CN220464353U - Slicing unitized production line - Google Patents

Abstract

The utility model relates to the technical field of wire cutting, and particularly provides a slicing unitized production line, which comprises the following steps: a production line main body; at least one microtome disposed on the line body and capable of forming an avoidance space; and the transfer mechanism at least comprises at least one AGV, and the at least one AGV can carry the workpiece and at least can convey the workpiece to and/or remove the workpiece from the slicer through the avoidance space. For example, the liquid path part and the electric control part of the slicing machine are arranged outside the cutting chamber, and the arrangement mode of the liquid path part and the electric control part can enable the slicing machine to create an avoidance space. With this configuration, it is possible to realize a dicing unit production by a plurality of machines.

Description

Slicing unitized production line

Technical Field

The utility model relates to the technical field of wire cutting, and particularly provides a slicing unitized production line.

Background

Taking a hard and brittle material as a silicon rod as an example, a device for processing the silicon rod generally comprises a cutting machine for cutting a bar (round rod) according to a length specification, an squaring machine for cutting the round rod with a certain length into square rods, a grinding machine for grinding (grinding surface and chamfer) the square rod (such as rough grinding and fine grinding), and a slicing machine for slicing the square rod with the precision reaching the standard after the grinding, wherein the working principle of the slicing machine is as follows: after bonding the square bar to the wafer support, slicing the square bar by wire webs of a cutter in a wire saw cutting manner along the radial direction of the silicon bar (the silicon bar is fed along the radial direction thereof, and the wire webs reciprocate between adjacent cutting rollers) to produce silicon wafers (such as silicon wafers), and a one-blade slicing operation of the cutter corresponding to each complete slicing operation of the wire webs.

Taking the slicing operation as an example, the slicing operation of the existing slicing machine is concentrated near the slicing station, and each cutting operation is a single operation performed on a single silicon rod, since each cutting operation usually comprises several tens of operation steps and is usually completed by one to two operators. Such a processing manner often has the following problems: the operation of the slicing machine has high requirements on the expertise and the proficiency of operators, the operation of the slicing machine is easy to make mistakes by operators, and cutting anomalies with different degrees can be caused once the mistakes of the operators occur.

Taking the photovoltaic industry as an example, which is one of the application fields of silicon wafers, along with the rapid development of the photovoltaic industry, the continuous production expansion requirement is necessarily put forward for the silicon wafer processing chain including slicing operation. As described above, this has led to a continuous increase in the gap of operators who have had a gap, and thus, the stand-alone products (slicers) corresponding to stand-alone operations have been gradually unable to meet the market demands. In view of this, the inventors have made intensive studies and analyses on the operation of the microtome, and have aimed at providing a unitized structure frame capable of realizing simultaneous operation of a plurality of microtomes.

Disclosure of Invention

The utility model aims to provide a production line capable of realizing slicing unitization operation finished by a plurality of slicing machines.

In view of this, the present utility model provides a slicing unitized production line, comprising: a production line main body; at least one microtome, and the microtome is capable of forming an avoidance space; and a transfer mechanism including at least one automatic guided vehicle (Automated Guided Vehicle, AGV for short) capable of carrying a workpiece and at least capable of delivering and/or removing the workpiece to and/or from the microtome through the avoidance space.

By this construction, a possible construction of the dicing line is given.

It is understood that the structural form and number of the transfer mechanism, the specific mode of carrying the workpiece to the transfer mechanism, the movement of the workpiece and the position to which the transfer mechanism can drive can be determined by those skilled in the art according to actual requirements. For example, the transfer mechanism can have one or more degrees of freedom to realize movement in corresponding directions, the workpiece can be directly or by means of a certain intermediate component carried on the transfer mechanism, the transfer mechanism can realize carrying of the workpiece by means of bonding, abutting, accommodating and the like, and the number of the transfer mechanism and the number of the slicing machines can be one-to-one, one-to-many or many-to-many.

It will be appreciated that the specific form, orientation, manner of formation, etc. of the avoidance space may be determined by those skilled in the art based on actual requirements, such as being formed within an existing component of the microtome, between different existing components, between an existing component of the microtome and other components that are newly added, etc.

It will be appreciated that one skilled in the art may determine the number of microtomes and AGVs and the correspondence between the two according to the actual requirements, and in the case where the microtome includes a plurality of microtomes, for example, the correspondence between the AGVs and the microtomes may be one-to-one, many-to-many, etc. The method can be as follows: the zoned or split line orientation configures a plurality of AGVs for a plurality of microtomes. It is obvious that one skilled in the art can select an AGV of any specification (e.g., a loading scale, a dimension of activity, a walking principle, control logic, a model, etc.) according to actual needs.

It is understood that the transfer mechanism can be completed by the AGV in all links for the transfer task of the workpiece, or can be completed by the ground track robot only in part. May be accomplished by one AGV or may be accomplished by multiple AGVs in concert. Illustratively, the relay tasks corresponding to the workpieces include relay tasks corresponding to path A, B, C, where the relay tasks corresponding to path a are accomplished by the AGV and the relay tasks corresponding to path B, C are accomplished by other means. Illustratively, after the workpiece is delivered by path a to a designated location (e.g., the intersection of path a and path B) by the AGV, the workpiece transport corresponding to path B is accomplished by another robot, such as a ceiling track robot, truss robot, RGV, or gripper assembly, etc.

For the slicing unitized production line, in one possible implementation manner, the production line main body is provided with a feeding component and a discharging component, and the transfer mechanism can move between a feeding area corresponding to the feeding component and a discharging area corresponding to the discharging component; and/or the transfer mechanism can move in the feeding area and/or the discharging area.

By means of this construction, a movement of the workpiece by means of the transfer mechanism is provided.

For the above slicing unitized production line, in one possible embodiment, the transfer mechanism is movable in a manner approaching/separating from the slicer at a position between the loading area and the unloading area.

By means of this construction, a movement of the workpiece by means of the transfer mechanism is provided.

For the above slicing unitizing production line, in one possible embodiment, the relay mechanism is movable in a vertical direction in a manner to approach/separate from the slicer.

By means of this construction, a movement of the workpiece by means of the transfer mechanism is provided.

For the above slicing unitized production line, in one possible implementation manner, the production line main body is configured with a joining tool, the joining tool can be set up in the transfer mechanism, and the workpiece can be carried to the joining tool.

With this configuration, the work can be mounted on the transfer mechanism by the joining tool.

