cutting frame and are used for taking up and paying off the first cutting line, and the second take-up and pay-off unit includes a second pay-off drum and a second take-up drum which are arranged on the base or the cutting frame and are used for taking up and paying off the second cutting line.

Of course, other variations of the cutting line are possible than with a take-up and pay-off unit.

In some embodiments, the first cutting unit and the second cutting unit in the cutting device are independent parts, wherein for the first cutting unit, the first cutting line is wound around a plurality of first cutting wheels and first transition wheels to form a first closed loop cutting line in an end-to-end connection, and for the second cutting unit, the second cutting line is wound around a plurality of second cutting wheels and second transition wheels to form a second closed loop cutting line in an end-to-end connection. The first closed-loop cutting line and the second closed-loop cutting line can avoid the acceleration and deceleration processes of the cutting lines from influencing the cutting precision in the process of being operated to execute cutting, so that the cutting precision is improved, and the follow-up procedures are facilitated to be simplified.

In some embodiments, the first cutting line in the first cutting unit and the second cutting line in the second cutting unit may be the same cutting line. In this case, the common cutting line is wound around the plurality of first cutting wheels, the first transition wheel, the intermediate transition wheel, the plurality of second cutting wheels, and the second transition wheel to form a closed loop cutting line in end-to-end relationship. The closed-loop cutting line can avoid the influence of the acceleration and deceleration processes of the cutting line on the cutting precision in the process of running to execute cutting, so that the cutting precision is improved, and the subsequent procedures are facilitated to be simplified.

When the silicon rods at the first cutting area and the second cutting area of the silicon rod processing platform are cut by using the cutting device 2 in the embodiment shown in fig. 1, 2 and 9, the cutting support 22 is driven to descend relative to the cutting frame 21, the first cutting unit 23 and the second cutting unit 25 at the left and right sides of the cutting support 22 simultaneously cut the silicon rod at the corresponding first cutting position and the silicon rod at the corresponding second cutting position, wherein, the first cutting unit 23 performs a first folding cutting on the silicon rod at the first cutting zone (the first cutting unit 23 is provided with two orthogonal first cutting wire saws in a shape of a plus or a reversed L), and the second cutting unit 25 performs a second folding cutting on the silicon rod at the second cutting zone (the second cutting unit 25 is provided with two orthogonal second cutting wire saws in a shape of a plus or a reversed L). As can be seen, in the present embodiment, the first cutting unit 23 and the second cutting unit 25 of the cutting apparatus 2 share the cutting support 22, and the first cutting unit 23 and the second cutting unit 25 thereon can perform the first folding cutting on the silicon rod at the first cutting location and the second folding cutting on the silicon rod at the second cutting location, respectively, at the same time by driving the shared cutting support 22 to perform the lifting motion. The cutting device 2 is simple in structure on the whole, convenient to control and capable of improving the cutting efficiency and quality of the silicon rod.

It should be noted that, in some embodiments, the intersection point of the two orthogonal first cutting wire saws when the first folding cutting is performed on the silicon rod to be cut in the first cutting unit 23 is located in the cross section of the silicon rod to be cut (including the case that the intersection point is located on the circumference of the cross section), and the intersection point of the two orthogonal second cutting wire saws when the second folding cutting is performed on the silicon rod to be cut in the second cutting unit 25 is located in the cross section of the silicon rod to be cut (including the case that the intersection point is located on the circumference of the cross section), so that the formed cut silicon rod obtains a cross section as large as possible (the surface area of the silicon wafer obtained after subsequent slicing is large), material loss in subsequent grinding (such as surface grinding and rounding/chamfering) operations is reduced, and the utilization rate of the silicon material is improved.

With the above-described cutting apparatus 2, after the first cutting operation (first fold cutting of the silicon rod 100 by the first cutting unit 23) and the second cutting operation (second fold cutting of the silicon rod 100 to be cut by the second cutting unit 25) are performed on the silicon rod 100 to be cut, a silicon rod having a cross-section in a substantially rectangular shape is formed.

In the silicon rod cutting and grinding all-in-one machine, the cutting device further comprises a distance adjusting unit. In the embodiment shown in fig. 1 and 2, the cutting device comprises a first and a second pitch unit 24, 26 in addition to a cutting frame 21, a cutting support 22, a first cutting unit 23, and a second cutting unit 25. The first distance adjusting unit 24 is arranged on a first support flank of the cutting support 22 and is used for adjusting the position of the first cutting unit; the second pitch unit 26 is provided on a second support flank of the cutting support 22 for adjusting the position of the second cutting unit.

When the silicon rods to be cut are placed on the silicon rod positioning mechanism, the positions of the silicon rods to be cut are fixed, the positions of the corresponding cutting units are adjusted through the distance adjusting units, the cutting position of at least one cutting wire saw in the cutting units can be adjusted, the cutting amount of the silicon rods can be controlled, and therefore the silicon rods to be cut in different sizes can be cut and/or the cut silicon rods in different sizes can be cut according to the production process requirements.

Taking the first cutting unit as an example, the cutting position of at least one first cutting wire saw in the first cutting unit can be adjusted by adjusting the position of the first cutting unit through the first distance adjusting unit. Taking the second cutting unit as an example, the cutting position of at least one second cutting wire saw in the second cutting unit can be adjusted by adjusting the position of the second cutting unit through the second distance adjusting unit.

Thus, in some embodiments, the first pitch unit comprises a first carriage adjustment mechanism for adjusting the position of the first carriage and the plurality of first cutting wheels and first transition wheels thereon, and the second pitch unit comprises a second carriage adjustment mechanism for adjusting the position of the second carriage and the plurality of second cutting wheels and second transition wheels thereon.

In some embodiments, the first distance adjustment unit includes a first bobbin adjustment mechanism (in the following description, the first bobbin adjustment mechanism is denoted as 24), and the first bobbin adjustment mechanism 24 is used for adjusting the position of the first bobbin 231 and the plurality of first cutting wheels 233 and the first transition wheels 234 thereon. The adjusting of the position of the first wire frame 231 and the plurality of first cutting wheels 233 and the first transition wheels 234 thereon may be, for example, driving the first wire frame 231 and the plurality of first cutting wheels 233 and the first transition wheels 234 thereon to move along the X-axis, so that the two orthogonal first cutting lines in the first cutting unit change positions by moving along the X-axis. For example, driving the first wire frame 231 and the plurality of first cutting wheels 233 and the first transition wheels 234 thereon to move toward the silicon rod conversion device 4 along the X axis using the first wire frame adjusting mechanism 24 may move two orthogonal first cutting lines in the first cutting unit 23 toward the silicon rod to be cut on the silicon rod conversion device 4, may increase the cutting amount of the silicon rod to be cut, or may cut a silicon rod to be cut having a smaller size. The first wire frame 231, the plurality of first cutting wheels 233 and the first transition wheel 234 thereon are driven by the first wire frame adjusting mechanism 24 to move away from the silicon rod conversion device 4 along the X axis, so that two orthogonal first cutting lines in the first cutting unit 23 move away from the silicon rod to be cut on the silicon rod conversion device 4, the cutting amount of the silicon rod to be cut can be reduced, or the silicon rod to be cut with a larger size can be cut.

Similarly, the second distance adjusting unit includes a second bobbin adjusting mechanism (in the following description, the second bobbin adjusting mechanism is denoted by 26), and the second bobbin adjusting mechanism 26 is used for adjusting the positions of the second bobbin 251 and the plurality of second cutting wheels 253 and second transition wheels 254 thereon. The adjusting of the positions of the second bobbin 251 and the plurality of second cutting wheels 253 and the second transition wheels 254 thereon may be, for example, driving the second bobbin 251 and the plurality of second cutting wheels 253 and the second transition wheels 254 thereon to move along a Y-axis (the Y-axis is orthogonal to the X-axis) so that two orthogonal second cutting lines in the second cutting unit change positions by moving along the X-axis. For example, driving the second bobbin 251 and the plurality of second cutting wheels 253 and second transition wheels 254 thereon to move toward the silicon rod conversion device 4 along the Y axis using the second bobbin adjusting mechanism 26 may cause two orthogonal second cutting lines in the second cutting unit 25 to move toward the silicon rod to be cut on the silicon rod conversion device 4, may increase the cutting amount of the silicon rod to be cut, or may cut a silicon rod to be cut having a smaller size. The second wire rack adjusting mechanism 26 is used for driving the second wire rack 251 and the plurality of second cutting wheels 253 and the second transition wheels 254 thereon to move away from the silicon rod conversion device 4 along the Y axis, so that two orthogonal second cutting lines in the second cutting unit 25 can move away from the silicon rod to be cut on the silicon rod conversion device 4, the cutting amount of the silicon rod to be cut can be reduced, or the silicon rod to be cut with larger size can be cut.

In some embodiments, the first bobbin adjusting mechanism may include a first lead screw and a first motor, wherein the first lead screw is associated with the first bobbin, and the first bobbin is driven to move back and forth along the X-axis by the first motor driving the first lead screw to rotate back and forth. For example, the first motor drives the first screw rod to rotate forwards, and drives the first bobbin to move towards the silicon rod conversion device along the X axis; the first motor drives the first lead screw to rotate reversely, and drives the first wire frame to move away from the silicon rod conversion device along the X axis.

Similarly, the second bobbin adjusting mechanism may include a second lead screw and a second motor, wherein the second lead screw is associated with the second bobbin, and the second bobbin is driven to move back and forth along the Y-axis by the second motor driving the second lead screw to rotate forward and backward. For example, the second motor drives the second screw rod to rotate forwards, and drives the second bobbin to move towards the silicon rod conversion device along the Y axis; the second motor drives the second screw rod to rotate reversely, and drives the second wire rack to move along the Y axis away from the silicon rod conversion device.

For example, the first bobbin adjusting mechanism may include a first lead screw, a first synchronous belt, and a first motor, wherein the first lead screw is associated with the first bobbin, the first lead screw is associated with an output shaft of the first motor through the first synchronous belt, and the first bobbin is driven to move back and forth along the X axis by the first motor driving the first lead screw to rotate forward and backward. For example, the first motor drives the first lead screw to rotate forwards, and drives the first bobbin to move towards the silicon rod conversion device along the X axis; the first motor drives the first lead screw to rotate reversely, and drives the first line frame to move away from the silicon rod conversion device along the X axis. Similarly, the second carriage adjusting mechanism may include a second lead screw, a second synchronous belt, and a second motor, wherein the second lead screw is associated with the second carriage, the second lead screw is associated with an output shaft of the second motor through the second synchronous belt, and the second carriage is driven to move back and forth along the Y axis by the second motor driving the second lead screw to rotate forward and backward. For example, the second motor drives the second screw rod to rotate forwards, and drives the second bobbin to move towards the silicon rod conversion device along the Y axis; and the second motor drives the second screw rod to rotate reversely, and drives the second wire frame to move away from the silicon rod conversion device along the Y axis. In the foregoing description, the lead screw and the motor in the bobbin adjusting mechanism are associated through the synchronous belt, so that the layout space of the mechanism on a straight line (for example, an X axis or a Y axis) can be saved and the structure is more compact compared with a mode that the lead screw is directly connected with the motor.

In addition, first line frame guiding mechanism still can be including locating the first guide rail on first line frame, does benefit to first line frame is along the smoothness nature of X axle removal, similarly, second line frame guiding mechanism still can be including locating the second guide rail on the second line frame, does benefit to the smoothness nature of second line frame along the Y axle removal.

Still other variations of the first and second carriage adjustment mechanisms are possible, for example, the first or second carriage adjustment mechanism may include: the device comprises a sliding rack, a rotating gear meshed with the sliding rack and a sliding driving motor associated with the rotating gear.

In some examples, the at least one cutting unit further comprises at least one transition wheel, each transition wheel having at least two wire grooves; when the plurality of cutting wheels in the at least one cutting unit are driven by the at least one distance adjusting mechanism to move along the cutting wheel axle, at least one transition wheel in the at least one cutting unit and the plurality of cutting wheels are kept static relatively.

The first distance adjusting unit comprises a first bobbin adjusting mechanism, and the first bobbin adjusting mechanism is used for adjusting the positions of the first bobbin and a plurality of first cutting wheels and first transition wheels on the first bobbin; the second cutting unit includes: the second wire frame, a plurality of second cutting wheels and second transition wheels which are arranged on the second wire frame, and a second cutting wire, wherein the second cutting wire is wound around the plurality of second cutting wheels and the second transition wheels to form two orthogonal second cutting wire saws; the second distance adjusting unit comprises a second wire frame adjusting mechanism, and the second wire frame adjusting mechanism is used for adjusting the positions of the second wire frame and a plurality of second cutting wheels and second transition wheels on the second wire frame.

In the first cutting unit or the second cutting unit, each first cutting wheel 233 has at least two cutting wire grooves, different cutting wire grooves are parallel to each other, and a cutting wire groove interval is provided between two adjacent cutting wire grooves. The distance between two different adjacent cutting wire slots is not limited, and may be the same (i.e., equal distance) or different.

Taking the first cutting unit as an example, when the first cutting line 213 is changed to a cutting line groove wound around the first cutting wheel 233, the position of the first cutting wheel on the first line stand can be adjusted by the first line stand adjusting mechanism.

For example, assuming that the first cutting wire 235 is wound around the outermost cutting wire groove of the first cutting wheel 233 at the initial time, when the first cutting wire 235 is to be wound around the cutting wire groove of the first cutting wheel 233, for example, the winding position of the first cutting wire 235 is to be changed from the outermost cutting wire groove to another cutting wire groove, the moving distance of the first cutting wheel 233 along the X-axis is determined according to the distance between the outermost cutting wire groove and the cutting wire groove of the target position, such that the first cutting wheel and the first transition wheel on the first frame are driven by the first frame adjusting mechanism to move towards the silicon rod transfer device along the X-axis by the distance corresponding to the determined moving distance, and then the first cutting wire 235 is wound around the cutting wire groove of the target position, and after the winding is completed, the cutting space formed by the two orthogonal first cutting wires in the first cutting unit 23 is not changed, that is, the cutting amount is not changed, and thus, the groove change of the first cutting line is realized. Of course, when the first frame, the first cutting wheel and the first transition wheel thereon are driven by the first frame adjusting mechanism to move towards the silicon rod conversion device along the X axis and the determined moving distance does not correspond, the first cutting wire 235 is wound around the cutting wire slot at the target position, and after the winding is completed, the cutting space formed by the two orthogonal first cutting wire saws in the first cutting unit 23 is changed, that is, the cutting amount is changed, so that both the cutting wire slot switching and the cutting amount adjustment are realized. In the above description, the reason for the first cutting wire to be replaced includes, but is not limited to, the wear of the original cutting wire groove due to long-term use to the extent that replacement is required. In addition, the distance of movement of the first cutting wheel 233 along the X-axis, which is determined based on the distance between the cutting line groove at the starting position and the cutting line groove at the target position, is determined in relation to the relationship between the respective cutting line grooves in the first cutting wheel and the X-axis. For example, the plane of the cutting line grooves in the first cutting wheel is at an angle of 45 ° to the X-axis, so the relationship between the distance between the cutting line groove at the starting position and the cutting line groove at the target position in the first cutting wheel and the moving distance along the X-axis satisfies the pythagorean theorem, i.e., the ratio of the distance between two cutting line grooves to the moving distance along the X-axis is √ 2: 1.

In addition, in the first cutting unit, since the first transition wheel and the first cutting wheel are relatively stationary, when the position of the first cutting wheel on the first wire frame is adjusted by the first wire frame adjusting mechanism, the first transition wheel may be designed differently so that the first cutting wire saw after the first cutting wire is wound around the wire cutting groove of the first cutting wheel 233 whose position is changed and the part of the first cutting wire wound around the first transition wheel are still in the same plane (the plane may be, for example, a vertical plane).

In some embodiments, the first transition wheel has at least two guide line slots, different guide line slots are parallel to each other, and a guide line slot interval is provided between two adjacent guide line slots.

In some embodiments, the number of the guide wire grooves in the first transition wheel is the same as the number of the cutting wire grooves in the first cutting wheel, and the distance between each guide wire groove in the first transition wheel is consistent with the distance between each corresponding cutting wire groove in the first cutting wheel.

In this implementation, when the position of the first cutting wheel on the first wire frame is adjusted by the first wire frame adjusting mechanism, the first transition wheel on the first wire frame is also adjusted synchronously with the first cutting wheel, when the first cutting wire is changed to be wound around the cutting wire slot on the first cutting wheel, the first cutting wire is also changed to be wound around the guide wire slot on the first transition wheel, and it can still be ensured that the first cutting wire saw after the first cutting wire is wound around the cutting wire slot on the first cutting wheel and the part of the first cutting wire after the first cutting wire is wound around the transition wire slot on the first transition wheel are still in the same vertical plane.

In some embodiments, although the first transition wheel has at least two guiding slots therein, the first transition wheel cannot be ensured to be relatively stationary with respect to the first cutting wheel when adjusted by the first wire frame adjusting mechanism alone due to one or more of, for example, the number of guiding slots in the first transition wheel is not the same as the number of cutting slots in the first cutting wheel, or the guiding slot pitch between each guiding slot in the first transition wheel is not the same as the cutting slot pitch between each cutting slot in the first cutting wheel, or the first cutting wheel and the first transition wheel are configured and mounted such that the guiding slots in the first transition wheel are not completely aligned with the cutting slots in the first cutting wheel.

In some embodiments, the first transition wheel only has one guiding line groove, and the relative rest of the first transition wheel and the first cutting wheel cannot be ensured when the first transition wheel is adjusted by the first line frame adjusting mechanism. In addition, the wire chase may have an alternate wire chase bushing that can be replaced with a new one after wear from long-term use.

As can be seen from the above, in some situations, when the adjustment is performed by the first wire frame adjusting mechanism, the first transition wheel and the first cutting wheel cannot be kept stationary. In view of the above, in some embodiments, the first distance adjusting unit further includes a first calibrating mechanism in addition to the first bobbin adjusting mechanism, and the first calibrating mechanism is configured to drive the first transition wheel to move relative to the first cutting wheel, so that a current wire groove wound by the first cutting wire in the first transition wheel is adjusted from a first cutting wire groove corresponding to the first cutting wheel to a second cutting wire groove corresponding to the first cutting wheel.

In some embodiments, the first alignment mechanism comprises two racks engaged with each other, the two racks are respectively disposed on the first cutting wheel and the first transition wheel, and the first transition wheel and the first cutting wheel can be driven to move relative to each other by the mutual movement of the two racks. For example, as shown in fig. 9, the first alignment mechanism 27 includes a first rack and a second rack engaged with each other, wherein the first rack is associated with the first cutting wheel, the second rack is associated with the first transition wheel, the first rack is associated with the first cutting wheel, for example, the first rack is disposed on the first wire frame, and the second rack is associated with the first transition wheel, for example, the second rack is disposed on the bracket for mounting the first transition wheel.

Of course, in the case where there are a plurality of transition wheels, the first calibration mechanism in the first pitch adjustment unit may not be limited to one. For example, the first cutting unit 23 further includes a plurality of transition wheels disposed on the cutting frame 21, and the first distance adjusting unit further includes a plurality of first alignment mechanisms disposed adjacent to the plurality of transition wheels.

As can be seen from the above, the first frame adjusting mechanism in the first distance adjusting unit drives the first frame and the plurality of first cutting wheels and the first transition wheel thereon to move towards or away from the silicon rod conversion device along the X axis, so that the two orthogonal first cutting lines in the first cutting unit can move towards or away from the silicon rod to be cut on the silicon rod conversion device, and the cutting amount of the silicon rod to be cut or the silicon rods to be cut suitable for different sizes can be adjusted; additionally, the first alignment mechanism in the first distance adjusting unit is used for driving the first transition wheel and the first cutting wheel to move relatively, so that the current wire groove wound by the first cutting wire in the first transition wheel is adjusted from the first cutting wire groove corresponding to the first cutting wheel to the second cutting wire groove corresponding to the first cutting wheel, and the relative rest of the first transition wheel and the first cutting wheel is ensured.

With respect to the second pitch unit associated with the second cutting unit, in certain embodiments, the second pitch unit may include a second carriage adjustment mechanism, and in certain embodiments, as shown in fig. 9, the second pitch unit may include a second carriage adjustment mechanism 26 and a second calibration mechanism 28. For the application of the second bobbin adjusting mechanism, or the second bobbin adjusting mechanism and the second calibrating mechanism and the working principle 4 thereof, reference may be made to the description of the first bobbin adjusting mechanism, or the first bobbin adjusting mechanism and the first calibrating mechanism, which is not described herein again.

Referring to fig. 10 to 13, schematic views of another embodiment of the silicon rod slicing and grinding all-in-one machine of the present application are shown, wherein fig. 10 is a perspective view of another embodiment of the silicon rod slicing and grinding all-in-one machine of the present application, fig. 11 is a top view of another embodiment of the silicon rod slicing and grinding all-in-one machine of the present application, fig. 12 is a schematic view of another embodiment of a cutting device in the silicon rod slicing and grinding all-in-one machine of the present application, and fig. 13 is a top view of another embodiment of the cutting device in the silicon rod slicing and grinding all-in-one machine of the present application. In fig. 10 to 13, the cutting device in the silicon rod cutting and grinding machine is mainly referred to, so that the cutting device in the silicon rod cutting and grinding machine is simplified, but the protection scope of the present application is not limited.

