CN111763918A - Magnetic pipe bending mechanism for target material - Google Patents

Abstract

The invention relates to the technical field of vacuum coating equipment, in particular to a magnetic bent pipe mechanism of a target, which comprises a base, a vacuum bent pipe fitting, an electromagnetic coil, a target liquid cooling fixing assembly and an arc striking assembly, wherein the base is installed at one end of the vacuum bent pipe fitting, the electromagnetic coil is wound on the outer wall of the vacuum bent pipe fitting, the target liquid cooling fixing assembly is used for installing the target and cooling the target, and the arc striking assembly is used for driving the target to generate arc spots. The moving track of the charged sputtered atoms is coincided with the central axis of the vacuum elbow fitting or is arranged in parallel under the action of the electromagnetic field force, the central axis of the vacuum elbow fitting is in a bending arc shape, so that the charged sputtered atoms are sputtered to the surface of a workpiece at a preset position along a specific path, a coating is formed by deposition, flowing cooling liquid is introduced into the target liquid cooling fixing assembly, the target liquid cooling fixing assembly can be rapidly cooled, the target liquid cooling fixing assembly and the target are protected, and the service life of the target liquid cooling fixing assembly is prolonged.

Description

Magnetic pipe bending mechanism for target material

Technical Field

The invention relates to the technical field of vacuum coating equipment, in particular to a magnetic pipe bending mechanism for a target material.

Background

The vacuum coating technology is widely applied to real production life as a technology for generating a specific film layer. Vacuum coating techniques come in three forms, namely evaporation coating, sputter coating and ion plating. Magnetron sputtering can be considered as one of the most prominent achievements in coating technology. The method has the advantages of high sputtering rate, low substrate temperature rise, good film-substrate bonding force, stable device performance, convenient operation and control and the like, and becomes a preferred scheme of the coating industrial application field, in particular to the continuous coating occasions with particularly strict requirements on large-area uniformity, such as architectural coated glass, transparent conductive film glass, flexible substrate winding coating and the like. "sputtering" refers to the phenomenon in which energetic particles bombard a solid surface (target) causing solid atoms or molecules to be ejected from the surface. The ejected particles are mostly in an atomic state, and are often referred to as sputtered atoms. The sputtered particles used to bombard the target can be electrons, ions or neutral particles, and because ions are readily accelerated under an electric field to achieve the required kinetic energy, ions are mostly used as the bombarding particles.

In the prior art, the sputtering path of charged sputtering atoms is difficult to control in the sputtering process, sputtering can be generally realized only along a straight path, the sputtering precision is low, and the coating effect of a workpiece is poor; in addition, in the process of bombarding the target material by positive ions, internal parts in contact with the target material are in an ultrahigh-temperature state and are easily burnt, so that the whole sputtering process fails, the coating of the workpiece fails, and the requirement of modern production cannot be met.

Disclosure of Invention

The technical problem to be solved by the invention is to provide a magnetic pipe bending mechanism for a target, wherein charged sputtering atoms can be sputtered onto the surface of a workpiece at a preset position along a curved path to form a coating by deposition, the sputtering accuracy is high, the target liquid cooling fixing assembly can be rapidly cooled, and the cooling effect is good.

In order to solve the technical problems, the invention adopts the following technical scheme:

the utility model provides a magnetism return bend mechanism of target, its includes the base, the vacuum elbow pipe fitting, solenoid and all install in the fixed subassembly of target liquid cooling and the striking subassembly of base, the base is installed in the one end of vacuum elbow pipe fitting, solenoid is around the outer wall of locating the vacuum elbow pipe fitting, the fixed subassembly of target liquid cooling is used for installing the target and to the target cooling, the striking subassembly is used for ordering about this target and produces the arc spot, the moving trajectory of electrified sputter atom sets up or parallel arrangement with the central axis coincidence of vacuum elbow pipe fitting.

Further, the target liquid cooling fixing assembly comprises a liquid cooling pipe fitting installed on the base, a clamping piece installed at one end of the liquid cooling pipe fitting and a connecting pipe fitting installed at the other end of the liquid cooling pipe fitting, one end, provided with the clamping piece, of the liquid cooling pipe fitting protrudes into the vacuum pipe bending fitting, one end, provided with the connecting pipe fitting, of the liquid cooling pipe fitting is exposed outside the vacuum pipe bending fitting, the clamping piece is provided with a clamping groove, and one end of the target is installed in the clamping groove.

Further, a liquid inlet nozzle and a liquid outlet nozzle are installed on the connecting pipe fitting, the liquid cooling pipe fitting is provided with a liquid inlet channel, a first liquid cooling cavity communicated with the liquid inlet channel, a second liquid cooling cavity communicated with the first liquid cooling cavity and a liquid outlet channel communicated with the second liquid cooling cavity, the liquid inlet nozzle is communicated with the liquid inlet channel, the liquid outlet nozzle is communicated with the liquid outlet channel, the liquid inlet channel is arranged inside the liquid outlet channel, the liquid inlet channel and the liquid outlet channel are coaxially arranged, cooling liquid sequentially flows through the liquid inlet nozzle, the liquid inlet channel, the first liquid cooling cavity, the second liquid cooling cavity, the liquid outlet channel and the liquid outlet nozzle, and a sealing ring is installed between the clamping piece and the liquid cooling.