It is understood that, a person skilled in the art may determine the structural form and number of the joining tool, the manner in which the workpieces are mounted on the joining tool, the manner in which the workpieces are configured in the transfer mechanism, and the like according to actual requirements. The method can be as follows: the two connecting tools are used for carrying the workpiece through the approach of the two connecting tools in the vertical direction or the horizontal direction; the connecting tool comprises a space which is formed in the connecting tool and can accommodate the space; etc.

For the above slicing unitized production line, in one possible embodiment, the joining tool includes: the first movable part can move in a direction approaching to/separating from a cutting chamber of the slicing machine, and at least one abutting structure capable of fixedly connecting the first movable part with a workpiece is arranged on the first movable part.

By such a construction, a possible structural form of the joining tool is given.

It will be appreciated that the person skilled in the art can determine the structural form of the first movable part and the way in which it is realized the movement towards/away from the cutting chamber, according to the actual requirements, e.g. manually or by means of a reasonable driving transmission or the like. The first movable portion may be a plate-like structure, a block-like structure, a structure having an accommodation space, or the like, for example.

In addition, it is understood that those skilled in the art can determine the structural form, number and specific manner of implementing the fastening of the docking structure and the workpiece according to actual requirements. For example, the butt joint structure can be butt joint with the original structure of the workpiece (or the original configuration structure of the workpiece) to realize the fixedly connection, or a structure matched with the butt joint structure is added to realize the fixedly connection, and the fixedly connection mode can be bonding, butt joint, lap joint, clamping connection, grafting connection, screwing connection and the like.

For the above slicing unitized production line, in one possible implementation, the workpiece is carried on a crystal holder, and the docking structure can cooperate with the crystal holder and thus achieve the fixation of the workpiece to the first movable portion.

By such a construction, a possible form of achieving the work-piece fixation by the docking structure is given. For example, the butt joint structure can be matched with the existing part/structure or the newly added part/structure of the crystal support in the modes of bonding, abutting, lapping, clamping, inserting, screwing and the like to realize the fixedly connection of the workpiece and the first movable part.

For the slicing unitized production line, in one possible implementation manner, the crystal support comprises an operation end, and the docking structure can be fixedly connected with the crystal support in a manner of extending into the operation end.

By means of the structure, a mode of realizing fixedly connection of the butt joint structure is provided, for example, the handle with the middle part being hollow at the operation end. Accordingly, the abutting structure may be a protruding end of a block structure, a columnar structure, a hook structure, or the like. For example, the docking structure can drive the docking structure to extend into/withdraw from the handle through the movement of the transit structure along the vertical direction.

For the slicing unitized production line, in one possible implementation manner, the first movable portion is a strip-shaped structure, and a plurality of the abutting structures are arranged on the strip-shaped structure along the length direction of the strip-shaped structure.

By means of this construction, a possible construction of the first movable part is given.

It is understood that, a person skilled in the art may determine the number of the docking structures and the distribution form thereof on the strip structure according to the actual requirement, for example, the structure forms of the plurality of docking structures may be the same or different, and the plurality of docking structures may be uniformly or unevenly distributed along the length direction of the strip structure, etc.

For the slicing unitizing production line, in one possible implementation manner, the strip-shaped structure has a first end and a second end, the strip-shaped structure is provided with the docking structure at the first end or a position close to the first end, and the strip-shaped structure is provided with the docking structure at the second end or a position close to the second end.

With this configuration, the feeding and discharging operation for the single microtome can be realized by the cooperation of the two butting structures.

For the above slicing unitized production line, in one possible embodiment, the joining tool includes: a first driving part capable of driving the first movable part to move in a manner of approaching/separating from the cutting chamber.

By such a construction, a possible way of the first movable part to achieve its movement is given.

It will be appreciated that the configuration of the first driving member and the specific manner in which it drives the first movable part to move closer to/further from the cutting chamber may be determined by one skilled in the art based on actual requirements. For example, the first driving component can be a motor, a power cylinder (such as a cylinder, an electric cylinder and a hydraulic cylinder), a rotary module, a linear module and the like, and the first driving component can directly drive and also can indirectly drive the first movable part to move close to/far from the cutting chamber through a transmission component such as a gear set, a gear rack mechanism, a screw nut mechanism and the like.

For the above slicing unitized production line, in one possible embodiment, the joining tool includes: the first driving part can drive the first movable part to move along a mode of approaching/separating from the cutting chamber through the first lead screw nut mechanism.

By such a constitution, a specific form of the drive transmission mechanism corresponding to the first movable portion is given.

For the above slicing unitized production line, in one possible embodiment, the joining tool includes: a carrying portion capable of carrying a workpiece so as to: in the case of loading a workpiece onto the loading portion, the loading portion and the workpiece move with the movement of the first movable portion.

By such a construction, a possible structural form of the joining tool is given.

It is understood that the structural form, number and specific manner of carrying the work pieces can be determined by those skilled in the art according to actual requirements. For example, the mounting portion may have a static mounting space or may form a dynamic mounting space.

For the above slicing unitizing production line, in one possible embodiment, the carrying portion includes a second movable portion including a first portion and a second portion, the first portion and the second portion being capable of relative movement therebetween in a direction approaching/separating from each other to hug the workpiece.

With this configuration, a possible configuration of the mounting portion is given.

It will be appreciated that the person skilled in the art can determine the form of construction of the first/second part, the manner of relative movement between the two, the manner of generation of the forces by means of which this movement is achieved, etc. according to the actual requirements. As may be the case where both the first and second portions are movable or only one of them is movable and the other stationary. The relative movement between the two can be achieved by manpower or by means of a reasonable driving transmission mechanism or the like.

For the above slicing unitized production line, in one possible embodiment, the joining tool includes: a second drive member capable of driving movement of the first portion and/or the second portion.

By such a construction, a possible way of the second movable part to achieve its movement is given.

Similar to the first drive member described above, it will be appreciated that the configuration of the second drive member and the particular manner in which it drives the first/second portions to effect relative movement therebetween will be determined by one skilled in the art based on actual requirements. For example, the second driving component can be a motor, a power cylinder (such as a cylinder, an electric cylinder and a hydraulic cylinder), a rotary module, a linear module and the like, and the second driving component can directly drive or indirectly drive the first part and the second part to generate relative movement through a transmission component such as a gear set, a gear rack mechanism, a screw nut mechanism and the like.

For the above slicing unitized production line, in one possible embodiment, the joining tool includes: a second screw-nut mechanism, the screw of which has two threaded sections with opposite screwing directions, the second driving member being capable of driving the first portion and the second portion to move in a manner approaching/moving away from each other by the second screw-nut mechanism.

By such a constitution, a specific form of the drive transmission mechanism corresponding to the second movable portion is given.