Referring to fig. 10 to 13, in the silicon rod slicing and grinding all-in-one machine, the silicon rod slicing and grinding all-in-one machine includes: a machine base 1, a cutting device 6, a silicon rod grinding device, a silicon rod conversion device 4 and a silicon rod loading and unloading device 5.

Wherein, regarding the cutting device 6 in the present embodiment, the cutting device 6 includes: the cutting device 2 includes: a cutting frame 61, a cutting support 62, a first cutting unit 63, and a second cutting unit 65.

The cutting frame 61 is arranged on the machine base 1. In the present embodiment, the cutting frame 61 is a column structure or a frame structure, and serves as a support body of the cutting device 6, and can provide support for other components in the cutting device 6.

The cutting support 62 is arranged on the cutting frame 61 in a lifting manner by a lifting mechanism. In some embodiments, the lifting mechanism may include a mechanism that can realize the vertical movement of the cutting support 62, such as a lifting motor and a lifting rail, wherein the lifting rail is vertically disposed on the cutting frame 61, and in order to realize the stable lifting of the cutting support 62 on the mounting structure of the machine base 1, a dual-rail design may be adopted, that is, two lifting rails are adopted, and the two lifting rails are disposed in parallel. The cutting support 62 is driven by the lifting motor (which may be a servo motor, for example) to move up and down relative to the cutting frame 61 and the machine base 1 via a lifting guide rail. In some embodiments, the lifting mechanism may further include a lifting slider that may be disposed on the back of the cutting support 62 and cooperate with the lifting rail.

In the present embodiment, since the cutting support 62 can be provided with the first cutting unit 63 and the second cutting unit 65, that is, the first cutting unit 63 and the second cutting unit 65 share the cutting support 62. Thus, in the present embodiment, on the one hand, the cutting carriage 61 and the cutting support 62 in the cutting device 6 are provided in a central position between the first cutting location and the second cutting location. On the other hand, the cutting support 62 is specially designed. The cutting support 62 in this embodiment may include a support body and first and second support wings located on opposite lateral sides of the support body.

Referring to fig. 12, a top view of a cutting device of a silicon rod slicing and grinding all-in-one machine according to an embodiment of the present disclosure is shown.

Referring to fig. 10 to 13, the first cutting unit 63 is disposed at a first lateral side of the cutting support 62, and is configured to perform a first folding cutting on the silicon rod at a first cutting location of the silicon rod processing platform.

In the present embodiment, as described above, the cutting support 62 includes the support main body and the first and second support flanks located on opposite lateral sides of the support main body, and thus the first cutting unit 63 is mounted at the first support flank of the cutting support 62. Specifically, the first cutting unit 63 includes a first bobbin 631 disposed on a side of the first holder, a plurality of first cutting wheels 633 disposed on the first bobbin 631, and a first cutting wire 635, and the first cutting wire 635 is sequentially wound around the plurality of first cutting wheels 633 to form two orthogonal first cutting wires.

In practical applications, the first cutting unit 63 may at least include four first cutting wheels 633, and the four first cutting wheels 633 may be combined into two orthogonal first cutting wheel sets, that is, two first cutting wheels are oppositely disposed along the M axis to form one first cutting wheel set, and two first cutting wheel sets along the N axis to form one pair of first cutting wheel sets, wherein the M axis is orthogonal to the N axis. In particular, the first cutting unit 63 comprises two orthogonal sets of first cutting wheels, one comprising two first cutting wheels 633 arranged along the M axis and the other comprising two first cutting wheels 633 arranged along the N axis.

The first cutting lines 635 are sequentially wound around the first cutting wheels 633 of the first cutting unit 63 to form a first wire mesh. In practical applications, the first cutting wire 635 is sequentially wound around the four first cutting wheels 633 of the first cutting unit 63 to form two mutually orthogonal first cutting wire saws, thereby forming a first cutting wire web. Specifically, the first cutting wire 635 forms one first cutting wire saw by winding around the two first cutting wheels 633 arranged along the M axis in one first cutting wheel set, and the first cutting wire 635 forms another second cutting wire saw by winding around the two first cutting wheels 633 arranged along the N axis in the other first cutting wheel set. Thus, the two mutually orthogonal first cutting wire saws are matched to form a first cutting wire net in a shape of a plus or a T.

Of course, the first cutting unit 63 is not limited to the embodiment shown in fig. 10 to 13, and other variations can be made in other embodiments.

In this embodiment, the first cutting unit 63 may further include a transition wheel 634 for implementing transition guidance of the first cutting line 635. The transition wheels 634 may be not limited to one, and may be disposed on the first bobbin 631 and/or the first support wing, for example, in some embodiments, some of the transition wheels 634 may be disposed on the first bobbin 631, in some embodiments, some of the transition wheels 634 may be disposed on the first support wing, in some embodiments, some of the transition wheels 634 may be disposed on the first bobbin 631, and some of the transition wheels 634 may be disposed on the first support wing.

In addition, in some embodiments, the first cutting unit 63 may further include a tension pulley provided on the first bobbin 631 and/or the first holder side wing for performing tension adjustment of the first cutting line 635.

The second cutting unit 65 is disposed at a second side of the cutting support 62, and is configured to perform a second plane-folding cutting on the silicon rod 100 at a second processing location of the silicon rod processing platform.

In the present embodiment, as described above, the cutting support 62 includes the support main body and the first and second support flanks located at opposite lateral sides of the support main body, and thus the second cutting unit 65 is mounted at the second support flank of the cutting support 62. Specifically, the second cutting unit 65 includes a second reel 651 disposed on the second holder flank, a plurality of second cutting wheels 653 disposed on the second reel 651, and a second cutting wire 655, and the second cutting wire 655 is sequentially wound around the plurality of second cutting wheels 653 to form two orthogonal second cutting wires.

In practical applications, the second cutting unit 65 can include at least four second cutting wheels 653, and the four second cutting wheels 653 can be combined into two orthogonal second cutting wheel sets, that is, one second cutting wheel set is formed by two second cutting wheels arranged along the M axis, and one second cutting wheel set is formed by two second cutting wheel sets along the N axis, wherein the M axis is orthogonal to the N axis. In particular, the second cutting unit 65 comprises two orthogonal sets of second cutting wheels, one comprising two second cutting wheels 653 arranged along the M axis and the other comprising two second cutting wheels 653 arranged along the N axis.

The second cutting lines 655 sequentially wind around the respective second cutting wheels 653 disposed in the second cutting unit 65 to form a second wire net. In practical applications, the second cutting line 655 sequentially winds around the four second cutting wheels 653 disposed in the second cutting unit 65 to form two second cutting saws perpendicular to each other, thereby forming a second cutting wire web. Specifically, the second cutting line 655 forms one second cutting wire saw around the two second cutting wheels 653 arranged along the M axis in one second cutting wheel group, and the second cutting line 655 forms another second cutting wire saw around the two second cutting wheels 653 arranged along the N axis in the other second cutting wheel group. Thus, the two mutually orthogonal second cutting wire saws are matched to form a second cutting wire net in a shape of a plus or a reversed L.

Of course, the second cutting unit 65 is not limited to the embodiment shown in fig. 10 to 13, and other variations can be made in other embodiments.

In this embodiment, the second cutting unit 65 may further include a transition wheel 654 for implementing transition guidance of the second cutting line 655. The transition wheels 654 may be not limited to one, and may be disposed on the first carriage 631 and/or the first support wing, for example, in some embodiments, some of the transition wheels 654 may be disposed on the second carriage 651, in some embodiments, some of the transition wheels 654 may be disposed on the second support wing, in some embodiments, some of the transition wheels 654 may be disposed on the second carriage 651, and some of the transition wheels 654 may be disposed on the second support wing.

In addition, in some embodiments, the second cutting unit 65 may further include a tension wheel provided on the second string frame 651 and/or the second holder wing for performing tension adjustment of the second cutting line 655.

In certain embodiments, the first cut line and the second cut line are the same cut line. The cutting device further comprises a take-up and pay-off unit. For example, the take-up and pay-off unit may include a pay-off reel and a take-up reel, which may be disposed on the base or the cutting frame.

In the embodiment as shown in fig. 10 to 13, the first cutting line 635 in the first cutting unit 63 and the second cutting line 655 in the second cutting unit 65 may be the same cutting line. In this case, the common cutting line sequentially forms two orthogonal first cutting wires saw around the plurality of first cutting wheels 633 (and transition wheels) provided in the first cutting unit 63 and then transfers to the second cutting unit at the side to sequentially form two orthogonal second cutting wires saw around the plurality of second cutting wheels 653 (and transition wheels) provided in the second cutting unit 65. In this embodiment, therefore, the cutting support 62 is also provided with one or more transition wheels between the first cutting unit 63 and the second cutting unit 65 around which the common cutting line is wound. Specifically, in the embodiment shown in fig. 4, an intermediate transition wheel 67 around which the common cutting line is wound is provided on the holder body 221 between the first cutting unit 63 and the second cutting unit 65 in the cutting holder 62.

In addition, in the embodiment shown in fig. 10 to 13, the cutting device further includes a take-up and pay-off unit. For example, the wire winding and unwinding unit may include a wire winding drum and a wire winding drum, which may be disposed on the base 1 and located at opposite sides of the cutting frame 61, for winding and unwinding the common cutting wire.

The first cutting unit 63 and the second cutting unit 65 share the same cutting line, so that the structure of the cutting unit can be simplified (for example, a set of paying-off cylinder and a set of winding cylinder are omitted), the integrity is good, the winding process is simplified, the efficiency is improved, and the line tension and the like of the two cutting units can be better controlled.

In some embodiments, the first cutting unit and the second cutting unit in the cutting device are independent components, and then the cutting device further includes a first take-up and pay-off unit matched with the first cutting unit and a second take-up and pay-off unit matched with the second cutting unit, wherein the first take-up and pay-off unit includes a first pay-off drum and a first take-up drum which are arranged on the base or the cutting frame and are used for taking up and paying off the first cutting line, and the second take-up and pay-off unit includes a second pay-off drum and a second take-up drum which are arranged on the base or the cutting frame and are used for taking up and paying off the second cutting line.

Of course, other variations of the cutting line are possible than with a take-up and pay-off unit.

In some embodiments, the first cutting unit and the second cutting unit in the cutting device are independent parts, wherein for the first cutting unit, the first cutting line is wound around a plurality of first cutting wheels and first transition wheels to form a first closed loop cutting line in an end-to-end connection, and for the second cutting unit, the second cutting line is wound around a plurality of second cutting wheels and second transition wheels to form a second closed loop cutting line in an end-to-end connection. The first closed-loop cutting line and the second closed-loop cutting line can avoid the acceleration and deceleration processes of the cutting lines from influencing the cutting precision in the process of being operated to execute cutting, so that the cutting precision is improved, and the follow-up procedures are facilitated to be simplified.

In some embodiments, the first cutting line in the first cutting unit and the second cutting line in the second cutting unit may be the same cutting line. In this case, the common cutting line is wound around the plurality of first cutting wheels, first transition wheels, intermediate transition wheels, plurality of second cutting wheels and second transition wheels to form an endless closed loop cutting line. The closed-loop cutting line can avoid the influence of the acceleration and deceleration processes of the cutting line on the cutting precision in the process of running to execute cutting, so that the cutting precision is improved, and the subsequent procedures are facilitated to be simplified.

When the silicon rods on the first cutting location and the silicon rods on the second cutting location of the silicon rod processing platform are cut by means of the cutting device 6 in the embodiment shown in figures 10 to 13, the cutting support 62 is driven to descend relative to the cutting frame 61, the first cutting unit 63 and the second cutting unit 65 on the left and right sides of the cutting support 62 simultaneously cut the silicon rod on the corresponding first cutting area and the silicon rod on the corresponding second cutting area, the first cutting unit 63 performs first fracture surface cutting on the silicon rod at the first cutting area (the first cutting unit 63 is provided with two orthogonal first cutting wire saws in a shape like a plus or a reversed L), and the second cutting unit 65 performs second fracture surface cutting on the silicon rod at the second cutting area (the second cutting unit 65 is provided with two orthogonal second cutting wire saws in a shape like a plus or a reversed L). As can be seen from this, in the present embodiment, the first cutting unit 63 and the second cutting unit 65 of the cutting device 6 share the cutting support 62, and by driving the shared cutting support 62 to perform the lifting motion, the first cutting unit 63 and the second cutting unit 65 thereon can perform the first folding cutting on the silicon rod at the first cutting location and the second folding cutting on the silicon rod at the second cutting location, respectively, at the same time. The cutting device 6 is simple in structure on the whole, convenient to control and capable of improving the cutting efficiency and quality of the silicon rod.

It should be noted that, in some embodiments, the intersection point of the two orthogonal first cutting wires when the first folding cutting is performed on the silicon rod to be cut in the first cutting unit 63 is located in the cross section of the silicon rod to be cut (including the case that the intersection point is located on the circumference of the cross section), and the intersection point of the two orthogonal second cutting wires when the second folding cutting is performed on the silicon rod to be cut in the second cutting unit 65 is located in the cross section of the silicon rod to be cut (including the case that the intersection point is located on the circumference of the cross section), so that the formed cut silicon rod obtains a cross section as large as possible (the surface area of the silicon wafer obtained after subsequent slicing is large), material loss in subsequent grinding (such as surface grinding and rounding/chamfering) operations is reduced, and the utilization rate of the silicon material is improved.

With the above-described slicing apparatus 6, after the first slicing operation (first fold slicing of the silicon rod 100 by the first slicing unit 63) and the second slicing operation (second fold slicing of the silicon rod 100 to be sliced by the second slicing unit 65) are performed on the silicon rod 100 to be sliced, a silicon rod having a rectangular-like cross section is formed.

In the silicon rod cutting and grinding all-in-one machine of the application, the cutting device further comprises a distance adjusting unit for adjusting the cutting position of at least one of the first cutting unit and the second cutting unit.

In some embodiments, the distance adjusting unit further includes a first direction distance adjusting unit for adjusting a position of at least one of the first cutting unit and the second cutting unit in the first direction, and a second direction distance adjusting unit for adjusting a position of at least one of the first cutting unit and the second cutting unit in the second direction.

In the embodiment shown in fig. 10 to 13, the cutting apparatus includes a cutting frame 61, a cutting support 62, a first cutting unit 63, and a second cutting unit 65, and further includes a distance adjusting unit, the distance adjusting unit further includes a first direction distance adjusting unit 64 and a second direction distance adjusting unit 66, the first direction distance adjusting unit 64 is used for adjusting the positions of the first cutting unit 63 and the second cutting unit 65 in a first direction (i.e., M-axis direction shown in fig. 11 or 13), and the second direction distance adjusting unit 66 is used for adjusting the positions of the first cutting unit 63 and the second cutting unit 65 in a second direction (i.e., N-axis direction shown in fig. 11 or 13).

The first direction pitch unit 64 may include a cutting holder advancing and retreating mechanism (in the following description, the cutting holder advancing and retreating mechanism is denoted by 64) for driving the cutting holder 62 and the first and second cutting units 63 and 65 thereon to move in an advancing and retreating direction (i.e., a first direction, i.e., an M-axis direction as shown in fig. 11 or 13).

In some embodiments, the cutting support advancing and retreating mechanism 64 may include an advancing and retreating guide provided on the cutting frame 61 or a mounting structure associated with the cutting frame 61 in the advancing and retreating direction, and an advancing and retreating drive source that may include an advancing and retreating lead screw provided in the advancing and retreating direction (i.e., the first direction, i.e., the M-axis direction shown in fig. 11 or 13) and associated with the cutting support 62, and a drive motor associated with the advancing and retreating lead screw for driving the advancing and retreating lead screw to rotate forward and backward to drive the cutting support 62 to move forward and backward in the advancing and retreating direction (i.e., the M-axis direction shown in fig. 11 or 13) by using the drive motor. For example, the driving motor drives the advancing and retreating screw rod to rotate forward, and drives the cutting support 62 to move towards the center of the silicon rod conversion device 4 along the M axis, that is, the first cutting unit 63 and the second cutting unit 65 on the cutting support 62 are driven to move towards the corresponding first cutting area and second cutting area respectively; the driving motor drives the advance and retreat screw rod to rotate reversely, and drives the cutting support 62 to move away from the silicon rod conversion device 4 along the M axis, namely, the first cutting unit 63 and the second cutting unit 65 on the cutting support 62 are driven to move away from the corresponding first cutting area and second cutting area respectively. In some embodiments, the cutting block advance and retreat mechanism 64 may also include an advance and retreat slider disposed on the cutting block 62 and correspondingly engaged with the advance and retreat rail.

The cutting holder advancing and retreating mechanism 64 includes an advancing and retreating screw and a driving motor, but is not limited thereto, and the cutting holder advancing and retreating mechanism 64 may be modified as long as it can drive the cutting holder 62 to move forward and backward in a predetermined advancing and retreating direction, and for example, in some embodiments, the cutting holder advancing and retreating mechanism 64 may also employ a combination of an advancing and retreating rack provided in the advancing and retreating direction, a driving gear engaged with the advancing and retreating rack, and a driving motor for driving the driving gear to rotate. For example, in one example, the advancing and retracting rack is disposed on the cutting frame or a mounting structure associated with the cutting frame in an advancing and retracting direction, and the drive gear and the drive motor are disposed on the cutting support, or, in another example, the advancing and retracting rack is disposed on the cutting support in an advancing and retracting direction, and the drive gear and the drive motor are disposed on the cutting frame or a mounting structure associated with the cutting frame. The driving motor is used for driving the driving gear to rotate forwards and backwards to drive the cutting support to move forwards and backwards along the advancing and retreating direction. For example, the driving motor drives the driving gear to rotate forward, the driving gear rotating forward is matched with the advancing and retreating rack, and the cutting support is driven to move towards the center of the silicon rod conversion device along the advancing and retreating direction, namely, the first cutting unit and the second cutting unit on the cutting support are driven to move towards the corresponding first cutting area and second cutting area respectively; the driving motor drives the driving gear to rotate reversely, the reversely rotating driving gear is matched with the advancing and retreating rack, the cutting support is driven to deviate from the silicon rod conversion device to move along the advancing and retreating direction, and namely the first cutting unit and the second cutting unit on the cutting support are driven to deviate from the corresponding first cutting area and second cutting area respectively to move.

Of course, the cutting support advancing and retreating mechanism can still have other changes, and the description is omitted.

The second direction pitch unit 66 may include a cutting unit translation mechanism (in the following description, the cutting unit translation mechanism is denoted as 66) for driving the first cutting unit 63 and the second cutting unit 65 to move in a translation direction (i.e., a second direction, i.e., an N-axis direction as shown in fig. 11 or 13).

In some embodiments, the first cutting unit 63 is provided with a cutting unit translation mechanism 66, the first cutting unit 63 is driven to move in a translation direction by the cutting unit translation mechanism 66, and the second cutting unit 65 is provided with a cutting unit translation mechanism 66, and the second cutting unit 65 is driven to move in a translation direction by the cutting unit translation mechanism 66.

In certain embodiments, the cutting unit translation mechanism 66 may include a translation rail and a translation drive source. In certain embodiments, the cutting unit translation mechanism 66 may include a translation rail, a translation slide corresponding to the translation rail, and a translation drive source.

Taking the first cutting unit 63 as an example, a translation guide rail in the cutting unit translation mechanism 66 is disposed on the cutting support 62 along a translation direction (i.e., the second direction, i.e., the N-axis direction shown in fig. 11 or 13) and the length of the translation guide rail covers the translation range of the first cutting unit 63 along the translation direction, and the translation driving source in the cutting unit translation mechanism 66 may include a translation screw rod and a driving motor, the translation screw rod is associated with the first bobbin 631, and the driving motor is associated with the translation screw rod and drives the translation screw rod to rotate forward and backward to drive the first cutting unit 63 to move left and right along the translation direction (i.e., the N-axis direction shown in fig. 11 or 13). For example, the driving motor drives the translation screw rod to rotate forward, and drives the first cutting unit 63 to move towards the middle area of the cutting support 62 along the N-axis direction; the driving motor drives the translation screw rod to rotate reversely, and drives the first cutting unit 63 to move along the N-axis direction away from the middle area of the cutting support 62. When the cutting unit translation mechanism 66 further includes a translation slider, the translation slider is provided on the first wire frame 631 of the first cutting unit 63.

Taking the second cutting unit 65 as an example, the translation guide rail in the cutting unit translation mechanism 66 is disposed on the cutting support 62 along the translation direction (i.e., the second direction, i.e., the N-axis direction shown in fig. 11 or 13) and the length of the translation guide rail covers the translation range of the second cutting unit 65 along the translation direction, and the translation driving source in the cutting unit translation mechanism 66 may include a translation screw rod and a driving motor, the translation screw rod is associated with the second wire frame 651, and the driving motor is associated with the translation screw rod, and the driving motor drives the translation screw rod to rotate forward and backward to drive the second cutting unit 65 to move left and right along the translation direction (i.e., the N-axis direction shown in fig. 11 or 13). For example, the driving motor drives the translation screw rod to rotate forward, and drives the second cutting unit 65 to move towards the middle area of the cutting support 62 along the N-axis direction; the driving motor drives the translation screw rod to rotate reversely, and drives the second cutting unit 65 to move away from the middle area of the cutting support 62 along the N-axis direction. When the cutting unit translation mechanism 66 further comprises a translation slider, the translation slider is disposed on the second wire frame 651 of the second cutting unit 65.