For the above slicing unitized production line, in one possible implementation manner, the engagement tool includes a tool base, and the first movable portion is disposed on the tool base.

By such a construction, a possible structural form of the joining tool is given. For example, the tool base body is mainly used as a mounting carrier, and thus, the first movable part and the second movable part are directly or indirectly arranged on the mounting base body. In addition, the tool substrate can be fixedly connected to the transfer mechanism, so that the connection tool is adapted to the production line. For example, the tool matrix can be a mounting rack, a mounting table board and the like.

For the above slicing unitizing production line, in one possible embodiment, the slicer comprises: a microtome body formed with a cutting chamber: a liquid path portion; an electric control part; the liquid path part and the electric control part are arranged on the outer side of the cutting chamber, and the liquid path part and the electric control part are arranged in a mode that the slicing machine can be used for manufacturing an avoidance space so as to: the workpiece can realize feeding operation and/or discharging operation through the avoidance space.

By means of this construction, a possible design of the microtome is provided.

It is understood that the structural form of the liquid path portion and the electric control portion, the arrangement position of each relative to the cutting chamber, the relative position therebetween, and the like can be determined by those skilled in the art according to actual requirements. For example, the liquid path part/the electric control part can be arranged in a concentrated mode or in a split mode. The two can be arranged in a concentrated way or separated way.

It will be appreciated that a person skilled in the art may determine the specific form, orientation, etc. of the avoidance space according to the actual loading and unloading requirements, for example, the avoidance space allows the member to be loaded from the front end, the rear end, or the side of the cutting chamber.

For the slicing unitized production line, in one possible implementation manner, the electric control part comprises a first electric control cabinet and a second electric control cabinet, and the first electric control cabinet and the second electric control cabinet are arranged in a centralized manner or in a split manner.

By means of this construction, possible configurations of the electrical control unit are provided.

It will be appreciated that a person skilled in the art may determine the distribution manner of the first/second electric control cabinets according to actual requirements, e.g. according to a high voltage and a low voltage division, e.g. one of the first electric control cabinet and the second electric control cabinet is a high voltage electric control cabinet and the other is a low voltage electric control cabinet.

For the slicing unitized production line, in one possible implementation manner, the liquid path portion includes a liquid path system, and the liquid path system includes a first liquid path unit and a second liquid path unit, where the first liquid path unit and the second liquid path unit are set in a centralized manner or set separately.

By this construction, a possible configuration of the liquid passage portion is given.

It is understood that the manner of distribution of the first/second fluid path units may be determined by those skilled in the art according to actual needs, for example, according to the circulation division of the cutting fluid, such as that one of the first fluid path unit and the second fluid path unit is an outer circulation fluid path unit and the other is an inner circulation fluid path unit.

For the slicing unitizing production line, in one possible embodiment, the liquid path portion includes a liquid supply cylinder disposed at a position adjacent to the first liquid path unit or the second liquid path unit.

By this construction, a possible configuration of the liquid passage portion is given.

For the slicing unitized production line, in one possible implementation manner, the first liquid path unit and the second liquid path unit are respectively arranged at two sides of the cutting chamber, and the first electric control cabinet and the second electric control cabinet are respectively arranged above the first liquid path unit and the second liquid path unit, so that: and the avoidance space is formed between the first electric control cabinet and the second electric control cabinet.

By this construction, a possible design of the avoidance space is provided.

For the slicing unitized production line, in one possible implementation manner, a reserved space is formed below the first liquid path unit, and the liquid supply cylinder is disposed in the reserved space.

By this construction, a possible arrangement of the supply cylinders is given.

For the slicing unitized production line, in one possible implementation manner, the first liquid path unit and the second liquid path unit are arranged in a centralized manner to form a first assembly, the first electric control cabinet and the second electric control cabinet are arranged in a centralized manner to form a second assembly,

the first and second components are disposed on both sides of the cutting chamber and thus form the escape space therebetween.

By this construction, a possible design of the avoidance space is provided.

For the above slicing unitizing production line, in one possible embodiment, the supply cylinder is disposed between the second assembly and the second assembly.

By this construction, a possible arrangement of the supply cylinders is given.

For the slicing unitized production line, in one possible implementation manner, the first liquid path unit and the second liquid path unit are arranged in a centralized manner to form a first component, the first electric control cabinet and the second electric control cabinet are arranged in a centralized manner to form a second component, and the first component and the second component are arranged on one side of the cutting chamber along the feeding and discharging direction of the workpiece in a longitudinally stacked manner, and therefore an open avoidance space is formed between the cutting chamber and one side of the cutting chamber.

By this construction, a possible design of the avoidance space is provided.

For the slicing unitizing production line, in one possible implementation manner, the liquid supply cylinder is arranged beside a structure formed by longitudinally stacking the first component and the second component, and projects toward a cutting chamber along the feeding and discharging direction of the workpiece, and the cutting chamber and the liquid supply cylinder are at least partially overlapped.

By this construction, a possible arrangement of the supply cylinders is given. The method can be as follows: a portion disposed at the other side of the cutting chamber so as not to overlap with the cutting chamber; is disposed entirely between the two sides so that the projection entirely overlaps the cutting chamber; one part is disposed between the two sides and the other part is disposed at the other side so as to partially overlap the cutting chamber.

For the slicing unitized production line, in one possible implementation manner, the first electric control cabinet and the second electric control cabinet are collectively arranged to form a second assembly, and the second assembly is configured in the cutting chamber in a suspension manner.

By this construction, a possible design of the avoidance space is provided.

It can be understood that the suspended setting mode and setting position of the second component can be arbitrarily selected according to actual requirements.

Drawings

The following takes a workpiece as a silicon rod (hereinafter referred to as a silicon rod for short, including a silicon rod to be processed including a crystal support and a processed silicon wafer including a crystal support), and the transfer mechanism includes an AGV (wherein, the AGV has the obvious advantages of flexible operation during the completion of the transfer operation, and physically does not occupy a fixed space on the ground; although there are also disadvantages such as low positioning accuracy and low operation efficiency), and the preferred embodiment of the present utility model will be described with reference to the accompanying drawings, in which:

FIG. 1 shows a schematic diagram of a slicing unitizing production line according to one embodiment of the present utility model;

fig. 2 shows a schematic structural diagram of a joining tool in a slicing and unitizing production line according to an embodiment of the present utility model;

fig. 3 shows a second schematic structural diagram of a joining tool in a slicing and unitizing production line according to an embodiment of the present utility model;

fig. 4 shows a third schematic structural diagram of a joining tool in a slicing and unitizing production line according to an embodiment of the present utility model;

FIG. 5 shows a schematic diagram of the state of the joining tool for the feeding operation of the single machine of the microtome in the slicing unitized production line (AGV in place) according to one embodiment of the present utility model;

fig. 6 shows a second schematic state diagram of a joining tool for feeding operation of a single machine of a slicing machine (a handle of a tail end of a crystal support is hooked by an extending end at a rear part of the joining tool) in a slicing unitized production line according to an embodiment of the utility model;

Fig. 7 shows a third schematic view of a state of a joining tool for feeding operation of a single machine of a slicer in a slicing unitized production line according to an embodiment of the present utility model (the whole material exits from the inside of the fixture and is joined to an inner rail of the cutting chamber);

fig. 8 shows a fourth schematic state diagram of a joining tool for feeding operation of a single machine of a slicing machine (a first movable part of the joining tool extends out to hook a handle at the tail end of a crystal support) in a slicing unitized production line according to an embodiment of the utility model;

fig. 9 shows a fifth state diagram of a feeding operation of the joining tool for a single slicer in the slicing and unitizing production line according to one embodiment of the present utility model (pushing the whole material into the cutting chamber):

FIG. 10 shows a schematic diagram of the state of the engagement tool in the slicing unitized production line for the blanking operation of the single machine of the slicer (AGV in place) according to one embodiment of the present utility model;

FIG. 11 shows a second schematic view of a state of a joining tool (a first movable portion of the joining tool extends to hook a handle at a tail end of a crystal support) for a single machine blanking operation of a slicing machine in a slicing unitized production line according to an embodiment of the present utility model;

fig. 12 shows a third schematic view of a state of a joining tool for a single-machine blanking operation of a slicer (pulling the whole material out of a cutting chamber) in a slicing unitized production line according to an embodiment of the present utility model;

Fig. 13 shows a fourth schematic view of a state of a joining tool for a single-machine blanking operation of a slicing machine in a slicing and unitizing production line according to an embodiment of the present utility model (a first movable portion of the joining tool stretches out again, and a stretching end at a rear portion thereof hooks a handle at a tail end of a crystal support);

fig. 14 shows a fifth state diagram of a joining tool for a single-machine blanking operation of a slicer (pulling the whole material into the interior of the jig) in a slicing unitized production line according to an embodiment of the present utility model;

FIG. 15 is a schematic view showing the structure of a single microtome in a microtome unit production line according to one embodiment of the present utility model;

FIG. 16 shows a second schematic view of the architecture of a microtome stand-alone in a microtome unit fabrication line in accordance with one embodiment of the present utility model; and

fig. 17 shows a third schematic view of the structure of a single microtome in a microtome unit process line according to an embodiment of the present utility model.

List of reference numerals:

1. a production line main body;

21. a feeding area; 22. a blanking area;

3、AGV；

4. a connecting tool;

40. a mounting substrate;

41. a first movable portion; 411. an extension end; 412. a first servo motor; 413. a first lead screw nut mechanism;

421. a first portion; 422. a second portion; 423. a second servo motor; 424. a second lead screw nut mechanism; 425. a second linear guide rail; 426. a clamping plate; 427. a protrusion;

5. A slicer;

51. a slicer body; 52. a cutting chamber; 53. a cutting mechanism;

54. a fluid path system; 541. an internal circulation liquid path unit; 542. an external circulation liquid path unit; 55. a liquid supply cylinder;

57. an electric control cabinet; 571. a low-voltage electric control cabinet; 572. a high-voltage electric control cabinet;

61. a silicon rod; 62. and a crystal support.

Detailed Description

Preferred embodiments of the present utility model are described below with reference to the accompanying drawings. It should be understood by those skilled in the art that these embodiments are merely for explaining the technical principles of the present utility model, and are not intended to limit the scope of the present utility model.

It should be noted that, in the description of the present utility model, terms such as "center," "upper," "lower," "left," "right," "vertical," "horizontal," "inner," "outer," and the like indicate directions or positional relationships based on the directions or positional relationships shown in the drawings, which are merely for convenience of description, and do not indicate or imply that the apparatus or elements must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the present utility model. Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

Furthermore, it should be noted that, in the description of the present utility model, unless explicitly specified and limited otherwise, the terms "mounted," "configured," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be directly connected, can be indirectly connected through an intermediate medium, and can also be communicated with the inside of two elements. The specific meaning of the above terms in the present utility model can be understood by those skilled in the art according to the specific circumstances.

Furthermore, in the following detailed description, numerous specific details are set forth in order to provide a thorough understanding of the present utility model, it will be appreciated by those skilled in the art that the present utility model may be practiced without some of these specific details. In some instances, the principles of microtomes, AGVs BAIGF1, etc., which are well known to those skilled in the art, have not been described in detail in order to highlight the gist of the present utility model. The present utility model will be explained below with reference to all or part of fig. 1 to 17.

A microtome is a form of apparatus of a wire cutting machine, and is mainly used for cutting a silicon rod (commonly called a square rod) having a grinding accuracy reaching the standard by using a wire net composed of cutting wires (such as diamond wires, etc.) to obtain a silicon wafer. In general, the slicing operation is performed in the following manner: after the sticking of the square rods to be sliced is finished (the square rods to be sliced are stuck to the crystal support) in a sticking workshop, the crystal support is fixed on a feeding mechanism, and in the process of reciprocating motion of a wire net wound on a cutting main roller of a cutting mechanism, the wire net can slice the square rods in a wire saw cutting mode by driving the feeding mechanism to drive the silicon rods to be close to the wire net. If the slicing machine comprises a slicing machine body, a cutting chamber is formed on the slicing machine body, an operation door is arranged on the left side and the right side of the cutting chamber respectively, and a cutting mechanism is arranged in the cutting chamber. In this example, the cutting mechanism constituted by the plurality of main cutting rollers is constructed in such a manner that a single operation is a single-station structure capable of slicing one silicon rod.

In one possible embodiment, the present utility model provides a slicing production line capable of realizing multi-machine automated production, and the production line mainly includes a production line main body 1, for example, the production line main body may include, but is not limited to, a necessary working table, an end allowing manual intervention, a part needing manual operation, a control end configured at an operation site, an acquisition end capable of acquiring an operation on site (such as a visual signal, an audio signal, etc.), a central control end capable of analyzing and controlling the slicing operation on site, and a reminding end capable of sending reminding information such as voice broadcasting, alarm, etc. if necessary. The slicing line includes a plurality of slicers 5 (single machines) disposed on the main body of the line, based on which, it is expected that the slicers simultaneously slice the silicon rod to be processed (the ground square rod) or select a part of the slicers to slice the silicon rod, for example, the single machines are disposed on both sides of the main body of the line in a removable manner, so that the scale of the line can be flexibly adjusted and the single machines can be replaced or overhauled after being removed. The configuration of the plurality of single units, the slicing operation mode, and the mode of arrangement thereof in the production line main body may be the same or different. Illustratively, the production line body includes a plurality of zones, wherein a single unit of a certain zone is mainly used for processing silicon wafers requiring more severe requirements, and thus the single unit corresponding to the zone has better processing accuracy.