In some embodiments, the first cutting unit 63 and the second cutting unit 65 are jointly provided with a cutting unit translation mechanism 66, and the first cutting unit 63 and the second cutting unit 65 are driven to move towards or away from each other along the translation direction by the cutting unit translation mechanism 66.

In certain embodiments, the cutting unit translation mechanism 66 may include a translation rail and a translation drive source. In certain embodiments, the cutting unit translation mechanism 66 may include a translation rail, a translation slide corresponding to the translation rail, and a translation drive source.

Wherein the translation guide rail in the cutting unit translation mechanism 66 is arranged on the cutting support 62 along the translation direction (i.e. the second direction, i.e. the N-axis direction shown in fig. 11 or fig. 13) and the length of the translation guide rail covers the translation range of the first cutting unit 63 and the second cutting unit 65 in the translation direction, and the translation drive source in the cutting unit translation mechanism 66 may comprise a bidirectional translation screw rod and a drive motor. The bidirectional translation screw rod can be called a left-handed screw rod and a right-handed screw rod, one end of the bidirectional translation screw rod is provided with left-handed screw teeth, and the other end of the bidirectional translation screw rod is provided with right-handed screw teeth. In practical application, the bidirectional translation screw rod is arranged in a translation manner, two ends of the bidirectional translation screw rod are respectively associated with the first line frame 631 and the second line frame 651, the driving motor is associated with the bidirectional translation screw rod, and the driving motor is used for driving the bidirectional translation screw rod to rotate forward and backward to drive the first cutting unit 63 and the second cutting unit 65 to move in the translation direction in the opposite direction or in the opposite direction. For example, the driving motor drives the bidirectional translation screw to rotate forward, and drives the first cutting unit 63 and the second cutting unit 65 to move toward each other in a translation direction (i.e., an N-axis direction as shown in fig. 11 or 13) (i.e., the first cutting unit 63 and the second cutting unit 63 move toward a middle region of the cutting support 62); the driving motor drives the bidirectional translation screw rod to rotate reversely, and drives the first cutting unit 63 and the second cutting unit 65 to move back and forth in the translation direction (i.e., the N-axis direction shown in fig. 11 or 13) to move away from each other (i.e., the first cutting unit 63 and the second cutting unit 63 both move away from the middle region of the cutting support 62). When the cutting unit translation mechanism 66 further includes a translation slider, the translation slider is disposed on the first wire frame 631 of the first cutting unit 63 and the second wire frame 651 of the second cutting unit 65.

The cutting unit translation mechanism 66 includes a translation screw rod and a driving motor, but not limited thereto, and the cutting unit translation mechanism 66 may be changed as long as the first cutting unit 63 and the second cutting unit 65 can be driven to move left and right along a predetermined translation direction, for example, in some embodiments, the cutting unit translation mechanism 66 may also adopt a combination of a translation rack, a driving gear and a driving motor, the translation rack is arranged along the forward and backward direction, the driving gear is engaged with the translation rack, and the driving motor is used for driving the driving gear to rotate. For example, taking the first cutting unit as an example, in one example, the translation rack is disposed on the cutting support along the advancing and retreating direction, and the driving gear and the driving motor are disposed on the first bobbin of the first cutting unit, or in another example, the translation rack is disposed on the first bobbin of the first cutting unit along the advancing and retreating direction, and the driving gear and the driving motor are disposed on the cutting support. And the driving motor is used for driving the driving gear to rotate forwards and backwards so as to drive the first cutting unit to move left and right along the translation direction. For example, the driving motor drives the driving gear to rotate forwards, and the driving gear rotating forwards is matched with the translation rack to drive the first cutting unit to move towards the middle area of the cutting support along the translation direction; the driving motor drives the driving gear to rotate reversely, the reversely rotating driving gear is matched with the translation rack, and the first cutting unit is driven to move back to the middle area of the cutting support along the translation direction.

Of course, the cutting unit translation mechanism may still have other variations, which are not described herein.

In this application silicon rod cutting and grinding all-in-one, work as the silicon rod that treats the cutting is put its rigidity on silicon rod positioning mechanism, through the position of the corresponding cutting unit of roll adjustment unit adjustment, can adjust the cutting position of an at least cutting coping saw in the cutting unit can be used to realize the cutting volume control to the silicon rod to can cut and/or cut out the not unidimensional silicon rod that has cut to the silicon rod that treats the cutting of not unidimensional according to the production technology requirement.

With regard to the above-mentioned pitch adjustment unit, the pitch adjustment unit may still be varied in other ways depending on the structural differences of the cutting device. Here, different variations of the pitch adjustment unit in other embodiments are briefly described.

In certain embodiments, in the silicon rod cutting and grinding all-in-one machine, the silicon rod processing platform comprises a cutting location, and therefore the silicon rod cutting and grinding all-in-one machine comprises a cutting device comprising a cutting unit. Correspondingly, the cutting device can comprise a cutting frame, a cutting support and a cutting unit, the cutting frame is arranged in the cutting area of the base, the cutting support movably ascends and descends the cutting frame, and the cutting unit is arranged on the cutting support. The cutting unit may include a wire frame, a cutting wheel, a transition wheel, and a cutting wire wound around the cutting wheel and the transition wheel to form two orthogonal cutting wire saws.

The cutting device further comprises a distance adjusting unit corresponding to the cutting unit, wherein the distance adjusting unit can comprise a first direction distance adjusting unit and a second direction distance adjusting unit, the first direction distance adjusting unit is used for adjusting the position of the cutting unit in the first direction, and the second direction distance adjusting unit is used for adjusting the position of the cutting unit in the second direction. In some implementations, the first direction distance adjusting unit may be, for example, a cutting support advancing and retreating mechanism, and includes an advancing and retreating guide rail and an advancing and retreating driving source, wherein the advancing and retreating guide rail is disposed on the base or the cutting frame along the first direction, and the advancing and retreating driving source is configured to drive the cutting support and the cutting unit thereon to move along the first direction. The advance and retreat driving source may further include an advance and retreat screw rod provided in a first direction and associated with the first cutting frame or the first cutting holder, and a driving motor associated with the advance and retreat screw rod.

In certain embodiments, in the silicon rod cutting and grinding all-in-one machine, the silicon rod processing platform comprises a first cutting location and a second cutting location, and the silicon rod cutting and grinding all-in-one machine comprises a first cutting device and a second cutting device.

First cutting device includes first cutting frame, first cutting support, first cutting unit and first roll adjustment unit, wherein, first cutting frame is located the first cutting position of frame, first cutting support activity go up and down in first cutting frame, first cutting unit is located on the first cutting support, cutting unit can include first line frame, first cutting wheel, first transition wheel and first cutting wire, first cutting wire is around forming the first cutting coping saw of two orthogonals behind first cutting wheel and the first transition wheel. The first distance adjusting unit comprises a first direction distance adjusting unit and a second direction distance adjusting unit, the first direction distance adjusting unit in the first distance adjusting unit is used for adjusting the position of the first cutting unit in the first direction, and the second direction distance adjusting unit in the first distance adjusting unit is used for adjusting the position of the first cutting unit in the second direction.

The second cutting device comprises a second cutting frame, a second cutting support, a second cutting unit and a second distance adjusting unit, wherein the second cutting frame is arranged in a second cutting area of the base, the second cutting support movably ascends and descends to the second cutting frame, the second cutting unit is arranged on the second cutting support, the cutting unit can comprise a second wire frame, a second cutting wheel, a second transition wheel and a second cutting line, and the second cutting line is wound around the second cutting wheel and the second transition wheel to form two orthogonal second cutting wire saws. The second distance adjusting unit comprises a first direction distance adjusting unit and a second direction distance adjusting unit, the first direction distance adjusting unit in the second distance adjusting unit is used for adjusting the position of the second cutting unit in the first direction, and the second direction distance adjusting unit in the second distance adjusting unit is used for adjusting the position of the second cutting unit in the second direction.

The first direction distance adjusting unit in the first distance adjusting unit comprises a first cutting support advancing and retreating mechanism which is used for driving the first cutting support and the first cutting unit on the first cutting support to move along a first direction; and the second direction distance adjusting unit in the first distance adjusting unit comprises a first cutting unit translation mechanism which is used for driving the first cutting unit to move along the second direction. The first cutting holder advancing and retreating mechanism includes: the first advancing and retreating guide rail is arranged on the base or the first cutting frame along a first direction, and the first advancing and retreating driving source is used for driving the first cutting support and the first cutting unit thereon to move along the first direction; the first advancing-retreating drive source includes: the cutting device comprises a first advancing and retreating screw rod and a first driving motor, wherein the first advancing and retreating screw rod is arranged along a first direction and is associated with the first cutting frame or the first cutting support, and the first driving motor is associated with the first advancing and retreating screw rod. The first cutting unit translation mechanism includes: the first translation guide rail is arranged on the first cutting support along the second direction, the length of the first translation guide rail covers the corresponding translation range of the first cutting unit in the second direction, and the first translation driving source is used for driving the first cutting unit to move along the second direction. The first translation drive source includes: the first translation screw rod is arranged along a second direction and is associated with the first cutting unit, and the first driving motor is associated with the first advancing and retreating screw rod.

The first direction distance adjusting unit in the second distance adjusting unit comprises a second cutting support advancing and retreating mechanism which is used for driving the second cutting support and a second cutting unit on the second cutting support to move along the first direction; and a second direction distance adjusting unit in the second distance adjusting unit comprises a second cutting unit translation mechanism which is used for driving the second cutting unit to move along a second direction. The second cutting support advancing and retreating mechanism comprises: the second advancing and retreating guide rail is arranged on the machine base or the second cutting frame along a first direction, and the second advancing and retreating driving source is used for driving the second cutting support and a second cutting unit on the second cutting support to move along the first direction; the second advancing-retreating drive source includes: the second advance and retreat lead screw and second driving motor, the second advance and retreat lead screw set up along first direction and with the second cutting frame or the second cutting support is relevant, second driving motor with the second advances and retreat lead screw is relevant. The second cutting unit translation mechanism includes: the second translation guide rail is arranged on the second cutting support along the second direction, the length of the second translation guide rail covers the translation range of the corresponding second cutting unit in the second direction, and the second translation driving source is used for driving the second cutting unit to move along the second direction. The second translation drive source includes: the second translation screw rod is arranged along a second direction and is associated with the second cutting unit, and the second driving motor is associated with the second advancing and retreating screw rod.

In the silicon rod slicing and grinding all-in-one machine, the "first direction" and the "second direction" referred to in the pitch adjusting unit are not determined for different cutting devices, that is, the "first direction" in the first pitch adjusting unit and the "first direction" in the second pitch adjusting unit do not necessarily refer to the same direction, and similarly, the "second direction" in the first pitch adjusting unit and the "second direction" in the second pitch adjusting unit do not necessarily refer to the same direction. In some examples, the "first direction" in the first pitch unit and the "first direction" in the second pitch unit, and the "second direction" in the first pitch unit and the "second direction" in the second pitch unit refer to the same direction, for example, the "first direction" in the first pitch unit and the "first direction" in the second pitch unit refer to an M-axis direction, and the "second direction" in the first pitch unit and the "second direction" in the second pitch unit refer to an N-axis direction. In some examples, the "first direction" in the first distance adjusting unit and the "first direction" in the second distance adjusting unit are not the same direction, for example, the "first direction" in the first distance adjusting unit refers to an X-axis direction, the "first direction" in the second distance adjusting unit refers to a Y-axis direction, the "second direction" in the first distance adjusting unit refers to a Y-axis direction, and the "second direction" in the second distance adjusting unit refers to an X-axis direction (since the first cutting location and the second cutting location are disposed at 90 ° intervals).

According to the foregoing, the silicon rod may form a boundary skin after being cut by the cutting device, in order to avoid interference with the cutting device and other devices, the generated boundary skin needs to be discharged in time, and for the discharge of the boundary skin, a general boundary skin discharging manner is still manually operated by an operator to separate the boundary skin from the cut silicon rod and to move the boundary skin out of the silicon rod multi-station processing equipment. In view of this, this application silicon rod multistation processing equipment still includes flaw-piece discharge apparatus, flaw-piece discharge apparatus is used for unloading the flaw-piece that produces after cutting device carries out the evolution cutting to the silicon rod. Wherein the cut silicon rod refers to a silicon rod having at least one side surface cut to form a skirt, that is, including: a silicon rod having one side surface cut to form one edge skin, a silicon rod having two side surfaces cut to form two edge skins, a silicon rod having three side surfaces cut to form three edge skins, and a silicon rod having four side surfaces cut to form four edge skins (in this case, the silicon rod having four side surfaces cut may also be referred to as an extracted silicon rod).

In certain embodiments, the silicon rod processing platform comprises a cutting zone and the silicon rod squarer comprises a cutting device comprising a cutting unit for squaring and cutting a silicon rod at the respective cutting zone, wherein the cutting unit may comprise four cutting wire saws or two cutting wire saws. Correspondingly, the silicon rod squaring machine further comprises a flaw-piece discharging device, and the flaw-piece discharging device is used for discharging flaw-pieces generated by the squaring and cutting operation of the silicon rods by the cutting units in the cutting device.

In certain embodiments, the silicon rod processing platform comprises a first cutting zone and a second cutting zone, the silicon rod squarer comprises a cutting device and the cutting device comprises a first cutting unit and a second cutting unit corresponding to the first cutting zone and the second cutting zone, respectively, or the silicon rod squarer comprises a first cutting device and a second cutting device and the first cutting device comprises a first cutting unit corresponding to the first cutting zone and the second cutting device comprises a second cutting unit corresponding to the second cutting zone, the silicon rod at the corresponding cutting zone is subjected to squaring and cutting operations using the cutting units, wherein the cutting units may comprise two cutting wire saws. The silicon rod squaring machine further comprises a first flaw-piece discharging device corresponding to the first cutting unit and a second flaw-piece discharging device corresponding to the second cutting unit, the first flaw-piece discharging device is used for discharging flaw-pieces generated by the squaring and cutting operation of the silicon rod by the first cutting unit, and the second flaw-piece discharging device is used for discharging flaw-pieces generated by the squaring and cutting operation of the silicon rod by the second cutting unit.

In one example, two cutting wires of the first or second cutting unit are parallel to each other, which cooperate to form a cutting wire web in the "═ or" | "-shape, for cutting a silicon rod to be cut at the cutting location to form two parallel side cut faces. Correspondingly, the first flaw-piece discharging device is used for discharging two opposite flaw-pieces generated after the first cutting unit performs the first parallel cutting on the silicon rod, and the second flaw-piece discharging device is used for discharging two opposite flaw-pieces generated after the second cutting unit performs the second parallel cutting on the silicon rod.

In one example, the two cutting wires of the first or second cutting unit are crossing each other, provided that the crossing angle of the two cutting wires is 90 °, i.e. the two cutting wires are orthogonal to each other, the two orthogonal cutting wires cooperating to form a cutting wire web in a "+" or "Γ" shape, the two orthogonal cutting wires being used for cutting a silicon rod to be cut at the cutting zone to form two orthogonal side cutting surfaces. Correspondingly, the first flaw-piece discharging device is used for discharging two adjacent flaw-pieces generated after the first cutting unit performs the first folding cutting on the silicon rod, and the second flaw-piece discharging device is used for discharging two adjacent flaw-pieces generated after the second cutting unit performs the second folding cutting on the silicon rod.

Taking the silicon rod cutting and grinding all-in-one machine shown in fig. 1, 2 and 9 as an example, the silicon rod cutting and grinding all-in-one machine further comprises a first flaw-piece discharging device corresponding to the first cutting unit 23 and a second flaw-piece discharging device corresponding to the second cutting unit 25. Taking the silicon rod cutting and grinding all-in-one machine shown in fig. 10 to 13 as an example, the silicon rod cutting and grinding all-in-one machine further includes a first flaw-piece discharging device corresponding to the first cutting unit 63, and a second flaw-piece discharging device corresponding to the second cutting unit 25.

Since the first and second flaw-piece discharging devices have the same structure, only the first flaw-piece discharging device will be described as an example.

In certain embodiments, the size of the table surface of the rotary carrier table, which is in contact with the silicon rod, is equal to or larger than the cross section of the silicon rod to be cut after the cutting of the silicon rod to be cut (i.e., the cut silicon rod), and therefore, the table surface of the rotary carrier table may be provided with a cutting groove for the cutting wire saw of the cutting unit to enter, and particularly, the table surface is provided with a cutting groove for the cutting wire saw to enter. Taking the cutting unit including two parallel cutting wire saws as an example, two parallel cutting grooves for the cutting wire saws to enter are arranged on the table-board. Taking the cutting unit including two mutually orthogonal cutting wire saws as an example, two mutually orthogonal cutting grooves for the cutting wire saws to enter are arranged on the table-board. Therefore, when the cutting unit descends along with the cutting support, the cutting line saw formed in the cutting unit performs cutting operation on the silicon rod to be cut borne by the rotary bearing platform positioned in the cutting area, when the cutting line saw reaches the bottom of the silicon rod to be cut, the cutting line saw can descend continuously without hindrance until penetrating through the silicon rod to be cut, and the silicon rod to be cut is completely cut.

In certain embodiments, the dimension of the surface of the rotary carrier table that is in contact with the silicon rod is smaller than the cross-section of the silicon rod to be cut after the cutting of the cut silicon rod (i.e., the cut silicon rod). Like this, when cutting unit followed the decline of cutting support, the silicon rod that treats the cutting that the rotatory plummer that forms among the cutting unit bore to be located the cutting district bears carries out the operation of squaring and cutting, when the cutting coping saw reachd the bottom of the silicon rod that treats the cutting, just can unimpeded continue descending until running through the silicon rod that treats the cutting, the realization is treated the complete cutting of the silicon rod that cuts.

As described above, the size of the mesa of the rotary carrying table contacting the silicon rod is smaller than the cross section of the silicon rod to be cut (i.e., the cut silicon rod) formed after the cut silicon rod is cut, so that the cutting wire saw in the wire cutting unit can perform the cutting on the silicon rod to be cut carried by the rotary carrying table in the cutting area without hindrance. However, such a design also entails certain problems, since the underlying position of the edge skin to be produced by the silicon rod to be cut is not correspondingly supported: when the cutting wire saw in the cutting unit finally penetrates out of the silicon rod to be cut, the edge can be broken due to the edge skin; after the silicon rod to be cut on the rotary bearing table in the cutting area completes the cutting operation, the flaw-piece generated after cutting may fall or overturn due to no corresponding support. Therefore, in certain embodiments, the flaw-piece discharging device disclosed in the present application includes a flaw-piece jacking mechanism for jacking a flaw-piece generated after the silicon rod to be cut is subjected to the squaring and cutting.

The flaw-piece jacking mechanism is arranged on the periphery of the rotary bearing table, and after the cutting device cuts the silicon rod to be cut borne by the rotary bearing table in the cutting area for one time, the cut side surface can form a flaw-piece after cutting. Therefore, in practical application, the cutting side corresponding to the cutting scroll saw at the periphery of the rotary bearing table is provided with a corresponding flaw-piece jacking mechanism so as to jack the corresponding flaw-piece. Through the flaw-piece jacking mechanism can jack and hold the flaw-piece generated after the cutting operation is performed on the silicon rod to be cut through the cutting device, so that the relative displacement between the flaw-piece and the cut silicon rod is avoided, the situation that the cutting wire saw in the cutting device collapses when penetrating out the silicon rod to be cut is prevented, the phenomena that the flaw-piece falls, topples and the like, and the cut silicon rod is damaged due to the contact of the flaw-piece are avoided.

Referring to fig. 14 to 16, fig. 14 is a schematic view illustrating an application of a boundary skin jacking mechanism in a silicon rod unloading device of the silicon rod slicing and grinding all-in-one machine in an embodiment of the present invention, fig. 15 is a top view of fig. 14, and fig. 16 is a schematic view illustrating a structure of the boundary skin jacking mechanism in the silicon rod unloading device of the silicon rod slicing and grinding all-in-one machine in an embodiment of the present invention.

With reference to fig. 14 to 16, the flaw-piece jacking mechanism in this embodiment includes a jacking assembly and a jacking driving unit, where the jacking assembly is configured to jack the bottom of the flaw-piece, and the jacking driving unit is configured to drive the jacking assembly to adjust a jacking position.

In this embodiment, the cutting unit comprises two cutting wire saws, which are mutually crossed, and the crossing angle of the two cutting wire saws is 90 °, namely, the two cutting wire saws are mutually orthogonal, and the two mutually orthogonal cutting wire saws are used for cutting the silicon rod to be cut at the cutting position to form two orthogonal side cutting surfaces. Correspondingly, two corresponding flaw-piece jacking mechanisms are arranged on the periphery of the rotary bearing table and on each cutting side corresponding to the cutting wire saw, and one flaw-piece generated after cutting is jacked by the two flaw-piece jacking mechanisms. In the embodiment shown in fig. 14, two pelt jacking mechanisms 71 for jacking one of the pelts 101 can be provided on a mounting structure, and each of the pelt jacking mechanisms 71 can comprise a jacking assembly 711 and a jacking drive unit 712.