In one possible embodiment, the production line body is provided with a loading assembly and a discharging assembly, wherein the loading assembly is connected with a glue shop or a glue area, and the silicon rods (bonded to the crystal trays) which are discharged from a curing warehouse of the glue shop can be transferred to the loading area 21 corresponding to the loading assembly by manual and/or automatic operation, and the trolley carrying the silicon rods is manually transferred to the loading area. The blanking assembly is connected with a degumming workshop or a degumming area, and the degumming workshop mainly carries out degumming treatment on silicon rods (a plurality of silicon wafers in a shape) which are adhered to the crystal support and are subjected to slicing operation. Similar to the previously described engagement between the glue shop and the loading operation, the silicon rods corresponding to the blanking area 22 of the blanking assembly may also be transferred to the degumming shop or degumming area by means of manual and/or automatic operations, for example, by manually transferring the trolley carrying the silicon rods to the degumming shop or degumming area. The up/down assembly typically includes an up/down cart or up/down rack, etc.

In one possible embodiment, the aforementioned multiple units share a single loading assembly and a single unloading assembly and employ similar loading and unloading control logic for the units. Obviously, the structure of the feeding/discharging assembly can be adjusted according to actual requirements, such as but not limited to: configuring a plurality of feeding components and discharging components for a plurality of slicing machines, such as configuring one feeding component and discharging component for one or a plurality of single machines according to azimuth, priority, product model, attribute of a to-be-processed workpiece (such as specificity or importance degree of a certain batch of products, etc.), and configuring one feeding component and discharging component for a plurality of single machines in the same row by way of example, and configuring a single feeding component and discharging component for a certain single machine; the single machines share a feeding component and a discharging component, and separate feeding and discharging control logic is configured for one single machine or a plurality of single machines (such as the direction, the priority, the product model, the attribute of a workpiece to be processed and the like).

Taking a group of feeding components and a group of discharging components for example, the production line comprises a transfer mechanism, and the transfer mechanism is mainly used for realizing the transfer among the silicon rod to be sliced and the cut silicon wafer between the feeding components, the slicing machine and the discharging components and the transfer among the feeding components and the discharging components respectively, such as the transfer (feeding operation) of the silicon rod to be sliced, the transfer (discharging operation) of the silicon wafer after the cut between the slicing machine and the discharging components, the corresponding operation in the feeding/discharging components, the connection operation such as material taking and discharging in the area between the feeding/discharging components and the two, and the like.

In one possible embodiment, the transfer mechanism includes a manipulator/robot capable of traveling at least in the directions between the feeding component, the discharging component, and the different slicers, as in this embodiment, the manipulator of the transfer mechanism includes a plurality of AGVs 3 (six are included in this example), and the traveling logic of the six AGVs is used to realize the motion requirements of the AGVs between the feeding component and the discharging component (such as in the length direction corresponding to the slicing unitized production line, which may be referred to as the length direction), traveling in the direction of moving into/out of the cutting area of the single machine (such as in the width direction corresponding to the slicing unitized production line, which may be referred to as the width direction), traveling in the vertical direction (such as may be referred to as the longitudinal direction), traveling along other preset paths (such as oblique lines, folding lines, curves, etc.). For example, the corresponding single machine number can be calculated according to the logic beat of the group control system, so that the loading and unloading operation of the silicon rod on the single machine (moving in/out from a single machine cutting area) and the production line (entering a loading area of the production line or moving out of a discharging area of the production line) can be realized through the running of a plurality of AGVs in corresponding dimensions respectively carried by the AGVs.

Based on this, the production line works approximately as follows: for example, the group control system can be combined with the number of silicon rods to be processed, the equipment state of the single machine, the state of the AGV and the like to match the current silicon rods to be processed with the proper single machine, and based on the group control system, the AGV conveys the silicon rods to be processed to a preset target position which can be connected with the single machine of the slicing machine through the running cooperation along the length direction and the width direction from a feeding area corresponding to the feeding assembly according to the control instruction of the group control system. In the case where the silicon rod arrives at the target position, the group control system reconfirms the state information of the single microtome, such as state information including but not limited to in operation, in debugging, in maintenance, in fault processing, in standby, corresponding to the current arrival job, based on, for example, equipment management information, etc. When one or more of the AGVs fail, the single current slicer can be fed through the manner of manually feeding the front wall of the cutting room instead of the AGVs or by other AGVs instead of the AGVs originally configured for the current slicer. After the single machine of the slicing machine completes slicing operation on the silicon rod, the AGV moves the cut silicon wafer containing the crystal support to a blanking area corresponding to the blanking assembly through a walking path similar to the feeding operation path.

It can be seen that in the whole slicing unitized production line of the utility model, the functional area mainly comprises a feeding area corresponding to the feeding assembly, a slicing area corresponding to a plurality of single slicing machines, a discharging area corresponding to the discharging assembly and a temporary storage area for temporarily storing the carrying trolley. Based on this, by means of the traveling of the AGV on the ground, the movement of the silicon rod between the different microtome units can be achieved.

In one possible implementation, the production line body is configured with a joining tool 4, which can be configured in an AGV, and a silicon rod or wafer containing a wafer support can be mounted to the joining tool. The connection tool is mainly used for being matched with an AGV, so that a silicon rod containing a crystal support is moved into a single-machine cutting area to realize single-machine slice feeding operation, or a silicon wafer containing the crystal support is moved out of the single-machine cutting area to realize single-machine slice discharging operation.

In one possible embodiment, the engagement fixture 4 includes a fixture base 40 as a mounting carrier, and a first movable portion 41 and a second movable portion provided on the fixture base, such as a robot arm, on which the engagement fixture can be mounted by being engaged with the fixture base. Illustratively, the tooling substrate is generally a plate-like structure. The first movable part can move along the direction of moving in/out from the cutting area of the single machine so as to drive the silicon rod containing the crystal support to move along the direction, and the second movable part can form a clamping space for tightly holding the silicon rod containing the crystal support. Therefore, on the basis that the silicon rod containing the crystal support is held tightly by the second movable part, the loading and unloading operation of the silicon rod containing the crystal support on a single machine can be realized by means of the first movable part.