The jacking assembly 711 is used to jack the bottom of the flaw-piece 101. As shown in fig. 16, the top bracket component 711 further includes: a top bar seat 713 and at least one top bar 715 arranged in the top bar seat 713 and capable of lifting.

The ram seat 713 may be fixedly disposed, for example, the ram seat 713 may be fixedly disposed on a mounting structure, such as a mounting plate or block, for example. The ejector pin seat 713 has a hollow accommodating space and is provided with an ejector pin hole.

The top bar 715 is arranged in the accommodating space of the top bar base 713 in a liftable manner through the top bar hole, the top bar 715 has a stressed bottom end 7151 and a jacking end 7153 which are opposite, wherein the jacking end 7153 of the top bar 715 can pass through the top bar hole and can move up and down relative to the top bar base 713. In practical applications, the stressed bottom end 7151 of the top bar 715 is stressed to drive the supporting end 7153 of the top bar 715 to move up and down relative to the top bar base 713.

In some embodiments, to enable the pin 715 to move up and down relative to the pin base 713, the top bracket assembly 711 further includes: and an elastic member 717 provided on the top bar 715 and located between the top bar 715 and the top bar seat 713. The resilient member 717 allows the top bar 715 to move up and down relative to the top bar base 713, i.e., the top end 7153 of the top bar 715 can move telescopically through the top bar hole. In some embodiments, the elastic member 717 may be, for example, a compression spring, and the compression spring 717 may be defined in the receiving space between the stem seat 713 and the locking portion 7155 of the stem 715. The spring 717 is compressed to allow the lift movement of the plunger 715 relative to the plunger seat 713. That is, when the compression spring 717 is compressed (the force applied to the compression spring is greater than the elastic force of the compression spring), the supporting end 7153 of the top bar 715 is driven to move upward, and when the compression spring 717 is not or is slightly applied (the force applied to the compression spring is less than the elastic force of the compression spring), the supporting end 7153 of the top bar 715 is driven to move downward.

In some embodiments, the jacking end 7153 of the ram 715 may also be provided with a cushioning structure, for example, the cushioning structure may be a cushion pad. The cushion pad is made of, for example, a rubber material having elasticity, or a silicone rubber or other material having elastic deformation, damping properties or cushioning properties.

The jacking driving unit 712 is used for driving the jacking rods 715 in the jacking assembly 711 to adjust jacking positions. As mentioned above, the top bar 715 in the top support assembly 711 has a stressed bottom end 7151, and the top support driving unit 712 provides a force to the stressed bottom end 7151 of the top bar 715.

As shown in fig. 16, the jacking driving unit 712 further includes a driving cylinder 7124 with an expansion link 7122. Taking the driving cylinder as an example, the driving cylinder 7124 is fixedly disposed, for example, the driving cylinder 7124 may be fixedly disposed on a mounting structure, and the retractable rod 7122 is associated with the stressed bottom end 7151 of the push rod 715. Thus, the jacking driving unit 712 can drive the jacking rod 715 to make the jacking rod 715 move up and down relative to the jacking rod seat 713, so as to adjust the jacking position of the jacking rod 715.

In some embodiments, as shown in fig. 16, the driving cylinder 7124 is disposed beside the top rod seat 713, and the axis of the telescopic rod 7122 of the driving cylinder 7124 is disposed at an angle to the axis of the top rod 715, i.e., an effective angle is formed between the telescopic rod 7122 and the top rod 715. In different embodiments, the included angle between the axis of the retractable rod 7122 of the driving cylinder 7124 and the axis of the top bar 715 may be any value within 60 ° to 120 °, such as 60 °, 61 °, … …, 65 °, … …, 69 °, 70 °, 71 °, … …, 75 °, … …, 79 °, 80 °, 81 °, … …, 85 °, … …, 89 °, 90 °, 91 °, … …, 95 °, … …, 99 °, 100 °, 101 °, … …, 105 °, … …, 119 °, 110 °, 111 °, … …, 115 °, … …, 119 °, 120 °, and the like, and the included angle may be an angle that is not a positive integer within the range of 60 ° to 120 ° according to the installation error of the device. Taking the included angle as 90 °, the top bar 715 may be vertically disposed, and the expansion bar 7122 may be horizontally disposed.

In order to realize that the driving cylinder 7124 drives the ejector rod 715 to move up and down relative to the ejector rod seat 713 through the telescopic rod 7122, the stressed bottom end 7151 of the ejector rod 715 and the acting end (i.e., the free end) of the telescopic rod 7122 may adopt a wedge-shaped structure, i.e., the stressed bottom end 7151 of the ejector rod 715 is designed into a wedge-shaped structure or a wedge block is added to the stressed bottom end 7151 of the ejector rod 715, correspondingly, the acting end (i.e., the free end) of the telescopic rod 7122 is designed into a wedge-shaped structure or a wedge block is added to the acting end (i.e., the free end) of the telescopic rod 7122, and the wedge-shaped structure or the wedge face of the wedge block of the stressed bottom end 7151 of the ejector rod 715 is correspondingly matched with the wedge-shaped structure or the wedge face of the wedge block of the acting end (i.e., the free end) of the telescopic rod 7122. Still take the ejector pin 715 to set up for erectting and the telescopic link 7122 sets up for the level as an example, the sum of the included angle of the wedge-shaped structure of the atress bottom end 7151 of ejector pin 715 or the wedge-shaped surface of the wedge and the horizontal plane and the included angle of the wedge-shaped structure of the action end (i.e., the free end) of telescopic link 7122 or the included angle of the wedge-shaped surface of the wedge and the horizontal plane can be 90 ° for example, therefore, the wedge-shaped structure of the atress bottom end 7151 of ejector pin 715 or the included angle of the wedge-shaped surface of the wedge and the horizontal plane, the wedge-shaped structure of the action end (i.e., the free end) of telescopic link 7122 or the included angle of the wedge-shaped surface of the wedge and the horizontal plane can have different combination modes. Of course, as mentioned above, when the included angle between the axis of the telescopic link 7122 of the driving cylinder 7124 and the axis of the push rod 715 is selected as another angle, the included angle between the wedge-shaped structure of the stressed bottom end 7151 of the push rod 715 or the wedge-shaped surface of the wedge block and the horizontal plane, and the included angle between the wedge-shaped structure of the acting end (i.e., the free end) of the telescopic link 7122 or the wedge-shaped surface of the wedge block and the horizontal plane may be different, and will not be described herein again.

In addition, the angle between the axis of the telescopic rod 7122 of the driving cylinder 7124 and the axis of the top rod 715 may be any value within 60 ° to 120 °, which is also only exemplary, and is not intended to limit the arrangement of the telescopic rod 7122 and the top rod 715 of the driving cylinder 7124 in the present application, for example, in some embodiments, in the case that the equipment space is feasible, the driving cylinder 7124 and the telescopic rod 7122 thereof are located right below the top rod seat 713 and are also arranged vertically, that is, the axis of the telescopic rod 7122 of the driving cylinder 7124 is aligned with the axis of the top rod 715, that is, the angle between the two is 180 ° or about 180 °.

Therefore, when the flaw-piece jacking mechanism is applied, the jacking driving unit provides acting force to the ejector rod in the jacking component so as to enable the ejector rod to move up and down and contact and jack the bottom of the silicon rod to be cut, which is borne by the rotary bearing table, after the ejector rod moves.

Of course, the flaw-piece jacking mechanism can be modified in other ways. For example, in some variations, the flaw-piece jacking mechanism includes a support member including a base attached to one side of the rotatable carrier and a jacking portion extending upwardly from the base. In this embodiment, the base is set to be a flat plate structure adapted to the side surface of the rotary bearing table, but not limited thereto, the base may also be set to be a curved plate structure or other special-shaped structures, the jacking portion is set to be two jacking pillars located at two sides of the base, the extending height of the jacking pillars is consistent with the height of the bearing surface of the rotary bearing table, and in practice, the jacking portion may also be a top plate or a top rod extending upwards from the base. When the cutting device performs cutting of the silicon rod to be cut on the rotating bearing table, the corresponding flaw-piece can be supported by the supporting piece, so that the situation that the cutting wire saw in the cutting device collapses when penetrating out the silicon rod to be cut is effectively prevented, and the flaw-piece can be prevented from falling and overturning.

In certain variations, the flaw-piece jacking mechanism includes a movable support member and a locking control member. The movable supporting piece comprises a movable base connected to one side surface of the rotary bearing table, a supporting part extending upwards from the movable base, and a power generation structure providing the supporting part to move up and down. In some embodiments, the movable base may be, for example, a flat plate structure adapted to a side surface of the rotary carrying table, but not limited thereto, and the movable base may also be, for example, a curved plate structure or other special-shaped structures. The top support part is at least two top rods extending upwards from the movable base, but not limited to this, and the top support part may also be a top plate or a top pillar extending upwards from the movable base, for example. The power generating structure comprises two support legs arranged on the movable base and two springs respectively sleeved on the two support legs, but not limited thereto, and the power generating structure can also adopt structures such as a torsion spring, an elastic sheet and the like. The supporting legs and the connected mandril can move up and down relative to the rotary bearing table by utilizing the elasticity of the springs. In this embodiment, the locking control member is used for controlling the movable support member in a locked state when the movable support member abuts against the bottom of the silicon rod to be cut. In an initial state, the ejector rod is exposed on the bearing surface of the rotary bearing platform under the action of the support legs and the springs, when a silicon rod to be cut is placed, the ejector rod overcomes the elasticity of the springs to move downwards after being pressed by the silicon rod to be cut until the silicon rod to be cut is completely placed on the bearing surface of the rotary bearing platform, at the moment, the electromagnetic lock serving as the locking control piece is electrified, and the movable base in the movable bearing piece is tightly adsorbed through strong magnetic force generated by an electromagnetic principle, so that the ejector rod is controlled in a locking state. When the cutting device performs cutting of the silicon rod to be cut, which is borne by the rotary bearing platform corresponding to the cutting area in the silicon rod conversion device, the movable bearing piece in the locking state can support the corresponding flaw-piece, so that the situation that the cutting wire net in the wire cutting unit is broken when penetrating out of the silicon rod to be cut can be effectively prevented, and the flaw-piece can be prevented from falling, overturning and the like.

The utility model discloses an edge skin discharge apparatus still includes edge skin hoisting unit, is used for promoting the edge skin is so that the edge skin top is salient the silicon rod of having cut.

After cutting the silicon rod by the cutting wire saw in the cutting unit, the produced flaw-piece depends on the rotary bearing platform or depends on the jacking action of the flaw-piece jacking mechanism continues to stay on the rotary bearing platform and abuts against the cut silicon rod, so that the flaw-piece produced after cutting and the cut silicon rod are required to be subjected to relative displacement, the flaw-piece is clamped by the protruding parts formed by displacement in a staggered manner, the flaw-piece is subsequently transported, and the flaw-piece lifting unit in the flaw-piece discharging device is used for lifting the flaw-piece so that the top end of the flaw-piece protrudes out the cut silicon rod.

After the cutting unit in the cutting device performs cutting and squaring on the silicon rod to be cut, which is borne by the rotary bearing platform in the cutting area, the cut side surface can form a flaw-piece after cutting. Therefore, in practical applications, a corresponding flaw-piece lifting unit is arranged on the cutting side corresponding to the cutting wire saw to lift the corresponding flaw-piece. The flaw-piece can be lifted by the flaw-piece lifting unit so that the top end of the flaw-piece protrudes out of the cut silicon rod, and the protruding flaw-piece can be discharged.

In the following description, the silicon rod slicing and grinding all-in-one machine shown in fig. 1, 2, and 9 and the silicon rod slicing and grinding all-in-one machine shown in fig. 10 to 12 will be used as an example to describe the flaw-piece lifting unit.

Fig. 17 is a schematic structural view of a flaw-piece lifting unit in a silicon rod unloading device of a silicon rod slicing and grinding all-in-one machine according to an embodiment of the present disclosure.

In this embodiment, the cutting unit includes two cutting wire saws, two cutting wire saw intercrossing, the hypothesis the crossing angle of two wire cutting wire saws is 90, promptly two wire cutting wire saw mutual orthogonals, two mutually orthogonals cutting wire saws be used for right the silicon rod that cutting position department was waited to cut cuts in order to form the side tangent plane of two orthorhombic. Correspondingly, each cutting side corresponding to the cutting wire saw is provided with a corresponding edge leather lifting unit, and an edge leather generated after cutting is lifted by the edge leather lifting unit. In the embodiment shown in fig. 17, the bark lifting unit 72 for lifting the bark may be disposed at a bobbin corresponding to the cutting unit (for example, the first bobbin 231 of the first cutting unit 23 in fig. 9, the first bobbin 631 of the first cutting unit 63 in fig. 13, the second bobbin 251 of the second cutting unit 25 in fig. 9, the second bobbin 651 of the second cutting unit 65 in fig. 13, and in fig. 17, the first bobbins 231, 631 of the first cutting units 23, 63 are taken as an example for explanation).

As shown in fig. 17, the edge leather lifting unit 72 is fixedly disposed on the bobbin of the cutting unit, so that the edge leather lifting unit 72 can move up and down along with the cutting unit. Specifically, referring to fig. 18, the pelt lifting unit 72 includes a jacking member 721 and a telescopic member 723, the jacking member 721 is driven by the telescopic member 723 to make telescopic movement, and the jacking member 721 is controlled to make stretching movement to support the bottom of the pelt 101 to jack the pelt 101.

In some embodiments, jacking members 721 are used to bear against the bottom of the flaw-piece 101 to jack the flaw-piece 101. In some implementations, the jacking member 721 may be a jacking plate, jacking block, or jacking rod.

In some embodiments, the telescoping member 723 may be, for example, a drive cylinder with a telescoping rod or a drive hydraulic cylinder 723. Taking the driving cylinder as an example, the driving cylinder 723 is fixedly disposed, for example, the driving cylinder 723 may be fixedly disposed on the first wire frame 631 through a seat 722, wherein the seat 722 is provided with a mounting hole, an expansion rod of the driving cylinder 723 may be connected to the lifting member 721, and the driving cylinder 723 may drive the expansion rod to drive the lifting member 721 to move in an expansion and contraction manner. Here, the telescopic motion of the jacking member 721 includes a contraction motion of the jacking member 721 and an extension motion of the jacking member 721, where the contraction motion of the jacking member 721 specifically means that the driving cylinder 723 drives the telescopic rod to contract to drive the jacking member 721 to move away from the rotary loading platform and the loaded edge leather 101, and the extension motion of the jacking member 721 specifically means that the driving cylinder 723 drives the telescopic rod to extend to drive the jacking member 721 to move close to the rotary loading platform and the loaded edge leather 101. Certainly, the telescopic component 723 may also be implemented in other manners, for example, the telescopic component 723 may also be, for example, a servo motor with a lead screw, where the lead screw is connected to the jacking component, and the lead screw is driven by the servo motor to rotate to drive the connected jacking component 721 to perform telescopic motion, for example, the lead screw is driven to rotate forward to drive the jacking component 721 to perform contraction motion and to drive the lead screw to rotate backward to drive the jacking component 721 to perform extension motion, or the lead screw is driven to rotate forward to drive the jacking component 721 to perform extension motion and to drive the lead screw to rotate backward to drive the jacking component 721 to perform contraction motion.

In practical applications, taking the embodiment shown in fig. 10 to 13 as an example, assuming that the first cutting unit 63 is going to perform an extracting and cutting operation on the silicon rod in the first cutting area, in an initial state, the telescopic rod of the telescopic member 723 drives the lifting member 721 to be in a contracted state, the first cutting unit 63 is driven to descend along with the cutting support 62 so that the cutting wire net formed by the first cutting wire saw and the second cutting wire saw in the first cutting unit 63 extracts and cuts the silicon rod to be cut in the first cutting area until each cutting wire saw penetrates through the silicon rod to be cut, one complete cutting of the silicon rod to be cut is completed and a bark is formed, at this time, the bark lifting unit 72 has descended to the bottom along with the cutting support 62 and the first wire frame 631 and the bark lifting unit 72 is located below the bottom of the silicon rod in a vertical height, the telescopic member 723 drives the telescopic rod to stretch to drive the lifting member 721 to approach the bark 101 until the lifting member 721 is inserted below the bark, subsequently, the first cutting unit is driven to ascend along with the cutting support 62 and the first wire frame 631, the flaw-piece lifting unit 72 ascends along with the first wire frame 631, the jacking flaw-piece 101 ascends and displaces relative to the silicon rod 100 which is subjected to one-time cutting, so that the top end of the flaw-piece 101 protrudes out of the silicon rod 100, when the top end of the flaw-piece 10 meets a set condition compared with the protruding portion of the silicon rod 100, the cutting support 62 and the first wire frame 631 can be controlled to stop ascending, and thus, the top end of the flaw-piece 101 can be used as a force application portion for grabbing, so that the flaw-piece 101 is grabbed and unloaded, and then the driving cylinder drives the telescopic rod to contract to drive the jacking piece 721 to return to the initial state and simultaneously control the cutting support 62 and the first wire frame 631 to drive the first cutting unit 63 and the flaw-piece lifting unit 72 to continuously ascend above the silicon rod 100 for performing the next-time cutting operation.

Of course, other variations of the above-described pelt lifting unit are possible. For example, in some embodiments, the leather lifting unit may include an absorbing member and a telescopic member for driving the absorbing member to perform telescopic movement, and the absorbing member is controlled by the telescopic member to abut against the leather and absorb the leather. The adsorption piece further comprises an abutting plate and an adsorption element. The abutting plate can be an arc-shaped plate matched with the arc-shaped surface of the edge leather, and can be fully contacted with the arc-shaped surface of the edge leather when the abutting plate abuts against the edge leather. The suction element may be, for example, a vacuum chuck, and a plurality of vacuum chucks may be disposed on a contact surface of the backup plate to be in contact with the edge skin. The telescopic component can be, for example, an air cylinder with a telescopic rod or a servo motor with a screw rod, taking the air cylinder with a telescopic rod as an example, the telescopic rod can be connected with the abutting plate in the jacking piece through a connecting structure, the air cylinder can drive the telescopic rod to contract to drive the abutting plate to be away from the flaw-piece, and the air cylinder can drive the telescopic rod to extend to drive the abutting plate to be close to the flaw-piece and to be adsorbed to the flaw-piece by the adsorbing element after the abutting plate is contacted with the flaw-piece. Subsequently, the cutting support is driven to rise, the flaw-piece lifting unit and the cutting unit rise along with the cutting support, and the flaw-piece lifting unit can drive the flaw-piece to move upwards relative to the silicon rod subjected to the primary cutting operation by utilizing the adsorption force, so that the top end of the flaw-piece protrudes out of the silicon rod subjected to the primary cutting operation.

The edge skin formed after cutting and evolution can be lifted and displaced relative to the cut silicon rod by using the edge skin lifting unit, so that the top of the edge skin protrudes out of the cut silicon rod. It should be noted that, since the flaw-piece lifting unit is disposed on the bobbin, when the flaw-piece lifting unit is required to lift the flaw-piece, the driving bobbin and the cutting unit thereon are lifted up to drive the flaw-piece lifting unit to lift, so that the cutting wire saw in the cutting unit is also lifted up. The wire saw is then, during the raising, to be returned along the cutting path in the previous cutting operation. Generally, in some cases, the cutting wire itself has a certain degree of flexibility, and the state of the cutting wire saw when it is lowered for cutting inside the silicon rod to be cut is likely to be different from the state of the cutting wire saw after the cutting operation is completed and the silicon rod to be cut is penetrated, so that when the cutting unit is lifted, it is difficult to require the cutting wire saw in the cutting wire web to return along the original cutting path and ensure that the cut silicon rod is not interfered with.

In practical applications, when the cutting wire saw in the cutting wire net moves upward and is ready to bypass the cut silicon rod, the cutting wire saw is likely to interfere with the cut silicon rod, so that damage may be caused to the cut silicon rod, for example, the cut silicon rod may break under the interference of the cutting wire saw.

To avoid the above-mentioned problem or other similar problems, the flaw-piece discharge apparatus in this application still includes the line mechanism of dialling with the cooperation of flaw-piece hoisting unit. The wire shifting mechanism can be used for shifting the cutting wire net to expand towards the outer side when the cutting wire saw is arranged in the cutting wire net so as to avoid the interference of the cutting wire saw and the cut silicon rod.

In certain embodiments, the wire setting mechanism includes a drivable member and a wire setting assembly. For a specific implementation of the wire-dialing mechanism, reference may be made to patent publications such as CN109129947A, which are not described herein again.

In addition, utilize above-mentioned flaw-piece hoisting unit to realize promoting the flaw-piece so that the top protrusion of flaw-piece in the silicon rod, nevertheless, under some circumstances, because of the flaw-piece hoisting unit is located the bottom below of flaw-piece, the stress point of flaw-piece concentrates on the below basically, when the flaw-piece length is longer and dead weight is great, at the in-process that utilizes the flaw-piece hoisting unit to promote the flaw-piece, probably produces the risk that the flaw-piece topples to the side, in addition, the roughness of the bottom of flaw-piece also is a risk factor that increases the side and topples.

Here, the flaw-piece discharging apparatus disclosed in the present application further includes a flaw-piece stabilizing unit for stabilizing the flaw-piece.

In this embodiment, the cutting unit comprises two cutting wire saws, which are mutually crossed, and the crossing angle of the two cutting wire saws is 90 °, namely, the two cutting wire saws are mutually orthogonal, and the two mutually orthogonal cutting wire saws are used for cutting the silicon rod to be cut at the cutting position to form two orthogonal side cutting surfaces. Correspondingly, a corresponding edge strip stabilizing unit is arranged on each cutting side corresponding to the cutting wire saw, and one edge strip generated after cutting is stabilized by the edge strip stabilizing unit. In the embodiment shown in fig. 12 and 13, the bark stabilizing unit 73 for stabilizing the bark may be provided at a bobbin corresponding to the cutting unit (e.g., a first bobbin 631 of the first cutting unit 63 in fig. 13, a second bobbin 651 of the second cutting unit 65 in fig. 13).

Referring to fig. 19 and 20, fig. 19 is a schematic structural view illustrating a stabilizing unit in a silicon rod unloading device of a silicon rod slicing and grinding all-in-one machine according to an embodiment of the present invention, and fig. 20 is a top view of fig. 19. With reference to fig. 19 and 20, the flaw-piece discharging device further includes a flaw-piece stabilizing unit 73, and the flaw-piece stabilizing unit 73 is fixedly disposed on the bobbin of the cutting unit, so that the flaw-piece stabilizing unit 73 can move up and down along with the cutting unit. Specifically, the pelt stabilizing unit 73 comprises a support assembly 731 and a drive member 732 connected to the support assembly 731.

In some embodiments, the support assembly 731 includes a mounting feature 733 and a flaw strip stop 735 disposed on the mounting feature 733. In certain implementations, the edge stop 735 can be, for example, an edge stop wheel (in the following description, the edge stop wheel is identified as 735), wherein the edge stop wheel 735 is journaled to the mounting member 733. The number of the edge rollers 735 may be one or more, for example, in some embodiments, the support assembly 731 includes two edge rollers 735, and the two edge rollers 735 are spaced apart and respectively coupled to two opposite sides of the mounting part 733, i.e., the edge rollers 735 can rotate relative to the mounting part 733. In some embodiments, the mounting part 733 may be a column structure or a frame structure, for example, the column structure or the frame structure may include a fixing portion 7331 and a movable portion 7333, wherein the fixing portion 7331 is configured to be fixed to a wire frame of the cutting unit, for example, a mounting hole is formed on the fixing portion 7331, the movable portion 7333 is configured to be provided with the edge blocking wheel 735, and the movable portion 7333 is movably connected to the fixing portion 7331, for example, the movable portion 7333 is movably connected to the fixing portion 7331 through a rotating shaft. The wheel axis of the edge skin barrier wheel 735 is identical to that of the corresponding cutting wire saw, and the two orthogonal cutting wire saws in the first cutting unit 23 shown in fig. 9 or the first cutting unit 63 shown in fig. 13 are respectively arranged along the M-axis and the N-axis, so that the wheel axis of the edge skin barrier wheel 735 in the supporting assembly 731 of the cutting wire saw arranged corresponding to the M-axis is also arranged along the M-axis, and the wheel axis of the edge skin barrier wheel 735 in the supporting assembly 731 of the cutting wire saw arranged corresponding to the N-axis is also arranged along the N-axis.

In some embodiments, the contact portion of the edge leather baffle 735 with the edge leather 101 is provided with a bevel or a circular arc surface to obtain as much contact area with the edge leather as possible. As known, the silicon rod to be cut is a cylindrical structure with a circular cross section, the outer peripheral edge of the edge skin generated after the silicon rod to be cut is subjected to squaring and cutting by the wire cutting device is arc-shaped, the inner side of the edge skin baffle wheel 735 contacts the edge skin earlier than the outer side of the edge skin baffle wheel, and therefore, the inner side of the edge skin baffle wheel 735 is provided with an inclined surface or an arc surface, and the radian of the arc surface is matched with or equivalent to the outer peripheral edge of the edge skin.

In some embodiments, the driving member 732 may be, for example, a driving cylinder with a telescoping rod or a driving hydraulic cylinder 732. Taking the driving cylinder as an example, the driving cylinder 732 is fixedly disposed, for example, the driving cylinder 732 may be fixedly disposed on a wire frame of the cutting unit through a seat 7322, wherein the seat 7322 is opened with an installation hole, the telescopic rod of the driving cylinder 732 may be connected to the movable portion 7333 of the installation part 733, and the driving cylinder 732 may drive the telescopic rod to drive the movable portion 7333 of the installation part 733 and the edge blocking wheel 735 thereon to move on the fixing portion 7331 and to make telescopic motion relative to the edge. Here, the telescopic motion of the movable portion 7333 of the mounting member 733 and the edge leather blocking wheel 735 thereon includes a contraction motion of the movable portion 7333 and the edge leather blocking wheel 735 thereon and an extension motion of the movable portion 7333 and the edge leather blocking wheel 735 thereon, wherein the contraction motion of the movable portion 7333 and the edge leather blocking wheel 735 thereon specifically means that the driving cylinder 732 drives the telescopic rod to contract to drive the movable portion 7333 to move to the fixing portion 7331 so as to make the edge leather blocking wheel 735 far away from the edge leather 101, and the extension motion of the movable portion 7333 and the edge leather blocking wheel 735 thereon specifically means that the driving cylinder 732 drives the telescopic rod to extend to drive the movable portion 7333 to move to the fixing portion 7331 so as to make the edge leather blocking wheel 735 close to the edge leather 101 until the wheel surface of the edge leather blocking wheel 735 contacts the edge leather and finally abuts against the edge leather, thereby realizing the support.

Of course, the above-mentioned embodiment of the driving part using the driving cylinder with the telescopic rod or the driving hydraulic cylinder may be modified, for example, in some embodiments, the driving part may also include a screw rod and a driving motor, for example, the driving motor may be fixedly disposed on a wire rack of the cutting unit, a motor shaft of the driving motor is associated with the screw rod, and the screw rod is directly screwed or screwed with the movable portion of the mounting part through a switching structure. Forward rotation is made to driving motor drive lead screw, and forward rotation's lead screw can drive the shrinkage motion is made to the movable part of installing component, makes leather fender wheel in the movable part keeps away from the flaw-piece, correspondingly, reverse rotation is made to driving motor drive lead screw, and reverse rotation's lead screw can drive the motion is made to the movable part of installing component to extend, makes leather fender wheel in the movable part is close to the flaw-piece, until the wheel face contact flaw-piece of leather fender wheel and finally support and lean on the flaw-piece, realize supporting.

In this application flaw-piece discharge apparatus, the flaw-piece stabilizing unit with the cooperation of flaw-piece hoisting unit is used, promptly, in practical application, after utilizing cutting unit to treat the silicon rod of cutting and carry out the evolution cutting and form the flaw-piece, telescopic part drive among the flaw-piece hoisting unit the bottom of supporting flaw-piece 101 after the extension motion is made to the jacking piece, the drive unit drive among the flaw-piece stabilizing unit the supporting component supports after the extension motion the lateral part of flaw-piece is promoting the flaw-piece in-process, the flaw-piece hoisting unit holds the bottom of holding the flaw-piece in order to promote the flaw-piece, at this moment, the unit accessible of stabilizing the flaw-piece is supported the lateral part of flaw-piece is in order to stabilize the flaw-piece to ensure the stability that the flaw-piece promoted, avoid appearing for example dropping, toppling, or accident such as the side is toppled over. It is thus clear that in the lifting of the flaw-piece, the flaw-piece lifting unit holds the bottom of the flaw-piece and the flaw-piece stabilizing unit supports the side of the flaw-piece, and therefore the setting position of the flaw-piece catch wheel in the flaw-piece stabilizing unit is higher than the setting position of the jacking piece in the flaw-piece lifting unit.

In addition, it should be noted that, as mentioned above, in the embodiment of the present application where the scrap discharging apparatus includes the scrap jacking mechanism, the scrap stabilizing unit may not only cooperate with the scrap lifting unit, but also cooperate with the scrap jacking mechanism in some embodiments. For example, when a cutting unit is used for conducting an evolution cutting operation on a silicon rod to be cut, the driving part in the flaw-piece stabilizing unit drives the supporting component to make stretching movement and then supports the side part of the silicon rod to be cut, the flaw-piece jacking mechanism jacks and butts the bottom part of the silicon rod to be cut during cutting, and the flaw-piece stabilizing unit can stabilize the flaw-piece by supporting the side part of the flaw-piece.

The utility model discloses flaw-piece discharge apparatus still includes the flaw-piece and transports the unit, be used for with the flaw-piece transports away and unloads from the cutting area.

In the embodiments shown in fig. 1, 2 and 9 and in the embodiments shown in fig. 10 to 13, each of the pelt discharge devices can comprise a pelt transfer unit. Taking the embodiment shown in fig. 1, 2 and 9 as an example, the first flaw-piece discharging device comprises a first flaw-piece transferring unit 74 corresponding to the first cutting unit 23 and used for transferring and discharging flaw-pieces in the first cutting area, and the second flaw-piece discharging device comprises a second flaw-piece transferring unit 75 corresponding to the second cutting unit 25 and used for transferring and discharging flaw-pieces in the second cutting area.

In certain embodiments, the flaw-piece transfer unit may be, for example, a clamping transfer unit with which it is possible to clamp the tip of the flaw-piece and to lift the flaw-piece to disengage the cut silicon rod and to transfer the flaw-piece to a flaw-piece discharge area.

In certain embodiments, the gripping transfer unit comprises: the clamping mechanism is used for clamping or releasing the top end of the flaw-piece; and the lifting driving mechanism is used for driving the clamping mechanism to move up and down so that the clamping mechanism can separate the clamped flaw-piece from the cut silicon rod.

The clamping mechanism can comprise a cover body and a clamping assembly arranged in the cover body. The clamping assembly is arranged inside the cover body; the clamping assembly and the cover body form a clamping space for clamping the edge leather.

In some embodiments, the clamping assembly may include a retractable clamping member disposed inside the cover body, and a clamping space for clamping the flaw-piece is formed between the clamping member and the cover body. The cover body is used for covering the flaw-piece, and the size of the cover body capable of covering the flaw-piece is slightly larger than the cross section circle of the silicon rod to be cut. For example, the first cutting unit includes two orthogonal first cutting wire saws, the second cutting unit includes two orthogonal second cutting wire saws, the warp can form two kerbs that are 90 ° angles after the first cutting unit cuts the silicon rod, the warp can form two kerbs that are 90 ° angles after the second cutting unit cuts the silicon rod, consequently, the cover body includes that the cross-section is the semicircular arc, the centre gripping subassembly includes two orthogonal holders.

The structure of the clamping assembly is not limited to this, and in other embodiments, the clamping assembly includes an arc-shaped plate and a retractable clamping member, and a clamping space for clamping the flaw-piece is formed between the clamping member and the arc-shaped plate.

The lifting driving mechanism drives the clamping mechanism to move up and down so that the clamping mechanism separates the clamped flaw-piece from the cut silicon rod, the lifting driving mechanism can be, for example, a lifting cylinder with a lifting rod, the lifting rod is connected with the clamping mechanism, and the lifting cylinder can control the lifting rod to stretch and retract so as to drive the clamping mechanism to move up and down, but not limited thereto. For example, the lifting driving mechanism can also be a screw rod assembly driven by a motor, the screw rod assembly is connected with the clamping mechanism, and the motor is used for driving the screw rod assembly to lift so as to drive the clamping mechanism to do lifting motion.

The flaw-piece and flaw-piece transfer unit can further comprise a translation mechanism moving along at least one direction. In certain embodiments, the translation mechanism includes a translation rail disposed along at least one direction and a drive assembly coupled to the gripper mechanism for driving the gripper mechanism to move on the translation rail. The driving assembly may be a screw rod assembly driven by a motor, or an air cylinder or a swing hydraulic cylinder with an expansion link, but not limited thereto.

In addition, in some embodiments, the flaw-piece discharging device can further comprise a flaw-piece conveying structure, and the flaw-piece conveying structure is arranged in the flaw-piece discharging area and used for conveying the flaw-pieces conveyed by the flaw-piece conveying unit. In certain embodiments, the flaw-piece conveying structure may be, for example, a conveyor belt. It is easy to understand that the flaw-piece discharging area is an area for discharging the flaw-pieces in the silicon rod processing equipment, and specifically, the flaw-piece discharging area is an area corresponding to the lower side of the flaw-piece transferring unit after the flaw-pieces are transferred from the cutting area. In actual operation, transfer the flaw-piece by the flaw-piece transfer unit and transfer to the flaw-piece district of unloading by the cutting district, the centre gripping subassembly in the flaw-piece transfer unit loosens in order to release the flaw-piece to the conveyer belt as flaw-piece transport structure on, by the conveyer belt is carried away the flaw-piece.

In certain embodiments, the flaw-piece discharge apparatus can further comprise a flaw-piece drum disposed in the flaw-piece discharge area. The barrel opening of the side leather barrel can be designed to be large or be a horn opening, so that the side leather can be conveniently placed in the barrel without obstacles, and the height of the barrel arm of the side leather barrel is also high, so that the placed side leather can be prevented from overturning and the like. So, by the flaw-piece transfer unit removes the flaw-piece by the cutting district to a flaw-piece section of thick bamboo, then can be followed the flaw-piece by operating personnel take out in the flaw-piece section of thick bamboo.

Of course, the discharging of the flaw-piece generated after the cutting of the silicon rod to be cut is not limited thereto. For example, in other embodiments, the flaw-piece discharge device may include both a flaw-piece drum and a flaw-piece conveying structure, wherein the flaw-piece conveying structure may be, for example, a conveyor belt, and the flaw-piece drum is disposed adjacent to the starting end of the conveyor belt (e.g., the flaw-piece drum is located beside or directly above the starting end of the conveyor belt, etc.). The barrel opening of the side leather barrel can be designed to be large or be a horn opening, so that the side leather can be conveniently placed in the barrel without obstacles, and the height of the barrel arm of the side leather barrel is also high, so that the placed side leather cannot overturn and the like. In practical application, the edge leather tube can be in a turnover design, and each edge leather in the edge leather tube can be smoothly transferred to the conveying belt by turning over the edge leather tube. For example, the bottom of the edge leather tube is provided with a turnover driving mechanism, and the turnover driving mechanism may include a turnover plate, a rotating shaft, and a turnover driving source (e.g., a turnover motor or a turnover cylinder). So, by the flaw-piece transfer unit with the flaw-piece by the cutting district transfer extremely back in the flaw-piece section of thick bamboo, the flaw-piece in the upset drive section of thick bamboo of flaw-piece section of thick bamboo is shifted to on the conveyer belt, by the conveyer belt is carried away the flaw-piece.

The application discloses silicon rod processing equipment, usable silicon rod conversion equipment can shift the silicon rod between each processingequipment orderly and seamlessly, utilize cutting device to carry out the evolution cutting to the silicon rod in order to form the silicon rod that the cross-section is similar rectangle, utilize the flaw-piece discharge apparatus to unload the flaw-piece that the cutting device produced after carrying out the evolution cutting to the silicon rod, utilize first carrier and the second carrier among the silicon rod device to carry the silicon rod of different forms respectively and make the upset through the drive carrier with the silicon rod that will bear at present place the state between the difference and change, thereby can realize the loading operation of the silicon rod of treating processing and the uninstallation operation of the silicon rod of processing simultaneously, thereby accomplish the integration operation of the evolution of silicon rod, improve the quality of production efficiency and product processing operation.

As described above, in the embodiment that the silicon rod processing apparatus disclosed in the present application is a silicon rod cutting and grinding all-in-one machine, the silicon rod cutting and grinding all-in-one machine further includes a grinding device for grinding the silicon rod after the silicon rod is subjected to the cutting operation by the cutting device.

With reference to fig. 1 and fig. 2, the silicon rod cutting and grinding all-in-one machine includes a grinding device 3, and the grinding device 3 is disposed in the grinding region of the silicon rod processing platform and is configured to grind the silicon rod on the grinding region of the silicon rod processing platform, which has been subjected to the cutting operation. In this embodiment, the grinding operation includes face grinding, rounding/chamfering.

The grinding device 3 has a receiving space for receiving a silicon rod which has been subjected to an open cut and is transferred from the second cutting zone to the grinding zone by means of the silicon rod transfer device 4. The grinding device 3 mainly comprises a grinding frame 31 and at least one pair of grinding tools 33, wherein the at least one pair of grinding tools 33 is oppositely arranged on the grinding frame 31 and is used for grinding the silicon rod which is positioned at the grinding position and has finished the cutting.

In this embodiment, the silicon rod after the square cutting has a rectangular-like cross section with four side cut surfaces and four connecting edge surfaces, so that the grinding tools 33 are at least one pair disposed opposite to each other with a receiving space therebetween for receiving the silicon rod 200, and after the silicon rod 200 is transferred to the grinding section and is located in the receiving space between the at least one pair of grinding tools 33, the at least one pair of grinding tools 33 can contact the pair of side cut surfaces or the pair of connecting edge surfaces opposite to each other in the silicon rod 200, and then can move up and down for grinding.

The grinding frame 31 is arranged on the machine base 1. In the present embodiment, the polishing frame 31 is a column structure or a frame structure, and serves as a support body of the polishing apparatus 3 to provide support for other components in the polishing apparatus 3.

Wherein, the grinding frame 31 can be slidably disposed on the machine base 1 through a sliding mechanism. In this embodiment, the sliding mechanism can realize sliding in at least one direction. For example, the slide mechanism may allow the polishing head 31 to slide in the advancing and retreating direction (in the X-axis direction as shown in fig. 2). Specifically, the slide mechanism may include a forward and backward guide rail and a forward and backward drive source, or the slide mechanism may include a forward and backward movement guide rail, a forward and backward movement slider corresponding to the forward and backward movement guide rail, and a forward and backward drive source. The forward and backward driving source may be, for example, a driving motor.

The grinding tool 33 can be slidably disposed on the grinding frame 31 by a sliding mechanism.

In certain embodiments, at least one pair of abrasive tools 33 in the abrading device 3 are independently provided. Taking a pair of grinding tools 33 as an example, the two grinding tools 33 are respectively slidably disposed on the grinding frame 31 through respective sliding mechanisms, wherein the sliding mechanisms can realize sliding movement in at least two directions. Specifically, the glide mechanism may include a first glide unit and a second glide unit, wherein, the first glide unit is the lift glide unit promptly, the lift glide unit is including locating lift guide and lift driving source on grinding frame 31, or, the lift glide unit is including locating lift guide on grinding frame 31, locating a movable mounting frame or grinding slide block on the support and lift driving source. The elevating driving source may be, for example, a driving motor. The second sliding unit includes a feeding guide rail (the feeding direction is the Y-axis direction shown in fig. 2) and a feeding driving source, which are disposed on the movable mounting frame or the grinding support and along the feeding direction, or the second sliding unit includes a feeding guide rail (the feeding direction is the Y-axis direction shown in fig. 2) and a feeding driving source, which are disposed on the movable mounting frame or the grinding support and along the feeding direction, a feeding slider disposed on the grinding tool 33, and a feeding driving source. The feeding drive source may be, for example, a drive motor.

In certain embodiments, at least one pair of abrasive tools 33 in the abrading device 3 are associated. As shown in fig. 2, taking a pair of grinding tools 33 as an example, the two grinding tools 33 are slidably disposed on the grinding frame 31 through a sliding mechanism, wherein the sliding mechanism can slide in at least two directions. Specifically, the sliding mechanism may include a first sliding unit and a second sliding unit, wherein the first sliding unit is a lifting sliding unit, the lifting sliding unit includes a lifting guide rail and a lifting driving source disposed on the grinding frame 31, or the lifting sliding unit includes a lifting guide rail disposed on the grinding frame 31, a lifting slider disposed on a common movable mounting frame or the grinding support 32, and a lifting driving source. The elevating driving source may be, for example, a driving motor. The two grinding tools 33 are slidably disposed on the common movable mounting frame or grinding support 32 through a second sliding unit, where the second sliding unit includes a feeding guide rail (the feeding direction is the Y-axis direction shown in fig. 2) and a feeding driving source, which are disposed on the common movable mounting frame or grinding support 32, along the feeding direction, or the second sliding unit includes a feeding guide rail (the feeding direction is the Y-axis direction shown in fig. 2) disposed on the common movable mounting frame or grinding support 32, along the feeding direction, a feeding slider disposed on the grinding tool 33, and a feeding driving source. The feeding drive source may be, for example, a drive motor.

Therefore, in the present embodiment, the grinding rack 31 can be slidably disposed on the machine base 1 through a sliding mechanism, so as to realize the advancing and retreating of the grinding rack 31, i.e. approaching to or departing from the silicon rod. The grinding tool 33 can be slidably disposed on the grinding frame 31 through the first sliding unit to realize the lifting of the grinding tool 33, and the grinding tool 33 can also be slidably disposed on the grinding frame 31 through the second sliding unit to realize the advancing and retreating of the grinding tool 33, that is, to control the grinding amount of the silicon rod when approaching or departing from the silicon rod.