In one possible embodiment, the first movable portion 41 generally comprises a strip-like structure disposed along the aforesaid direction of insertion/removal from the cutting area of the single machine, on which a docking structure capable of cooperating with the crystalline support is disposed or formed along its length, so as to achieve a rigid connection between the first movable portion and the operating end of the crystalline support by means of the docking structure. Illustratively, the docking structure is a protruding end 411 extending downward from the strip structure, the protruding end being capable of mating with a handle at the end of the wafer support as one of the operating ends to effect a secure connection between the first movable portion and the wafer support. Therefore, under the driving of the servo motor, the strip-shaped structure can freely slide in the groove on the upper surface of the crystal support, the connecting tool is driven to move downwards/upwards by the manipulator, and the extending end is matched with the handle at the tail end of the crystal support, so that the crystal support is clamped or released, and the strip-shaped structure is loosened. In the present utility model, two protruding ends are provided at substantially two ends of the strip-like structure, respectively.

Illustratively, the first movable portion includes a first servo motor 412 that moves the strip-like structure in a direction of moving in/out from the cutting area of the single machine via a first lead screw nut mechanism 413. For example, to ensure that the movement of the first movable part is more stable, a first linear guide (not shown) may be arranged on the second movable part along the direction of the first movable part, and in this example, one first linear guide is arranged on each of two sides of the strip-shaped structure, and correspondingly, a sliding groove or a sliding hole capable of being matched with the linear guide is arranged at the end of the strip-shaped structure.

In one possible embodiment, the second movable portion includes oppositely disposed first and second portions 421 and 422 for holding or releasing the workpiece by moving the first and/or second portions in a direction toward/away from each other. Illustratively, if the second movable portion is configured with a second servo motor 423, the second servo motor is connected with a second screw-nut mechanism 424, and the screw of the second screw-nut mechanism includes two threaded sections with opposite rotation directions, and nuts adapted to the threaded sections with opposite rotation directions are fixedly connected with the first portion and the second portion, respectively. In this way, approaching/separating between the two parts can be achieved. For example, in order to ensure a more stable approaching/separating movement between the two clamping portions, a second linear guide 425, which is adapted to a second spindle nut mechanism, may be arranged between the first and the second portion.

In one possible embodiment, in order to ensure that the two clamping portions can clamp the silicon rod containing the crystal support more reliably, the first/second portions are formed with clamping structures on sides close to each other, for example, the first/second portions have vertically arranged clamping plates 426 on the portions close to each other, and a plurality of protrusions 427 with buffering function are arranged on the clamping plates, so that the reliability of clamping can be ensured by multi-point clamping. Of course, the protrusion 427 may be directly fixed to the first and second portions. As in the present example, the first/second portions can be mated with a pair of sides of the wafer support, respectively, to clasp a silicon rod containing the wafer support within a clamping space formed by the first and second portions. Illustratively, the clamping plate includes a transverse portion and a vertical portion, the clamping plate being disposed inboard of the vertical portion, and reinforcing structures such as reinforcing ribs, reinforcing plates, etc. being disposed between the transverse portion and the vertical portion.

Referring mainly to fig. 5 to 9, as based on the above-described structure, after the robot arm conveys the silicon rod (in the length direction and the width direction) in place (fig. 5), the slice feeding operation flow for the single cutting chamber mainly includes the following steps:

s11, enabling the AGV to drive the connection tool to move downwards, enabling the extending end of the tail end (the right end in fig. 5) of the strip-shaped structure to move downwards so as to hook the handle of the tail end of the crystal support, and therefore the rear end of the strip-shaped structure is fixedly connected with the silicon rod containing the crystal support.

S12, the first servo motor 412 drives the strip-shaped structure to move (extend) towards the direction of the cutting chamber, so that the whole material (silicon rod containing the crystal support) is pushed out of the connecting tool, and the crystal support enters the feeding guide rail of the slicing machine.

S13, the AGV drives the connection tool to move upwards, so that the extending end at the rear end of the strip-shaped structure moves upwards to leave the handle at the tail end of the crystal support. The first servo motor 412 drives the strip-shaped structure to move (retract) towards the direction of the engagement tool, and the AGV drives the engagement tool to move downwards, so that the extending end of the front end (the left end in fig. 5) of the strip-shaped structure moves downwards, and the extending end of the front end of the strip-shaped structure hooks the handle of the tail end of the crystal support, so that the front end of the strip-shaped structure is fixedly connected with the silicon rod containing the crystal support.

S14, the first servo motor 412 drives the strip structure to move (extend) towards the cutting chamber, so that the strip structure moves (extends) again towards the cutting chamber, and the whole material is pushed into the single cutting chamber.

S15, the AGV drives the connection tool to move upwards, so that the extending end at the front end of the strip-shaped structure moves upwards to leave the handle at the tail end of the crystal support. The first servo motor 412 then drives the bar-like structure to move (retract) into the interior of the engagement tool in a direction toward the engagement tool.

Similarly, still based on the above structure, after the manipulator conveys the silicon rod (in the length direction and the width direction) in place (fig. 10), the dicing and blanking operation flow for the single-machine cutting chamber mainly refers to fig. 10 to 14, and as in the state shown in fig. 14, the strip-shaped structure moves in the direction away from the cutting chamber (gradually into the interior of the joining tool), so that the whole material (silicon rod including the crystal support) is pulled into the space below the joining tool.

It can be seen that the arrangement of the two extending ends of the front end and the tail end of the strip-shaped structure and the cooperation of the strip-shaped structure and the crystal support and the corresponding movement mode thereof are combined, so that the feeding and discharging operation of the single-machine cutting chamber is reliably realized.

In one possible implementation, a rear loading and unloading port may be disposed on a rear wall of the cutting chamber (near a feeding position of the unitized production line), a rear automatic loading and unloading door may be disposed at a position corresponding to the rear loading and unloading port, an automatic loading and unloading auxiliary rail may be disposed between the crystal support and the rear automatic loading and unloading door, and the orientation and structure of the automatic loading and unloading auxiliary rail and the crystal support may be adapted (e.g., the height is approximately level).

In one possible implementation manner, a front-end manual feeding and discharging door can be arranged on the front wall of the cutting chamber, a manual feeding and discharging auxiliary guide rail is arranged between the front-end manual feeding and discharging door and the crystal support, and the direction and structure of the manual feeding and discharging auxiliary guide rail and the crystal support can be adapted (such as the height is approximately level). Therefore, the silicon rod containing the crystal support can be fed through the front end manual feeding and discharging door and the manual feeding and discharging auxiliary guide rail by means of carrying equipment such as a feeding trolley, so that forearm feeding is realized, or the silicon wafer containing the crystal support is discharged after slicing operation is finished. For example, when the slicing machine is used as a minimum unit sold separately, the front-end manual feeding and discharging door can be used for feeding and discharging the slicing machine which is separated from the slicing unitized production line scene. And, if the feeding failure occurs in the slicing unitized production line, the feeding and discharging operation of the corresponding single slicer machine can be realized by means of the front-end feeding and discharging port.