In certain embodiments, the abrasive article may include a spindle and at least one grinding wheel, wherein the at least one grinding wheel is disposed at a working end of the spindle.

In certain embodiments, each of the abrasive articles in the abrading apparatus is a dual head structure. Specifically, each abrasive article includes: a rotary chassis; the double-head main shaft is arranged on the rotary chassis, a first end of the double-head main shaft is provided with a coarse grinding wheel, and a second end of the double-head main shaft is provided with a fine grinding wheel; and the driving motor is used for driving the rotary chassis to rotate so as to enable the position of the rough grinding wheel and the position of the fine grinding wheel in the double-head spindle to be changed. In practical application, during grinding, the rough grinding wheel of the double-head main shaft in at least one pair of grinding tools in the grinding device is used for performing rough grinding operation on the silicon rod which is subjected to the cutting, then the rotary chassis is driven to rotate so as to enable the rough grinding wheel and the finish grinding wheel in the double-head main shaft to exchange positions, and the finish grinding wheel of the double-head main shaft in at least one pair of grinding tools in the grinding device is used for performing finish grinding operation on the silicon rod which is subjected to the cutting. Wherein, the corase grind operation can include that the side tangent plane to the silicon rod that has accomplished the evolution cutting carries out the rough grinding face and connects the arris face to carry out coarse chamfering, the finish grind operation can include that the side tangent plane to the silicon rod that has accomplished the evolution cutting carries out the finish grinding face and connects the arris face to carry out the finish chamfering.

In certain embodiments, each grinding tool in the grinding apparatus comprises a rough grinding wheel and a finish grinding wheel nested within one another. For example, the rough grinding wheel is nested within the finish grinding wheel, or the finish grinding wheel is nested within the rough grinding wheel.

For example, the grinding tool includes a tool seat, and a rough grinding wheel and a finish grinding wheel both disposed on the tool seat, wherein the rough grinding wheel is nested inside the finish grinding wheel, the finish grinding wheel is larger than the rough grinding wheel, the finish grinding wheel is circular and hollow in the middle (i.e., circular ring structure), the rough grinding wheel can be circular structure or the rough grinding wheel can be circular and hollow in the middle (i.e., circular ring structure). The abrasive grain size of the finish grinding wheel is smaller than that of the rough grinding wheel, and the abrasive grain density of the finish grinding wheel is larger than that of the rough grinding wheel.

When the grinding tool comprises a rough grinding wheel and a finish grinding wheel, the silicon rod positioned by the silicon rod positioning mechanism can be subjected to rough grinding operation and finish grinding operation by using the grinding tool. Therefore, at least one of the rough grinding wheel and the finish grinding wheel is provided with a telescopic driving mechanism. For example, when the rough grinding wheel is nested in the finish grinding wheel, the rough grinding wheel may be provided with a telescopic driving mechanism, when performing rough grinding operation, the telescopic driving mechanism is used to drive the rough grinding wheel to extend out and protrude out of the finish grinding wheel, so as to perform rough grinding operation on a silicon rod by using the protruding rough grinding wheel, and when performing finish grinding operation, the telescopic driving mechanism is used to drive the rough grinding wheel to contract and sink into the finish grinding wheel, so as to perform finish grinding operation on the silicon rod by using the finish grinding wheel. Or when the rough grinding wheel is nested in the fine grinding wheel, the fine grinding wheel can be provided with a telescopic driving mechanism, when rough grinding operation is carried out, the telescopic driving mechanism is used for driving the fine grinding wheel to contract and recess in the rough grinding wheel so as to carry out rough grinding operation on a silicon rod by using the rough grinding wheel, and when fine grinding operation is carried out, the telescopic driving mechanism is used for driving the fine grinding wheel to extend out and protrude out of the rough grinding wheel so as to carry out fine grinding operation on the silicon rod by using the protruding fine grinding wheel.

For example, the finish grinding wheel is nested within the rough grinding wheel, which is larger than the finish grinding wheel, the rough grinding wheel is circular and hollow in the middle (i.e., circular ring structure), the finish grinding wheel can be circular in structure or the finish grinding wheel can be circular and hollow in the middle (i.e., circular ring structure). The abrasive grain size of the finish grinding wheel is smaller than that of the rough grinding wheel, and the abrasive grain density of the finish grinding wheel is larger than that of the rough grinding wheel.

When the grinding tool comprises a rough grinding wheel and a finish grinding wheel, the silicon rod positioned by the silicon rod positioning mechanism can be subjected to rough grinding operation and finish grinding operation by using the grinding tool. Therefore, at least one of the rough grinding wheel and the finish grinding wheel is provided with a telescopic driving mechanism. For example, when the finish grinding wheel is nested in the rough grinding wheel, the rough grinding wheel may be provided with a telescopic driving mechanism, when performing rough grinding operation, the telescopic driving mechanism is used to drive the rough grinding wheel to extend out and protrude out of the finish grinding wheel, so as to perform rough grinding operation on a silicon rod by using the protruding rough grinding wheel, and when performing finish grinding operation, the telescopic driving mechanism is used to drive the rough grinding wheel to contract and sink into the finish grinding wheel, so as to perform finish grinding operation on a silicon rod by using the finish grinding wheel. Or when the accurate grinding wheel is nested in the rough grinding wheel, the accurate grinding wheel can be provided with a telescopic driving mechanism, when the rough grinding operation is carried out, the telescopic driving mechanism is utilized to drive the accurate grinding wheel to contract and recess in the rough grinding wheel so as to utilize the rough grinding wheel to carry out the rough grinding operation on the silicon rod, and when the accurate grinding operation is carried out, the telescopic driving mechanism is utilized to drive the accurate grinding wheel to extend out and protrude out of the rough grinding wheel so as to utilize the protruding accurate grinding wheel to carry out the accurate grinding operation on the silicon rod.

The following description will be directed to a specific embodiment of the silicon rod polishing operation.

Taking rough grinding of the side cut surface of the silicon rod after the cutting is finished as an example: firstly, the silicon rod is switched to a grinding area by using the silicon rod switching device, the silicon rod is positioned and adjusted by the silicon rod positioning mechanism, and the grinding frame 31 moves towards the silicon rod relative to the base 1 along a forward and backward direction (i.e. an X-axis direction shown in fig. 2) through the sliding mechanism, so that the silicon rod is positioned between two grinding tools 33 of the pair of grinding tools 33, i.e. a first pair of side sections in the silicon rod corresponds to the pair of grinding tools 33 in the grinding device 3; feeding the grinding tool 33 relative to the grinding frame 31 by a second sliding unit according to the feeding amount along the feeding direction (i.e. the Y-axis direction shown in FIG. 2), rotating the rough grinding wheel in the grinding tool 33 and driving the grinding tool 33 to move up and down by the first sliding unit so as to roughly grind the first pair of side cut surfaces in the silicon rod; the silicon rod is driven by the rotary bearing platform 431 in the silicon rod positioning mechanism 43 to rotate forward (or reversely) by 90 degrees, so that the second pair of side tangent planes in the silicon rod corresponds to the pair of grinding tools 33 in the grinding device 3, and the rough grinding wheel in the grinding tool 33 is rotated and the grinding tool 33 is driven to move up and down through the first sliding unit so as to perform rough grinding on the second pair of side tangent planes in the silicon rod.

The rough grinding operation for any pair of side facets may, for example, include: providing a feeding amount, driving a rough grinding wheel in a pair of grinding wheels 33 to move from top to bottom to grind a pair of side cut surfaces of the silicon rod; the pair of rough grinding wheels are ground to the bottom of the silicon rod, penetrate through the silicon rod and then stay at the lower limit, the feeding amount is increased, and the pair of rough grinding wheels are driven to move from bottom to top to grind the silicon rod; the pair of rough grinding wheels are ground to the top of the silicon rod, penetrate through the silicon rod and then stay at the upper limit, the feeding amount is continuously increased, and the pair of rough grinding wheels are driven to move from top to bottom to grind the silicon rod; thus, after grinding, increasing the feeding amount, reversely grinding and increasing the feeding amount, and repeating for a plurality of times, the pair of side cut surfaces of the silicon rod can be ground to the preset size.

Taking the rough chamfering of the side cut surface of the silicon rod after the cutting is finished as an example: initially, when the silicon rod is transferred to the grinding section by the silicon rod transfer device 4, the side cut surface of the silicon rod corresponds to the pair of grinding tools 33 in the grinding device 3, and thus, the positioning adjustment of the silicon rod by the silicon rod positioning mechanism 43 may, for example, include driving the silicon rod to rotate forward (or backward) by 45 ° so that the first pair of connecting edge surfaces in the silicon rod corresponds to the pair of grinding tools 33 in the grinding device 3; moving the grinding frame 31 in a forward and backward direction (i.e. the X-axis direction as shown in fig. 2) towards the silicon rod relative to the base 1 by means of a sliding mechanism, so that the silicon rod is located between two grinding tools 33 of a pair of grinding tools 33, i.e. the first pair of side cut surfaces in the silicon rod corresponds to the pair of grinding tools 33 in the grinding device 3; feeding the grinding tool 33 relative to the grinding frame 31 by a second sliding unit according to the feeding amount along the feeding direction (i.e. the Y-axis direction shown in fig. 2), rotating the rough grinding wheel in the grinding tool 33 and driving the grinding tool 33 to move up and down by the first sliding unit to perform a first rough cutting on a first pair of connecting prism surfaces in the silicon rod; the silicon rod positioning mechanism 43 drives the silicon rod to rotate forwards by 5 degrees, the rough grinding wheel in the grinding tool 33 is rotated, and the grinding tool 33 is driven to move up and down through the first sliding unit so as to perform secondary rough cutting on the first pair of connecting edge surfaces in the silicon rod; the silicon rod positioning mechanism 43 drives the silicon rod to rotate forward by 80 degrees, so that the second pair of connecting edge surfaces in the silicon rod corresponds to the pair of grinding tools 33 in the grinding device 3, and the rough grinding wheel in the grinding tool 33 is rotated and drives the grinding tool 33 to move up and down through the first sliding unit so as to perform primary rough cutting on the second pair of connecting edge surfaces in the silicon rod; the silicon rod positioning mechanism 43 drives the silicon rod to rotate forwards by 5 degrees, the rough grinding wheel in the grinding tool 33 is rotated, and the grinding tool 33 is driven to move up and down through the first sliding unit so as to perform secondary rough cutting on a second pair of connecting edge surfaces in the silicon rod; the silicon rod positioning mechanism 43 drives the silicon rod to rotate forwards by 5 degrees, the rough grinding wheel in the grinding tool 33 is rotated, and the grinding tool 33 is driven to move up and down through the first sliding unit so as to perform the third rough cutting on the second pair of connecting edge surfaces in the silicon rod; the silicon rod positioning mechanism 43 drives the silicon rod to rotate forward by 80 degrees, the rough grinding wheel in the grinding tool 33 is rotated, and the grinding tool 33 is driven to move up and down through the first sliding unit so as to perform the third rough cutting on the first pair of connecting edge surfaces in the silicon rod.

It should be noted that, in the above-mentioned rough chamfering operation of the connecting edge surface, the silicon rod positioning mechanism 43 drives the silicon rod to rotate by a corresponding angle, for example: the silicon rod positioning mechanism 43 drives the silicon rod to rotate forward by 5 °, which is not the only implementation manner, but in other optional embodiments, the adjustment angle may be adapted to, for example, 3 ° to 7 °, including 3 °, 4 °, 5 °, 6 °, 7 °, or other angles, and accordingly, the adjustment angle is adapted when the silicon rod positioning mechanism 43 drives the silicon rod to rotate forward by 80 °.

Taking the fine grinding of the side cut surface of the silicon rod after the cutting and squaring as an example: firstly, the silicon rod is switched to a grinding area by using the silicon rod switching device, the silicon rod is positioned and adjusted by the silicon rod positioning mechanism, and the grinding frame 31 moves towards the silicon rod relative to the base 1 along a forward and backward direction (i.e. an X-axis direction shown in fig. 2) through the sliding mechanism, so that the silicon rod is positioned between two grinding tools 33 of the pair of grinding tools 33, i.e. a first pair of side sections in the silicon rod corresponds to the pair of grinding tools 33 in the grinding device 3; feeding the grinding wheel 33 relative to the grinding frame 31 by the second sliding unit according to the feeding amount in the feeding direction (i.e. the Y-axis direction shown in fig. 2), rotating the lapping wheel 333 in the grinding wheel 33 and driving the grinding wheel 33 to move up and down by the first sliding unit to lap the first pair of side cut surfaces in the silicon rod; the silicon rod is driven by the rotary bearing platform 431 in the silicon rod positioning mechanism 43 to rotate forwards (or reversely) for 90 degrees, so that the second pair of side tangent planes in the silicon rod corresponds to the pair of grinding tools 33 in the grinding device 3, and the fine grinding wheel in the grinding tool 33 is rotated and driven to move up and down through the first sliding unit so as to perform fine grinding on the second pair of side tangent planes in the silicon rod.

Wherein the finish grinding operation for any pair of side cut surfaces may for example comprise: providing a feeding amount, driving a fine grinding wheel in a pair of grinding tools 33 to move from top to bottom to grind a pair of side cut surfaces of the silicon rod; the pair of fine grinding wheels are ground to the bottom of the silicon rod, penetrate through the silicon rod and then stay at the lower limit, the feeding amount is increased, and the pair of fine grinding wheels are driven to move from bottom to top to grind the silicon rod; the pair of fine grinding wheels are ground to the top of the silicon rod, penetrate through the silicon rod and then stay at the upper limit, the feeding amount is continuously increased, and the pair of fine grinding wheels are driven to move from top to bottom to grind the silicon rod; thus, after grinding, increasing the feeding amount, reversely grinding and increasing the feeding amount, and repeating for a plurality of times, the pair of side cut surfaces of the silicon rod can be ground to the preset size.

Taking the precise chamfering of the side cutting surface of the silicon rod after the cutting is finished as an example: initially, when the silicon rod is transferred to the grinding section by the silicon rod transfer device 4, the side cut surface of the silicon rod corresponds to the pair of grinding tools 33 in the grinding device 3, and thus, the positioning adjustment of the silicon rod by the silicon rod positioning mechanism 43 may, for example, include driving the silicon rod to rotate forward (or backward) by 45 ° so that the first pair of connecting edge surfaces in the silicon rod corresponds to the pair of grinding tools 33 in the grinding device 3; moving the grinding frame 31 in a forward and backward direction (i.e. the X-axis direction as shown in fig. 2) towards the silicon rod relative to the base 1 by means of a sliding mechanism, so that the silicon rod is located between two grinding tools 33 of a pair of grinding tools 33, i.e. the first pair of side cut surfaces in the silicon rod corresponds to the pair of grinding tools 33 in the grinding device 3; feeding the grinding tool 33 relative to the grinding frame 31 in the feeding direction (i.e., the Y-axis direction shown in fig. 2) by the second sliding unit according to the feeding amount, rotating the finishing grindstone in the grinding tool 33 and driving the grinding tool 33 to move up and down by the first sliding unit to perform a first finishing cut on a first pair of connecting prism surfaces in the silicon rod; the silicon rod positioning mechanism 43 drives the silicon rod to rotate forwards for 5 degrees, the fine grinding wheel in the grinding tool 33 is rotated, and the grinding tool 33 is driven to move up and down through the first sliding unit so as to perform secondary fine cutting on the first pair of connecting edge surfaces in the silicon rod; the silicon rod positioning mechanism 43 drives the silicon rod to rotate forwards by 80 degrees, so that the second pair of connecting edge surfaces in the silicon rod corresponds to the pair of grinding tools 33 in the grinding device 3, and the fine grinding wheel in the grinding tool 33 is rotated and the grinding tool 33 is driven to move up and down through the first sliding unit so as to perform primary fine cutting on the second pair of connecting edge surfaces in the silicon rod; the silicon rod positioning mechanism 43 drives the silicon rod to rotate forwards by 5 degrees, the fine grinding wheel in the grinding tool 33 is rotated, and the grinding tool 33 is driven to move up and down through the first sliding unit so as to perform secondary fine cutting on a second pair of connecting edge surfaces in the silicon rod; the silicon rod positioning mechanism 43 drives the silicon rod to rotate forwards by 5 degrees, the fine grinding wheel in the grinding tool 33 is rotated, and the grinding tool 33 is driven to move up and down through the first sliding unit so as to perform third fine cutting on the second pair of connecting edge surfaces in the silicon rod; the silicon rod positioning mechanism 43 drives the silicon rod to rotate forward by 80 degrees, the fine grinding wheel in the grinding tool 33 is rotated, and the grinding tool 33 is driven to move up and down through the first sliding unit so as to perform third fine cutting on the first pair of connecting edge surfaces in the silicon rod.

For example, in the description of the polishing operation as the polishing device, the chamfering operation of the polycrystalline silicon rod is performed after the polishing operation of the silicon rod is performed, but the present invention is not limited thereto, and in other embodiments, the chamfering operation of the silicon rod is performed after the chamfering operation of the silicon rod is performed, and the present invention is also applicable and is within the scope of the present invention.

In some embodiments, the grinding device comprises a grinding tool and a chamfering tool, wherein the grinding tool comprises a main shaft and at least one grinding wheel assembly, the grinding wheel assembly is arranged at the working end of the main shaft, and the chamfering tool is arranged on the grinding support and is used for chamfering or rounding the edge of the cut silicon rod.

In the present embodiment, as shown in fig. 2, the grinding device 3 mainly includes a grinding frame 31, at least one pair of grinding tools 33, and a chamfering grinding tool 33, wherein the at least one pair of grinding tools 33 is oppositely disposed on the grinding frame 31 for grinding the cut silicon rod at the grinding location, and the chamfering grinding tool 33 is disposed on the grinding frame 31 for chamfering or rounding the edge of the cut silicon rod.

The chamfering tool may comprise a chamfering wheel.

In some embodiments, the chamfer grind stone 33 may move with the grind stone 33, for example, one or a combination of one or more of moving back and forth along the X-axis, moving along the Y-axis, and moving up and down along the vertical direction.

In some embodiments, the chamfering grinder 33 may be independently provided with a corresponding chamfering grinder advancing and retreating mechanism for driving the chamfering grinder to advance and retreat along the X axis and/or a chamfering grinder translating mechanism for driving the chamfering grinder to move along the Y axis.

In practical application, the chamfering grinding tool can be driven to move along the direction of the plumb line so as to enable the chamfering grinding tool to contact with the silicon rod edges, the cut silicon rod is driven to rotate along the axial lead of the cut silicon rod so as to enable the silicon rod edges to contact with the chamfering grinding tool to achieve rounding, or the cut silicon rod is driven to rotate along the axial lead of the cut silicon rod by a preset angle so as to enable the silicon rod edges to contact with the chamfering grinding tool or drive the chamfering grinding tool to advance and retreat so as to contact with the silicon rod edges to achieve chamfering.

In addition, the axis of the chamfering grinding wheel and the axis of the cut silicon rod have an offset. As shown in fig. 2, the axis of the chamfering wheel serving as the chamfering grinding stone 33 is offset from the axis of the cut silicon rod (i.e., the center of the silicon rod chuck in the silicon rod transfer device), so that the chord part of the chamfering wheel is brought into contact with the cut silicon rod, thereby obtaining a large contact area as much as possible and improving the working efficiency of chamfering or rounding.

For example, in the description of the polishing operation as the polishing device, the surface grinding operation of the silicon rod is performed first and then the chamfering operation of the silicon rod is performed, but the invention is not limited thereto, and in other embodiments, the surface grinding operation of the silicon rod is performed first and then the chamfering operation of the silicon rod is performed, and the invention is still within the scope of the present application.

Subsequently, after the silicon rod 200 is ground by the grinding device 3, the silicon rod 200 is switched from the grinding location to the waiting location by the silicon rod switching device 4, and the processed silicon rod is unloaded from the waiting location of the silicon rod processing platform by the silicon rod loading and unloading device. Wherein the content of the first and second substances,

of course, before unloading the silicon rod 200, if necessary, in the waiting section, the silicon rod 200 after the machining operation may be inspected by the inspection device, for example, by using a flatness inspection apparatus to inspect the silicon rod for plane flatness. By using the flatness detector, on one hand, whether the silicon rod meets the product requirements after each processing operation can be detected by detecting the plane flatness of the silicon rod 200 so as to determine the effect of each processing operation; on the other hand, the wear condition of the processing parts in each processing device can be indirectly obtained through detecting the plane flatness of the silicon rod 200, so that the calibration or correction, even the maintenance or replacement can be conveniently carried out in real time.

Furthermore, in the cutting and grinding all-in-one machine, in an optional embodiment, a silicon rod cleaning device can be further included. The silicon rod cleaning device can be arranged on the base and used for cleaning the silicon rod. In the silicon rod cleaning apparatus, generally, after the silicon rod is subjected to the above-described processing operation, cutting chips generated during the operation adhere to the surface of the silicon rod, and therefore, it is necessary to clean the silicon rod as necessary. Generally, the silicon rod cleaning device comprises a cleaning brush head and a cleaning solution spraying device matched with the cleaning brush head, wherein during cleaning, the cleaning solution spraying device sprays cleaning solution towards the silicon rod, and meanwhile, the cleaning brush head is driven by a motor to act on the silicon rod to complete cleaning operation. In practice, the cleaning liquid may be pure water, for example, and the cleaning brush head may be a rotary brush head, for example.