On the one hand, the process of serial connection among the transfer mechanism, the feeding/discharging assembly, the connecting tool and the single machine of a plurality of slicing machines can be realized to unitize and automate slicing operation. On the other hand, the traditional manual feeding and discharging operation in the scene of separating from unitization and automation operation can be realized in a manual feeding and discharging mode. In this way, the single microtome unit as the basic microtome unit in the slicing unitized production line of the present utility model is expected to be sold in a form of an element of a product constituting the production line, or can be sold in a separate form after being directly or through acceptable adjustment (for example, the structural form and the arrangement orientation of a liquid path system, an electric control cabinet, a liquid supply cylinder, etc. are adjusted to an acceptable degree on the premise of being allowed, for example, the restriction set for adapting to the scene of the unitized production line can be removed to a certain extent on the basis of the adjustment, and the microtome unit as the basic microtome unit in the slicing unitized production line of the present utility model is more friendly to adapt to different application scenes according to actual demands, and has good commercial prospects.

Embodiment one:

referring mainly to fig. 15, in one possible embodiment, the slicer 5 includes, in addition to the aforementioned slicer body 51 (including a frame and the like), a cutting chamber 52, a cutting mechanism 53 around which a cutting line is provided and which forms a cutting wire net, a liquid path portion including, for example, a liquid path system 54, a liquid supply cylinder 55, and a cutting liquid charging cart (not shown), and an electric control portion including, for example, an electric control cabinet 57, the main functions of the cutting liquid continuously supplied by the liquid path system including cooling, lubrication, and taking away silicon powder and the like generated at a kerf during slicing operation. As in the present embodiment, the fluid path system includes an inner circulation fluid path unit 541 and an outer circulation fluid path unit 542 which are separately provided, and the electric control cabinet 57 is provided in two according to low pressure and high pressure (e.g., respectively denoted as a low pressure electric control cabinet 571 and a high pressure electric control cabinet 572), and a fluid supply cylinder capable of supplying and recovering the cutting fluid is provided in a bottom space of the fluid path system.

In order to adapt to the necessary coordination of the single microtome, the engagement tool and the transfer mechanism required in the slicing and unitizing production line, in this embodiment, the liquid path system is disposed at the rear side of the cutting chamber, and the inner circulation liquid path unit and the outer circulation liquid path unit are disposed at the rear position of the cutting chamber and on both sides. The low-voltage control cabinet and the high-voltage control cabinet are respectively arranged above the inner circulation liquid path unit and the outer circulation liquid path unit. Therefore, the space between the two electric control cabinets can form a necessary avoiding space for feeding operation from the rear end (the position close to the feeding and discharging opening on the rear end of the single slicer) to the front end (the position close to the AGV layout area), so that the avoiding space for automatic feeding and discharging operation of the single slicer can be formed.

The base of the internal circulation liquid path unit rises to reserve space for the liquid supply cylinder, so that the liquid supply cylinder can be arranged below the internal circulation liquid path unit. Because the dead weight of the high-voltage control cabinet is heavier than that of the low-voltage control cabinet, the base of the external circulation liquid path unit directly falls to the ground. The cutting fluid adding trolley can be arranged on one side close to the external circulation fluid path unit.

It can be understood that, under the premise of ensuring that the slicing machine single machine can be adapted to a slicing unitized operation production line, a person skilled in the art can flexibly adjust elements of the slicing machine single machine and relative positions among the elements according to actual conditions. For example, the single microtome may also be (including but not limited to) the following constitution modes:

embodiment two:

referring mainly to fig. 16, unlike the first embodiment, in this embodiment, the fluid path system and the electric control cabinet are separately disposed at positions behind the cutting chamber and on both sides, and the fluid supply cylinder is disposed at a position between the fluid path system and the electric control cabinet. Therefore, a space between the liquid path system and the electric control cabinet forms an avoidance space capable of ensuring automatic feeding and discharging operation of a single machine of the slicing machine.

Embodiment III:

referring mainly to fig. 17, unlike the second embodiment, in this embodiment, the fluid path system and the electric control cabinet are disposed at one side behind the cutting chamber of the single microtome in a longitudinally stacked manner, wherein the fluid path system is located below the electric control cabinet. The liquid supply cylinder is arranged beside the liquid path system and the electric control cabinet, and has no overlapping or a certain overlapping part with the cutting chamber in space if observed along the automatic feeding and discharging direction. Therefore, the liquid path system and the electric control cabinet are arranged without interference due to the lower height of the liquid supply cylinder, so that the formation of an avoidance space for automatic feeding and discharging operation of a single slicer can be ensured.

Embodiment four:

in this embodiment, the electric control cabinet is adjusted to be a hanging cabinet which is arranged in a hanging manner, so that a space between two liquid path units of the liquid path system forms an avoidance space capable of ensuring automatic feeding and discharging operations of a single machine of the slicing machine. It can be understood that the suspended setting mode and setting position of the hanging cabinet can be arbitrarily selected according to actual requirements.

In the slicing unitized production line of the utility model, the single slicer is better adapted to the production line by making necessary adjustments to the conventional slicer. Based on the above, the silicon rod containing the crystal support before slicing and the silicon wafer containing the crystal support after slicing can be connected between the feeding assembly and the discharging assembly through the configuration of one or more transfer mechanisms such as AGVs. Through the configuration of linking frock, can make the silicon rod before the section and the monocrystalline silicon rod that contains brilliant support after the section can link up between AGV and arbitrary unit in a flexible way smoothly. On the basis, by analyzing the operation of a single machine, the operation between the single machine and the AGV and the operation between the feeding assembly and the discharging assembly, corresponding control logic is provided (such as a group control system comprising field control and remote central control) so as to realize unitized production of slicing operation. On the basis of unitization of slicing operation, the method is expected to better meet the market development requirements of sliced products such as silicon wafers and the like, and better caters to the development trend of the photovoltaic industry.

Thus far, the technical solution of the present utility model has been described in connection with the preferred embodiments shown in the drawings, but it is easily understood by those skilled in the art that the scope of protection of the present utility model is not limited to these specific embodiments. Equivalent modifications and substitutions for related technical features may be made by those skilled in the art without departing from the principles of the present utility model, and such modifications and substitutions will fall within the scope of the present utility model.

Claims (28)

1. A slicing unitized production line, characterized in that the production line comprises:

a production line main body;

at least one microtome disposed on the line body and capable of forming an avoidance space; and

the transfer mechanism at least comprises at least one AGV, and the at least one AGV can carry the workpiece and at least can convey the workpiece to and/or remove the workpiece from the slicer through the avoidance space.

2. The slicing and unitizing production line of claim 1, wherein the production line body is configured with a loading assembly and a blanking assembly,

the transfer mechanism can move between a feeding area corresponding to the feeding assembly and a discharging area corresponding to the discharging assembly; and/or

The transfer mechanism can move in the feeding area and/or the discharging area.

3. The slicing and unitizing production line of claim 2, wherein the relay mechanism is movable toward/away from the slicer at a position between the loading area and the unloading area.

4. The slicing and unitizing production line of claim 1, wherein the relay mechanism is movable in a vertical direction toward/away from the slicer.

5. The slicing unitized production line of claim 1, wherein the production line body is configured with a joining tool, the joining tool can be disposed in the transfer mechanism, and a workpiece can be carried to the joining tool.

6. The slicing unitized production line of claim 5, wherein the engagement tooling comprises:

a first movable portion movable in a direction approaching/separating from a cutting chamber of the microtome, and

at least one butt joint structure capable of fixedly connecting the first movable part with a workpiece is arranged on the first movable part.

7. The slicing unitized production line of claim 6, wherein the workpiece is carried on a wafer carrier, the docking structure being capable of mating with the wafer carrier and thereby effecting a secure attachment of the workpiece to the first movable portion.

8. The slicing and unitizing production line of claim 7, wherein the crystal holder comprises an operating end, and the docking structure is fixedly connected with the crystal holder by extending into the operating end.

9. The slicing and unitizing production line of claim 8, wherein the first movable portion is a strip-like structure having a plurality of the abutting structures disposed thereon along a length thereof.

10. The slicing and unitizing line of claim 9, wherein the strip structure has a first end and a second end,

the strip-shaped structure is provided with the abutting structure at the first end or a position close to the first end, and the strip-shaped structure is provided with the abutting structure at the second end or a position close to the second end.

11. The slicing unitized production line of claim 6, wherein the engagement tooling comprises:

a first driving part capable of driving the first movable part to move in a manner of approaching/separating from the cutting chamber.

12. The slicing unitized production line of claim 11, wherein the engagement tooling comprises:

The first driving part can drive the first movable part to move along a mode of approaching/separating from the cutting chamber through the first lead screw nut mechanism.

13. The slicing unitized production line of claim 6, wherein the engagement tooling comprises:

a carrying portion capable of carrying a workpiece so as to:

in the case of loading a workpiece onto the loading portion, the loading portion and the workpiece move with the movement of the first movable portion.

14. The slicing and unitizing production line of claim 13, wherein the carry-on portion includes a second movable portion,

the second movable portion includes a first portion and a second portion between which relative movement in a direction toward/away from each other can be produced to hug a workpiece.

15. The slicing unitized production line of claim 14, wherein the engagement tooling comprises:

a second drive member capable of driving movement of the first portion and/or the second portion.

16. The slicing unitized production line of claim 15, wherein the engagement tooling comprises:

A second screw-nut mechanism, the screw of which has two threaded sections with opposite screwing directions, the second driving member being capable of driving the first portion and the second portion to move in a manner approaching/moving away from each other by the second screw-nut mechanism.

17. The slicing unitized production line of claim 6, wherein the engagement tooling comprises a tooling base, and the first movable portion is disposed on the tooling base.

18. The slicing and unitizing production line of any one of claims 1 to 17, wherein the slicer comprises:

a microtome body formed with a cutting chamber:

a liquid path portion; and

an electric control part;

wherein the liquid path part and the electric control part are arranged outside the cutting chamber, and

the arrangement mode of the liquid path part and the electric control part can enable the slicing mechanism to create an avoidance space so as to:

the workpiece can realize feeding operation and/or discharging operation through the avoidance space.

19. The slicing unitized production line of claim 18, wherein the electrical control portion comprises a first electrical control cabinet and a second electrical control cabinet, and the first electrical control cabinet and the second electrical control cabinet are arranged in a centralized manner or in a split manner.

20. The slicing and unitizing production line of claim 19, wherein the liquid path portion comprises a liquid path system comprising a first liquid path unit and a second liquid path unit, the first liquid path unit and the second liquid path unit being centrally disposed or separately disposed.

21. The slicing and unitizing production line of claim 20, wherein the fluid circuit portion includes a fluid supply cylinder disposed adjacent to either the first fluid circuit unit or the second fluid circuit unit.

22. The slicing unitized production line of claim 21, wherein the first liquid path unit and the second liquid path unit are disposed on two sides of a cutting chamber of the slicer, and the first electric control cabinet and the second electric control cabinet are disposed above the first liquid path unit and the second liquid path unit, respectively, such that:

and the avoidance space is formed between the first electric control cabinet and the second electric control cabinet.

23. The slicing and unitizing production line of claim 22, wherein a headspace is formed below the first liquid path unit, and the liquid supply cylinder is disposed in the headspace.

24. The slicing unitized production line of claim 21, wherein the first fluid path unit and the second fluid path unit are collectively configured to form a first assembly, the first electrical control cabinet and the second electrical control cabinet are collectively configured to form a second assembly,

the first and second components are disposed on both sides of the cutting chamber and thus form the escape space therebetween.

25. The slicing and unitizing production line of claim 24, wherein the supply cylinder is disposed between the second assembly and the second assembly.

26. The slicing unitized production line of claim 21, wherein the first fluid path unit and the second fluid path unit are collectively configured to form a first assembly, the first electrical control cabinet and the second electrical control cabinet are collectively configured to form a second assembly,

the first component and the second component are arranged on one side of the cutting chamber along the feeding and discharging direction of the workpiece in a longitudinally stacked mode, and therefore an open avoidance space is formed between the cutting chamber and one side.

27. The slicing and unitizing line of claim 26, wherein the supply cylinder is disposed beside a structure formed by the longitudinal stacking of the first and second assemblies, and

And projecting the workpiece to a cutting chamber along the feeding and discharging direction of the workpiece, wherein the cutting chamber and the liquid supply cylinder are at least partially overlapped.

28. The slicing and unitizing production line of claim 21, wherein the first and second electrical cabinets are centrally disposed to form a second assembly, the second assembly being configured in a suspended manner in the cutting chamber.