In addition, in the cutting and grinding integrated machine of the present application, it is particularly noted that, if the cutting and grinding integrated machine increases or decreases the corresponding processing operation device, the number and the positional relationship of the functional location on the silicon rod processing platform and the silicon rod positioning mechanism on the conversion main body need to be adjusted accordingly.

In certain embodiments, provided that the silicon rod processing apparatus comprises a cutting zone, the silicon rod transfer device is also reduced by one silicon rod positioning means accordingly. Further, preferably, the angles set between two of the three silicon rod positioning mechanisms are also consistent with the angle distribution between two of the three functional areas. Thus, when a certain silicon rod positioning mechanism corresponds to a certain functional zone, other two silicon rod positioning mechanisms also respectively correspond to other two functional zone positions. Therefore, in the process of flow operation, at any moment, when one silicon rod is positioned on each silicon rod positioning mechanism and the silicon rod positioning mechanisms correspond to the function areas, the silicon rods are positioned at the corresponding function areas to execute corresponding processing operation. In an alternative embodiment, the three functional regions on the silicon rod processing platform are arranged at 120 ° with respect to one another, so that correspondingly the three silicon rod positioning means on the disk-shaped or ring-shaped changeover body are also arranged at 120 ° with respect to one another.

In addition, the cutting and grinding integrated machine of the present application, it is particularly pointed out that if the cutting and grinding integrated machine is additionally provided with a corresponding processing operation device, the number and the position relationship of the functional location on the silicon rod processing platform and the silicon rod positioning mechanism on the conversion main body need to be correspondingly adjusted. Supposing that a processing operation device is additionally arranged on the silicon rod processing equipment, a functional region is correspondingly additionally arranged on the silicon rod processing platform, and a silicon rod positioning mechanism is correspondingly additionally arranged on the silicon rod conversion device. Further, preferably, the angles set between every two of the five silicon rod positioning mechanisms are consistent with the angle distribution between every two of the five functional areas. Thus, when one silicon rod positioning mechanism corresponds to one functional zone, the other four silicon rod positioning mechanisms also correspond to the other four functional zones respectively. Therefore, in the running water operation, at any moment, when one silicon rod is positioned on each silicon rod positioning mechanism and the silicon rod positioning mechanisms correspond to the function areas, the silicon rods are positioned at the corresponding function areas to execute corresponding processing operation. In an alternative embodiment, the five functional regions on the silicon rod processing platform are arranged at 72 ° with respect to one another, so that correspondingly, the five silicon rod positioning means on the disk-shaped or ring-shaped conversion body are also arranged at 72 ° with respect to one another.

The application discloses silicon rod surely grinds all-in-one has assembleed cutting device and grinder, usable silicon rod conversion equipment can shift the silicon rod between each processingequipment orderly and seamlessly, utilize cutting device to carry out the evolution cutting to the silicon rod so that form the silicon rod that the cross-section is similar to the rectangle and utilize grinder to grind the silicon rod after the evolution cutting, utilize first carrier and the second carrier among the silicon rod device unloader to bear the weight of the silicon rod of different forms respectively and make the upset through the drive carrier with the silicon rod that bears at present place the state between the difference and change, thereby can realize the loading operation of the silicon rod of treating processing and the uninstallation operation of the silicon rod of processing simultaneously, thereby accomplish the integration operation of the evolution of silicon rod and grinding multiple processes, improve the quality of production efficiency and product processing operation.

The application further discloses a silicon rod processing method, which is applied to a silicon rod processing device, wherein the silicon rod processing device comprises a cutting device, a silicon rod conversion device and a silicon rod loading and unloading device, the silicon rod loading and unloading device comprises a base and a supporting body which is arranged on the base in a turnover mode through a turnover mechanism, and the supporting body comprises a bearing seat, a first bearing body, a second bearing body and a bottom supporting piece.

The silicon rod processing method applied to the silicon rod processing equipment can comprise the following steps:

placing a silicon rod to be processed on a first bearing piece of a bearing body in a silicon rod bearing device in a first placing state; the silicon rod to be processed is a first form silicon rod, which in certain embodiments is a silicon rod having a circular cross-section.

The supporting body is driven to overturn relative to the base through the overturning mechanism so that the supporting body and the silicon rod to be processed on the supporting body are converted from a first placing state to a second placing state, and the silicon rod to be processed is supported by the bottom supporting piece;

loading the silicon rod to be processed in the second placement state onto a silicon rod conversion device so as to enable silicon rod processing equipment to process the silicon rod to be processed to form a processed silicon rod; the processed silicon rods are second shape silicon rods, which in certain embodiments are quasi-rectangular in cross-section.

And unloading the processed silicon rods from the silicon rod conversion device to the bottom supporting pieces of the silicon rod loading and unloading device in a second placement state.

And driving the supporting body to overturn relative to the base through the overturning mechanism so as to enable the processed silicon rod to be converted from the second placement state into the first placement state, and bearing the processed silicon rod by the second bearing piece of the supporting body in the silicon rod bearing device.

In some embodiments, the silicon rod processing apparatus is a silicon rod squarer, and includes at least one cutting device, by which the silicon rod can be squared and cut, so that the first-form silicon rod with a circular original cross section forms a second-form silicon rod with a rectangular-like cross section after being squared and cut.

In the silicon rod squarer, comprising: the silicon rod loading and unloading device comprises a base, a cutting device, a silicon rod conversion device and a silicon rod loading and unloading device.

The base has a silicon rod processing platform that includes a cutting location, wherein the cutting location can include one or more locations. For example, if the silicon rod processing platform comprises a cutting zone, the silicon rod squarer comprises a cutting device corresponding to the cutting zone. For another example, if the silicon rod processing platform includes a first cutting area and a second cutting area, the silicon rod squarer includes a first cutting device corresponding to the first cutting area and a second cutting device corresponding to the second cutting area, or the silicon rod squarer includes a cutting device having a first cutting unit corresponding to the first cutting area and a second cutting unit corresponding to the second cutting area. In the following description, we assume: in the silicon rod squarer, the silicon rod processing platform comprises a first cutting area and a second cutting area, the silicon rod squarer comprises a cutting device, and the cutting device comprises a first cutting unit corresponding to the first cutting area and a second cutting unit corresponding to the second cutting area.

The silicon rod conversion device is arranged on the silicon rod processing platform and used for bearing a silicon rod and converting the position of the silicon rod on the silicon rod processing platform. The silicon rod transfer device may include a transfer body, a plurality of silicon rod positioning mechanisms, and a transfer drive mechanism. As described above, in the silicon rod squaring machine, the silicon rod processing platform may include a waiting zone, a first cutting zone and a second cutting zone, the first cutting zone and the second cutting zone of the silicon rod processing platform are distributed at 120 ° between two adjacent cutting zones, and the rotation angle range of the silicon rod conversion device is ± 240 °. In the present embodiment, it is assumed that the sequence of the waiting region, the first cutting region, and the second cutting region is defined as forward direction.

The silicon rod loading and unloading device is arranged adjacent to the silicon rod processing platform and used for bearing the silicon rod to be cut or the cut silicon rod and turning over the silicon rod to be cut or the cut silicon rod to convert the borne silicon rod to be cut or the cut silicon rod between a first placing state and a second placing state, and loading of the silicon rod to be cut and unloading of the cut silicon rod are completed. The first placement state can be, for example, a horizontal placement state, in which the axis of the silicon rod is placed along the horizontal line or approximately placed along the horizontal line, and the second placement state can be, for example, a vertical placement state, in which the axis of the silicon rod is placed along the vertical direction or approximately placed along the vertical direction.

Therefore, the silicon rod processing method applied to the silicon rod squarer can comprise the following steps:

step S101, the silicon rod loading and unloading device loads the first silicon rod to the waiting location.

In step S101, the step of causing the silicon rod loading and unloading device to load the first silicon rod to the waiting location may specifically include: when the supporting body of the silicon rod loading and unloading device is at a first position, such as a horizontal position, a first silicon rod with a circular cross section is horizontally placed on a first supporting body of the supporting body in the silicon rod loading and unloading device; the supporting body is driven to overturn relative to the base through the overturning mechanism so that the supporting body and the first silicon rod on the supporting body are converted from a horizontal type to a vertical type, and at the moment, the bottom supporting piece of the supporting body can support the bottom end of the first silicon rod; and loading the first silicon rod which is vertically placed on the silicon rod positioning mechanism at the waiting position of the silicon rod processing platform.

In practical applications, the step of loading the vertically-placed first silicon rod onto the silicon rod positioning mechanism at the waiting position of the silicon rod processing platform means that the vertically-placed first silicon rod supported by the bottom supporting member of the supporting body is loaded onto the rotary carrying table of the silicon rod positioning mechanism at the waiting position. For example, the bottom supporting part is driven to adjust to a first adjusting position, and a first silicon rod supported by the bottom supporting part at the first adjusting position is positioned above a rotary bearing table in a silicon rod positioning mechanism at a waiting position; and driving the bottom supporting piece to adjust to a second adjusting position, namely, descending the bottom supporting piece and the first silicon rod supported by the bottom supporting piece so that the first silicon rod is positioned on a rotary bearing table in the silicon rod positioning mechanism at the waiting position.

After the first silicon rod is loaded onto the silicon rod positioning mechanism at the waiting location, the first silicon rod can be correspondingly pretreated. The pretreatment can be used, for example, for the edge detection and centering of a first silicon rod located at the waiting location by means of a positioning detection device.

Step S103, rotating the silicon rod conversion device by a first preset angle to convert the first silicon rod from the waiting position to a first cutting position, and enabling a first cutting unit in the cutting device to perform first folding surface cutting on the first silicon rod at the first cutting position; at this stage, the silicon rod handling device loads a second silicon rod to the waiting location and pretreats the second silicon rod.

In step S103, since the waiting location and the first cutting location are 120 °, the first preset angle for rotating the silicon rod conversion device is 120 ° for forward rotation of the silicon rod conversion device. In this way, the first silicon rod at the first cutting location can be cut by the first cutting unit in the cutting device.

When a first cutting unit in the cutting device is used for cutting the first silicon rod at the first cutting area, the cutting support is driven to descend relative to the cutting frame, and the first cutting unit at one side of the cutting support performs first surface cutting on the first silicon rod at the first cutting area (the first cutting unit is provided with a first cutting wire net in a shape like a Chinese character '+' or 'gamma' shape).

As for loading the second silicon rod onto the silicon rod positioning mechanism at the waiting location by using the silicon rod loading and unloading device and performing the pretreatment on the second silicon rod, reference may be made to the description of the step S101 for the first silicon rod, which is not described herein again.

Step S105, rotating the silicon rod conversion device by a first preset angle to convert the first silicon rod from a first cutting position to a second cutting position and convert the second silicon rod from a waiting position to the first cutting position, and enabling a second cutting unit in the cutting device to perform second fold surface cutting on the first silicon rod in the second cutting position and enabling the first cutting unit to perform first fold surface cutting on the second silicon rod in the first cutting position; at this stage, the silicon rod handling device is caused to load a third silicon rod to a waiting location and to pretreat the second silicon rod. And the cross section of the first silicon rod after being cut by the second folded surface is rectangular.

In step S105, since the waiting location and the first cutting location are 120 °, the first preset angle for rotating the silicon rod transforming device is to rotate the silicon rod transforming device forward by 120 °, transform the first silicon rod from the first cutting location to the second cutting location, and transform the second silicon rod from the waiting location to the first cutting location. In this way, the first silicon rod in the second cutting location may be cut by the second cutting unit and the second silicon rod in the first cutting location may be cut by the first cutting unit in the cutting device.

When the cutting device cuts the second silicon rod on the first cutting area of the silicon rod processing platform and the second silicon rod on the first cutting area, the cutting support is driven to descend relative to the cutting frame, the first cutting unit and the second cutting unit on the left side and the right side of the cutting support simultaneously cut the second silicon rod on the corresponding first cutting area and the first silicon rod on the second cutting area, wherein the first cutting unit performs first plane cutting on the second silicon rod on the first cutting area (the first cutting unit is provided with a first cutting wire net in a shape of a plus or a reversed L), and the second cutting unit performs second plane cutting on the first silicon rod on the second cutting area (the second cutting unit 25 is provided with a second cutting wire net in a shape of a plus or a reversed L). Wherein, it should be noted that before the second folding surface cutting is carried out on the first silicon rod on the second cutting location by the second cutting unit, because of the problem of the aforementioned folding surface cutting, the silicon rod positioning mechanism in the silicon rod conversion device is still required to be utilized to drive the first silicon rod to rotate forward or reversely by 180 degrees so as to adjust the cutting surface. Therefore, after the first silicon rod positioned on the second cutting position is subjected to second plane-folding cutting by the second cutting unit, the first silicon rod with the rectangular-like cross section is formed.

As for loading the third silicon rod onto the silicon rod positioning mechanism at the waiting location by using the silicon rod loading and unloading device and preprocessing the third silicon rod, reference may be made to the description of the first silicon rod in step S101, which is not described herein again.

Step S107, rotating the silicon rod conversion device by a second preset angle to convert the first silicon rod from the second cutting area to the waiting area, convert the second silicon rod from the first cutting area to the second cutting area, and convert the third silicon rod from the waiting area to the first cutting area, and unloading the first silicon rod from the waiting area, loading the fourth silicon rod and preprocessing the fourth silicon rod by the silicon rod loading and unloading device; at this stage, the second cutting unit in the cutting device performs a second plane cutting on the second silicon rod at the second cutting location and the first cutting unit performs a first plane cutting on the third silicon rod at the first cutting location. And the cross section of the second silicon rod after being cut by the second folding surface is rectangular.

In step S107, since the waiting location, the first cutting location, and the second cutting location of the silicon rod processing platform are sequentially 120 ° apart from each other, the second preset angle for rotating the silicon rod conversion device is that the silicon rod conversion device is rotated forward by 120 ° or reversely by 240 °. The silicon rod conversion device is reversely rotated by 240 degrees, so that the silicon rod conversion device can return to an initial position, and a cable wound in the forward rotation process can be released.

And reversely rotating the silicon rod conversion device by 240 degrees, converting the first silicon rod from the second cutting area to the waiting area, converting the second silicon rod from the first cutting area to the second cutting area, and converting the third silicon rod from the waiting area to the first cutting area.

Therefore, the silicon rod loading and unloading device can unload the first silicon rod on the waiting position so as to transfer the first silicon rod out of the silicon rod processing platform, and load the fourth silicon rod to be cut onto the silicon rod positioning mechanism at the waiting position of the silicon rod processing platform.

In step S107, the step of causing the silicon rod loading and unloading device to unload the first silicon rod at the waiting position may specifically include: transferring the first silicon rod with the rectangular-like section to a bottom supporting piece of a supporting body in the silicon rod bearing device in a vertical placement state; the supporting body is driven to overturn relative to the base through the overturning mechanism, so that the supporting body and a first silicon rod on the supporting body are converted into a horizontal type from a vertical type, and a second supporting body of the supporting body in the silicon rod supporting device supports the first silicon rod, so that the first silicon rod is unloaded.

In practical application, the step of transferring the first silicon rod with the rectangular-like cross section to the bottom support member of the support body in the silicon rod carrying device in the vertical placement state refers to the step of transferring the first silicon rod on the rotary support table of the silicon rod positioning mechanism at the waiting position to the bottom support member of the support body in the silicon rod carrying device.

For example, the silicon rod handling device is moved to a waiting location, wherein the carrier of the silicon rod handling device is in a second position, for example, a vertical position, and the first carrier of the carrier is swung outward to expose the second carrier, and the bottom support member of the carrier is in a second adjustment position and is located below the rotary carrier; the supporting body is directly turned over through the turning mechanism, so that the supporting body is turned over relative to the base through the turning mechanism, so that the bottom supporting member supports the bottom end of the first silicon rod in the turning process and the first silicon rod leans against the second supporting member in the supporting body, or the bottom supporting member is driven to move from the second adjusting position to the first adjusting position (the height of the first adjusting position is higher than that of the second adjusting position in the vertical direction and the height of the table top of the rotary bearing table in the silicon rod positioning mechanism at the waiting position) until the bottom supporting member supports the first silicon rod on the rotary bearing table in an abutting mode (in some implementation modes, the first silicon rod on the rotary bearing table can also be ejected and lifted to be separated from the rotary bearing table).

As for loading the fourth silicon rod onto the silicon rod positioning mechanism at the waiting location by using the silicon rod loading and unloading device and preprocessing the fourth silicon rod, reference may be made to the description of the first silicon rod in step S101, which is not described herein again.

Meanwhile, the third silicon rod on the first cutting area and the second silicon rod on the second cutting area of the silicon rod processing platform can be cut by utilizing the cutting device.

When the cutting device is used for cutting a third silicon rod on a first cutting area and a second silicon rod on a second cutting area of the silicon rod processing platform, the cutting support is driven to descend relative to the cutting frame, and a first cutting unit and a second cutting unit on the left side and the right side of the cutting support simultaneously cut the third silicon rod on the corresponding first cutting area and the second silicon rod on the corresponding second cutting area, wherein the first cutting unit performs first surface cutting on the third silicon rod on the first cutting area (the first cutting unit 23 is provided with a first cutting wire mesh in a shape of a plus character or a reversed character), and the second cutting unit performs second surface cutting on the second silicon rod on the second cutting area (the second cutting unit is provided with a second cutting wire mesh in a shape of a plus character or a reversed character). Wherein, it should be noted that before the second cutting unit is used for carrying out the second folding surface cutting on the second silicon rod at the second cutting position, because of the problem of the aforementioned folding surface cutting, the silicon rod positioning mechanism in the silicon rod conversion device is also used for driving the second silicon rod to rotate forward or reversely by 180 degrees so as to adjust the cutting surface. Therefore, after the second silicon rod positioned on the second cutting area is subjected to second plane-folding cutting by the second cutting unit, the silicon rod with the rectangular-like cross section is formed.

According to the silicon rod cutting method, the silicon rods can be transferred between the processing devices in an orderly and seamless manner by the silicon rod conversion device, the silicon rods can be subjected to squaring and cutting operation by the cutting device so that the silicon rods with circular original sections can form the silicon rods with rectangular-like sections after squaring and cutting, the silicon rods with different shapes can be respectively borne by the first bearing parts and the second bearing parts in the silicon rod device unloading device, and the current borne silicon rods can be converted between different placement states by driving the bearing parts to turn over, so that the loading operation of the silicon rods to be processed and the unloading operation of the processed silicon rods can be simultaneously realized, the integrated operation of the squaring of the silicon rods is finished, and the production efficiency and the quality of product processing operation are improved.

In some embodiments, the silicon rod processing apparatus is a silicon rod cutting and grinding integrated machine, and includes at least one cutting device and at least one silicon rod grinding device, the silicon rod can be cut and processed by the at least one cutting device, so that the silicon rod with the original circular cross section can be cut and processed by the cutting and processing to form a silicon rod with a quasi-rectangular cross section, and the silicon rod grinding device can be used for grinding, such as surface grinding, rounding/chamfering, etc., on the cut and processed silicon rod.

In the silicon rod cutting and grinding all-in-one machine, include: the silicon rod cutting device comprises a base, a silicon rod loading and unloading device, a cutting device, a silicon rod grinding device and a silicon rod conversion device.

The base has a silicon rod processing platform that includes a cutting zone and a grinding zone, wherein the cutting zone can include one or more zones and the grinding zone can include one or more zones.

For example, if the silicon rod processing platform comprises a cutting location, the silicon rod cutting and grinding all-in-one machine comprises a cutting device corresponding to the cutting location. For another example, if the silicon rod processing platform includes a first cutting area and a second cutting area, the silicon rod cutting and grinding integrated machine includes a first cutting device corresponding to the first cutting area and a second cutting device corresponding to the second cutting area, or the silicon rod starting machine includes a cutting device having a first cutting unit corresponding to the first cutting area and a second cutting unit corresponding to the second cutting area. In the following description, we assume: in the silicon rod cutting and grinding all-in-one machine, the silicon rod processing platform comprises a first cutting area and a second cutting area, the silicon rod cutting and grinding all-in-one machine comprises a cutting device, and the cutting device comprises a first cutting unit corresponding to the first cutting area and a second cutting unit corresponding to the second cutting area.

For example, if the silicon rod processing platform comprises a grinding zone, the silicon rod cutting and grinding integrated machine comprises a grinding device corresponding to the grinding zone. For another example, the silicon rod processing platform includes a first grinding region and a second grinding region, and the silicon rod cutting and grinding integrated machine includes a first grinding device corresponding to the first grinding region and a second grinding device corresponding to the second grinding region, or the silicon rod starting-up includes a grinding device, and the grinding device includes a first grinding unit corresponding to the first grinding region and a second grinding unit corresponding to the second grinding region. In the following description, we assume: in the silicon rod cutting and grinding all-in-one machine, the silicon rod processing platform comprises a first grinding area and a second grinding area, the silicon rod cutting and grinding all-in-one machine comprises a grinding device, and the grinding device comprises a first grinding unit corresponding to the first grinding area and a second grinding unit corresponding to the second grinding area.

The silicon rod conversion device is arranged on the silicon rod processing platform and used for bearing a silicon rod and converting the position of the silicon rod on the silicon rod processing platform. The silicon rod transfer device may comprise a transfer body, a plurality of silicon rod positioning mechanisms, and a transfer drive mechanism. As mentioned above, in some embodiments, such as the embodiment shown in fig. 1, the silicon rod processing platform may comprise four functional regions, such as a waiting region, a first cutting region, a second cutting region and a milling region, wherein the four functional regions are distributed at 90 ° between two of the four functional regions, i.e. the waiting region is 90 ° different from the first cutting region, the first cutting region is 90 ° different from the second cutting region, the second cutting region is 90 ° different from the milling region, and the milling region is 90 ° different from the waiting region. Correspondingly, four silicon rod positioning mechanisms can be arranged on the conversion main body, the four silicon rod positioning mechanisms are distributed at 90 degrees between every two silicon rod positioning mechanisms, and each silicon rod positioning mechanism can position at least one silicon rod. Therefore, the rotation angle range of the silicon rod conversion device is +/-270 degrees. In the present embodiment, it is assumed that the sequence of the waiting zone, the first cutting zone, the second cutting zone, and the polishing zone is defined as the forward direction.

The silicon rod loading and unloading device is arranged adjacent to the silicon rod processing platform and used for bearing the silicon rod to be cut or the cut silicon rod and turning over the silicon rod to be cut or the cut silicon rod to convert the borne silicon rod to be cut or the cut silicon rod between a first placing state and a second placing state, and loading of the silicon rod to be cut and unloading of the cut silicon rod are completed. The first placement state can be, for example, a horizontal placement state, in which the axis of the silicon rod is placed along the horizontal line or approximately placed along the horizontal line, and the second placement state can be, for example, a vertical placement state, in which the axis of the silicon rod is placed along the vertical direction or approximately placed along the vertical direction.

Therefore, the silicon rod processing method applied to the silicon rod cutting and grinding integrated machine can comprise the following steps:

step S202, the silicon rod loading and unloading device loads the first silicon rod to the waiting location.

In step S202, the step of causing the silicon rod loading and unloading device to load the first silicon rod to the waiting location may specifically include: when the supporting body of the silicon rod loading and unloading device is at a first position, such as a horizontal position, a first silicon rod with a circular cross section is horizontally placed on a first supporting body of the supporting body in the silicon rod loading and unloading device; the supporting body is driven to overturn relative to the base through the overturning mechanism so that the supporting body and the first silicon rod on the supporting body are converted from a horizontal type to a vertical type, and at the moment, the bottom supporting piece of the supporting body can support the bottom end of the first silicon rod; and loading the first silicon rod which is vertically placed on the silicon rod positioning mechanism at the waiting position of the silicon rod processing platform.

In practical applications, the step of loading the vertically-placed first silicon rod onto the silicon rod positioning mechanism at the waiting position of the silicon rod processing platform means that the vertically-placed first silicon rod supported by the bottom supporting member of the supporting body is loaded onto the rotary carrying table of the silicon rod positioning mechanism at the waiting position. For example, the bottom supporting part is driven to adjust to a first adjusting position, and a first silicon rod supported by the bottom supporting part at the first adjusting position is positioned above a rotary bearing table in a silicon rod positioning mechanism at a waiting position; and driving the bottom supporting piece to adjust to a second adjusting position, namely, descending the bottom supporting piece and the first silicon rod supported by the bottom supporting piece so that the first silicon rod is positioned on a rotary bearing table in the silicon rod positioning mechanism at the waiting position.

After the first silicon rod is loaded onto the silicon rod positioning mechanism at the waiting location, the first silicon rod can be correspondingly pretreated. The pretreatment can be used, for example, for the edge detection and centering of a first silicon rod located at the waiting location by means of a positioning detection device.

Step S204, rotating the silicon rod conversion device by a first preset angle to convert the first silicon rod from the waiting position to a first cutting position, and enabling a first cutting unit in the cutting device to perform first folding cutting on the first silicon rod at the first cutting position; at this stage, the silicon rod handling device loads a second silicon rod to the waiting location and pretreats the second silicon rod.

In step S204, since the waiting location and the first cutting location are 90 °, the first preset angle for rotating the silicon rod conversion device is 90 ° in the forward direction. In this way, the first silicon rod at the first cutting location can be cut by the first cutting unit in the cutting device.

When a first cutting unit in the cutting device is used for cutting the first silicon rod at the first cutting position, the cutting support is driven to descend relative to the cutting frame, and the first cutting unit at one side of the cutting support performs first plane cutting on the first silicon rod at the first cutting position (the first cutting unit is provided with a first cutting wire net in a shape like a plus or a reversed L).

As for loading the second silicon rod onto the silicon rod positioning mechanism at the waiting location by using the silicon rod loading and unloading device and performing the pretreatment on the second silicon rod, reference may be made to the description of the first silicon rod in step S202, which is not repeated herein.

Step S206, rotating the silicon rod conversion device by a first preset angle to convert the first silicon rod from the first cutting area to the second cutting area and convert the second silicon rod from the waiting area to the first cutting area, and enabling the second cutting unit in the cutting device to perform second fold surface cutting on the first silicon rod in the second cutting area and the first cutting unit to perform first fold surface cutting on the second silicon rod in the first cutting area; at this stage, the silicon rod handling device is caused to load a third silicon rod to a waiting location and to pretreat the third silicon rod. And the cross section of the first silicon rod after being cut by the second folded surface is rectangular.

In step S206, since the waiting location and the first cutting location are 90 °, the first preset angle for rotating the silicon rod transforming device is to rotate the silicon rod transforming device forward by 90 °, transform the first silicon rod from the first cutting location to the second cutting location, and transform the second silicon rod from the waiting location to the first cutting location. In this way, the first silicon rod in the second cutting location may be cut by the second cutting unit and the second silicon rod in the first cutting location may be cut by the first cutting unit in the cutting device.

When the cutting device cuts the second silicon rod on the first cutting area of the silicon rod processing platform and the second silicon rod on the first cutting area, the cutting support is driven to descend relative to the cutting frame, the first cutting unit and the second cutting unit on the left side and the right side of the cutting support simultaneously cut the second silicon rod on the corresponding first cutting area and the first silicon rod on the second cutting area, wherein the first cutting unit performs first plane cutting on the second silicon rod on the first cutting area (the first cutting unit is provided with a first cutting wire net in a shape of a plus or a reversed L), and the second cutting unit performs second plane cutting on the first silicon rod on the second cutting area (the second cutting unit 25 is provided with a second cutting wire net in a shape of a plus or a reversed L). Wherein, it should be noted that before the second folding surface cutting is carried out on the first silicon rod on the second cutting location by the second cutting unit, because of the problem of the aforementioned folding surface cutting, the silicon rod positioning mechanism in the silicon rod conversion device is still required to be utilized to drive the first silicon rod to rotate forward or reversely by 180 degrees so as to adjust the cutting surface. Therefore, after the first silicon rod positioned on the second cutting position is subjected to second plane-folding cutting by the second cutting unit, the first silicon rod with the rectangular-like cross section is formed.

As for loading the third silicon rod onto the silicon rod positioning mechanism at the waiting location by using the silicon rod loading and unloading device and preprocessing the third silicon rod, reference may be made to the description of the first silicon rod in step S202, which is not repeated herein.

Step S208, rotating the silicon rod conversion device by a first preset angle to convert the first silicon rod from the second cutting region to the grinding region, convert the second silicon rod from the first cutting region to the second cutting region, convert the third silicon rod from the waiting region to the first cutting region, and enable the grinding device to grind the first silicon rod on the grinding region (for example, grinding surface, rounding/chamfering); at this stage, the second cutting unit in the cutting device performs second facet cutting on the second silicon rod at the second cutting location and the first cutting unit performs first facet cutting on the third silicon rod at the first cutting location, and at the same time, the silicon rod handling device loads the fourth silicon rod to the waiting location and pretreats the fourth silicon rod. And the cross section of the second silicon rod after being cut by the second folding surface is rectangular.

In step S208, since the waiting location, the first cutting location, the second cutting location, and the grinding location of the silicon rod processing platform are sequentially 90 ° different from each other, the first preset angle for rotating the silicon rod conversion device is to rotate the silicon rod conversion device forward by 90 °, convert the first silicon rod from the second cutting location to the grinding location, convert the second silicon rod from the first cutting location to the second cutting location, and convert the third silicon rod from the waiting location to the first cutting location.

Therefore, the grinding device can be used for grinding the first silicon rod on the grinding area of the silicon rod processing platform. For a specific manner of using the grinding device to grind the first silicon rod on the grinding region of the silicon rod processing platform, reference is made to the foregoing description, and further description is omitted here.

Meanwhile, the cutting device can be used for cutting the third silicon rod on the first cutting area and the second silicon rod on the second cutting area of the silicon rod processing platform. Regarding the specific manner of cutting the third silicon rod on the first cutting region and the second silicon rod on the second cutting region of the silicon rod processing platform by using the cutting device, reference may be made to the description of cutting the first silicon rod and the second silicon rod in step S206, and details are not repeated here.

As for the specific manner of loading the fourth silicon rod to the waiting location and pre-treating the fourth silicon rod by the silicon rod loading and unloading device, reference may be made to the description of the first silicon rod in step S202, which is not repeated herein.

Step S210, rotating the silicon rod conversion device by a second preset angle to convert the first silicon rod from the grinding area to a waiting area, convert the second silicon rod from the second cutting area to the grinding area, convert the third silicon rod from the first cutting area to the second cutting area, and convert the fourth silicon rod from the waiting area to the first cutting area, and unloading the first silicon rod from the waiting area, loading the fifth silicon rod and preprocessing the fourth silicon rod by the silicon rod loading and unloading device; at this stage, the grinding device is caused to perform grinding operations (e.g., surface grinding, rounding/chamfering) on the second silicon rod in the grinding location, the second cutting unit in the cutting device is caused to perform second fold cutting on the third silicon rod in the second cutting location, and the first cutting unit is caused to perform first fold cutting on the fourth silicon rod in the first cutting location. And the cross section of the third silicon rod after being cut by the second folded surface is rectangular.

In step S210, since the waiting location, the first cutting location, the second cutting location, and the grinding location of the silicon rod processing platform are sequentially 90 ° apart from each other, the second preset angle for rotating the silicon rod conversion device is that the silicon rod conversion device is rotated by 90 ° in the forward direction or 270 ° in the reverse direction. The silicon rod conversion device reversely rotates 270 degrees, so that the silicon rod conversion device can return to the initial position, and a cable wound in the forward rotation process can be released.

And reversely rotating the silicon rod conversion device by 270 degrees, converting the first silicon rod from the second cutting area to the waiting area, converting the second silicon rod from the first cutting area to the second cutting area, and converting the third silicon rod from the waiting area to the first cutting area.

Therefore, the silicon rod loading and unloading device can unload the first silicon rod on the waiting position so as to transfer the first silicon rod out of the silicon rod processing platform, and load the fourth silicon rod to be cut onto the silicon rod positioning mechanism at the waiting position of the silicon rod processing platform.

In step S210, the step of unloading the first silicon rod on the waiting section by the silicon rod loading and unloading device may specifically include: transferring the first silicon rod with the rectangular-like cross section to a bottom supporting piece of a supporting body in a silicon rod bearing device in a vertical placement state; the supporting body is driven to overturn relative to the base through the overturning mechanism so that the supporting body and a first silicon rod on the supporting body are converted from a vertical type to a horizontal type, and a second supporting body of the supporting body in the silicon rod supporting device supports the first silicon rod, so that the first silicon rod is unloaded.

In practical application, the transferring of the first silicon rod with the rectangular-like cross section to the bottom support member of the support body in the silicon rod bearing device in the vertical placement state refers to transferring the first silicon rod on the rotary support table of the silicon rod positioning mechanism at the waiting position to the bottom support member of the support body in the silicon rod bearing device.

For example, the silicon rod handling device is moved to a waiting position, wherein the carrier of the silicon rod handling device is at a second position, such as a vertical position, and the first carrier of the carrier swings outwards to reveal the second carrier, and the bottom supporting member of the carrier is at a second adjusting position and is located below the rotary carrier; the supporting body is directly turned over through the turning mechanism, so that the supporting body is turned over relative to the base through the turning mechanism, so that the bottom supporting member supports the bottom end of the first silicon rod in the turning process and the first silicon rod leans against the second supporting member in the supporting body, or the bottom supporting member is driven to move from the second adjusting position to the first adjusting position (the height of the first adjusting position is higher than that of the second adjusting position in the vertical direction and the height of the table top of the rotary bearing table in the silicon rod positioning mechanism at the waiting position) until the bottom supporting member supports the first silicon rod on the rotary bearing table in an abutting mode (in some implementation modes, the first silicon rod on the rotary bearing table can also be ejected and lifted to be separated from the rotary bearing table).

As for loading the fifth silicon rod onto the silicon rod positioning mechanism at the waiting location by using the silicon rod loading and unloading device and preprocessing the fifth silicon rod, reference may be made to the description of the first silicon rod in step S202, which is not repeated herein.

Meanwhile, the second silicon rod on the grinding area of the silicon rod processing platform can be ground by the grinding device. For a specific manner of using the grinding device to grind the second silicon rod on the grinding section of the silicon rod processing platform, reference is made to the foregoing description, and further description is omitted here.

Meanwhile, the third silicon rod on the first cutting area and the second silicon rod on the second cutting area of the silicon rod processing platform can be cut by utilizing the cutting device.

When the cutting device is used for cutting a third silicon rod on a first cutting area and a second silicon rod on a second cutting area of the silicon rod processing platform, the cutting support is driven to descend relative to the cutting frame, and a first cutting unit and a second cutting unit on the left side and the right side of the cutting support simultaneously cut the third silicon rod on the corresponding first cutting area and the second silicon rod on the corresponding second cutting area, wherein the first cutting unit performs first plane cutting on the third silicon rod on the first cutting area (the first cutting unit 23 is provided with a first cutting line net in a shape of a plus or a reversed L), and the second cutting unit performs second plane cutting on the second silicon rod on the second cutting area (the second cutting unit is provided with a second cutting line net in a shape of a plus or a reversed L). Wherein, it should be noted that before the second cutting unit is used for carrying out the second folding surface cutting on the second silicon rod at the second cutting position, because of the problem of the aforementioned folding surface cutting, the silicon rod positioning mechanism in the silicon rod conversion device is also used for driving the second silicon rod to rotate forward or reversely by 180 degrees so as to adjust the cutting surface. Therefore, after the second silicon rod positioned on the second cutting area is subjected to second plane-folding cutting by the second cutting unit, the silicon rod with the rectangular-like cross section is formed.

According to the silicon rod cutting and grinding method disclosed by the application, silicon rods can be transferred between the processing devices orderly and seamlessly by using the silicon rod conversion device, the silicon rods are subjected to cutting operation by using the cutting device to form the silicon rods with the rectangular-like cross sections, the cut silicon rods are ground by using the grinding device, the silicon rods with different shapes are respectively borne by the first bearing parts and the second bearing parts in the silicon rod device unloading device, and the current borne silicon rods are switched among different placement states by driving the bearing parts to turn over, so that the loading operation of the silicon rods to be processed and the unloading operation of the processed silicon rods can be simultaneously realized, the integrated operation of cutting and grinding the silicon rods is completed, and the production efficiency and the quality of product processing operation are improved.

The above embodiments are merely illustrative of the principles and utilities of the present application and are not intended to limit the application. Any person skilled in the art can modify or change the above-described embodiments without departing from the spirit and scope of the present application. Accordingly, it is intended that all equivalent modifications or changes which can be made by those skilled in the art without departing from the spirit and technical concepts disclosed in the present application shall be covered by the claims of the present application.

Claims (21)

1. The flaw-piece discharging device is applied to silicon rod processing equipment, the silicon rod processing equipment comprises a base, a cutting device and a silicon rod conversion device, the cutting device comprises a movably arranged cutting unit, the cutting unit is provided with at least one cutting wire saw, and the at least one cutting wire saw forms a cut silicon rod and a flaw-piece after cutting the silicon rod to be cut; the silicon rod discharge apparatus includes:

the flaw-piece jacking mechanism is used for jacking the flaw-pieces; and

a flaw-piece lifting unit for lifting a flaw-piece so that the flaw-piece tip protrudes out of the cut silicon rod.

2. The flaw-piece discharge device of claim 1, wherein the flaw-piece jacking mechanism comprises:

the jacking component is provided with at least one jacking rod; and

and the jacking driving unit is used for driving at least one jacking rod in the jacking assembly to do lifting motion.

3. The flaw-piece discharge apparatus of claim 2 wherein the jacking assembly comprises:

the ejector rod seat is provided with a hollow accommodating space and an ejector rod hole; and

at least one ejector rod is arranged in the accommodating space of the ejector rod seat in a liftable mode through the ejector rod hole.

4. The flaw-piece discharging device according to claim 3, wherein the ejector pin has a stressed bottom end and a jacking end opposite to each other, wherein the jacking end penetrates through the ejector pin hole, and the stressed bottom end drives the jacking end to move up and down relative to the ejector pin base after being stressed.

5. The flaw-piece discharging device according to claim 4, wherein the jacking end of the ejector rod is further provided with a buffering structure.

6. The flaw-piece discharge apparatus of claim 3, wherein the jacking assembly further comprises: the elastic piece is sleeved on the ejector rod and positioned between the ejector rod and the ejector rod seat.

7. The flaw-piece discharge apparatus of claim 6 wherein said resilient member comprises a compression spring.

8. The flaw-piece discharging device according to claim 2, wherein the jacking driving unit comprises a driving cylinder or a driving hydraulic cylinder with a telescopic rod, and the telescopic rod is associated with the stressed bottom end of the jacking rod.

9. The flaw-piece discharging device according to claim 8, wherein an action included angle is formed between the axis of the telescopic rod and the axis of the top rod, and the action end of the telescopic rod and the stressed bottom end of the top rod are in a wedge-shaped structure.

10. The flaw-piece discharging device according to claim 9, wherein the stressed bottom end of the ejector rod is designed to be a wedge-shaped structure or a wedge block is added to the stressed bottom end of the ejector rod, the action end of the telescopic rod is designed to be a wedge-shaped structure or a wedge block is added to the action end of the telescopic rod, and the wedge-shaped structure or the wedge block at the stressed bottom end of the ejector rod is correspondingly matched with the wedge-shaped structure or the wedge block at the action end of the telescopic rod.

11. The flaw-piece discharge apparatus of claim 1 wherein said flaw-piece lifting unit is fixedly disposed on said unit and comprises: the jacking piece is driven by the telescopic component to do telescopic motion.

12. The flaw-piece discharge apparatus of claim 1 further comprising a flaw-piece stabilizing unit including a support assembly and a drive member coupled to the support assembly.

13. The flaw-piece discharge apparatus of claim 12 wherein said support assembly includes a mounting member and a flaw-piece stop member disposed on the mounting member.

14. The flaw-piece discharge apparatus of claim 13 wherein said mounting member includes a fixed portion and a movable portion movably connected to said fixed portion, said flaw-piece stop being disposed on said movable portion.

15. The flaw-piece discharge apparatus of claim 13 or 14 wherein the flaw-piece stop comprises a flaw-piece wheel.

16. The flaw-piece discharge apparatus according to claim 15, wherein the contact portion of the flaw-piece block wheel with the flaw-piece is provided with a slope or a circular arc.

17. The flaw-piece discharge apparatus according to claim 13, wherein the driving member comprises a driving cylinder or a driving hydraulic cylinder having a telescopic rod connected to the movable portion of the mounting member.

18. The flaw-piece discharging device according to claim 1, further comprising a wire pulling mechanism provided on the cutting unit for pulling the cutting wire saw to expand outward to avoid interference between the cutting wire saw and the cut silicon rod.

19. The flaw-piece discharging apparatus according to claim 1, further comprising a flaw-piece transferring unit for transferring the flaw-piece from the cutting zone and discharging the flaw-piece.

20. A silicon rod squarer, comprising:

the base is provided with a silicon rod processing platform; the silicon rod processing platform comprises a cutting zone;

the cutting device is arranged at a cutting position of the silicon rod processing platform; the cutting device comprises a movably arranged cutting unit, and the cutting unit is provided with at least one cutting wire saw; and

A flaw-piece discharge apparatus as claimed in any one of claims 1 to 19.

21. The utility model provides a silicon rod surely grinds all-in-one which characterized in that includes:

the base is provided with a silicon rod processing platform; the silicon rod processing platform comprises a cutting area and a grinding area;

the cutting device is arranged at a cutting position of the silicon rod processing platform; the cutting device comprises a movably arranged cutting unit, and the cutting unit is provided with at least one cutting wire saw;

the flaw-piece discharge apparatus of any one of claims 1 to 19;

the grinding device is arranged at a grinding zone bit of the silicon rod processing platform; the grinding device comprises a movably arranged grinding tool; and

and the silicon rod conversion device is arranged on the silicon rod processing platform and used for bearing a silicon rod and converting the silicon rod among the functional regions.

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