Furthermore, first liquid cooling chamber is enclosed to establish by holder and liquid cooling pipe fitting and forms, and the centre gripping recess is located one side of holder, and first liquid cooling chamber is located the opposite side of holder.

Furthermore, the target liquid cooling fixing assembly further comprises an insulating cylinder piece, and the insulating cylinder piece is arranged on the outer side of the clamping piece and the outer side of the liquid cooling pipe fitting in a surrounding mode.

Furthermore, the arc striking assembly comprises a driving piece arranged on the base, a rod piece connected with the output end of the driving piece and an arc striking part arranged at one end of the rod piece far away from the driving piece, the arc striking part comprises a supporting end fixed on the rod piece and a bending end integrally formed with the supporting end, and the driving piece is used for driving the bending end to abut against the target material or to be far away from the target material.

Further, vacuum elbow spare includes curved pipe and two straight tubes, and two straight tubes are fixed in the both ends of curved pipe respectively, and the base is installed in the one end that the curved pipe was kept away from to a straight tube, and curved pipe and two straight tubes all are equipped with the intermediate layer cavity, and the intermediate layer cavity of curved pipe communicates each other with the intermediate layer cavity of two straight tubes respectively.

Furthermore, a blocking and filtering component is installed inside the arc-shaped pipe, and the blocking and filtering component is provided with a plurality of baffles.

The invention has the beneficial effects that:

1. the electromagnetic coil is wound on the outer wall of the vacuum elbow pipe fitting, the moving track of charged sputtering atoms is superposed or parallel to the central axis of the vacuum elbow pipe fitting under the action of electromagnetic field force, and the central axis of the vacuum elbow pipe fitting is in a curved arc shape, so that the charged sputtering atoms are sputtered onto the surface of a base material (workpiece) at a preset position along a specific path to form a coating through deposition;

2. in the process of bombarding the target by positive ions, flowing cooling liquid is introduced into the target liquid cooling fixing assembly, so that the target liquid cooling fixing assembly can be rapidly cooled, the target liquid cooling fixing assembly and the target are protected, and the service life of the target liquid cooling fixing assembly is prolonged.

Drawings

Fig. 1 is an overall sectional view of the present invention.

Fig. 2 is a schematic structural diagram of a base, a target liquid-cooling fixing assembly and an arc striking assembly according to the present invention.

Fig. 3 is a schematic structural diagram of a base, a vacuum elbow, a target liquid cooling fixing assembly and an arc striking assembly of the present invention.

Fig. 4 is a cross-sectional view of the target liquid cooling fixture assembly of the present invention.

Detailed Description

In order to facilitate understanding of those skilled in the art, the present invention will be further described with reference to the following examples and drawings, which are not intended to limit the present invention.

As shown in fig. 1 to 4, the magnetic tube bending mechanism for a target provided by the invention includes a base 1, a vacuum tube bending member 2, an electromagnetic coil 3, and a target liquid cooling fixing assembly 4 and an arc striking assembly 5 both mounted on the base 1, the base 1 is mounted at one end of the vacuum tube bending member 2, the electromagnetic coil 3 is wound on an outer wall of the vacuum tube bending member 2, the target liquid cooling fixing assembly 4 is used for mounting a target 28 and cooling the target 28, the arc striking assembly 5 is used for driving the target 28 to generate an arc spot, and a moving track of an electrified sputtering atom is overlapped with or parallel to a central axis of the vacuum tube bending member 2.

The sputtering principle is as follows: firstly, inert gas (usually Ar gas) generates glow discharge phenomenon to generate charged ions, and positive ions (usually Ar +) bombard a cathode (a target made of a deposition material) in a vacuum chamber; the charged ions are accelerated by the electric field and then impact the surface of the target 28, so that target atoms are bombarded and fly out, secondary electrons are generated at the same time, and then impact gas atoms to form more charged ions; the target material atoms carry enough kinetic energy to sputter to the surface of the substrate (workpiece) for deposition to form a coating. After bombardment and collision of high-energy electrons in the plasma region, part of target atoms are ionized, the sputtered target material is not necessarily in a single ion state, usually in a cluster shape, and when passing through the ionization region, if the single atoms are ionized into positive ions, the cluster shape absorbs electrons and carries negative charges.

In practical application, the vacuum elbow pipe fitting 2 is internally vacuumized and filled with inert gas, the target material liquid cooling fixing assembly 4 is connected with a cathode, the arc striking assembly 5 is connected with an arc striking circuit, the arc striking assembly 5 hits the side wall of the target material 28 to generate arc spots, the electromagnetic coil 3 is wound on the outer wall of the vacuum elbow pipe fitting 2, the moving track of charged sputtering atoms is superposed or parallel to the central axis of the vacuum elbow pipe fitting 2 under the action of electromagnetic field force, the central axis of the vacuum elbow pipe fitting is in a curved arc shape, so that the charged sputtering atoms are sputtered onto the surface of a base material (workpiece) at a preset position along a specific path to form a coating through deposition, the sputtering direction and the path of the sputtering atoms are generally not controlled, and the sputtering direction and the path of the charged sputtering atoms can be controlled under the action of the electromagnetic field force; in the process of positive ion bombardment of the target 28, the target liquid cooling fixing component 4 and the target 28 are both in an ultrahigh temperature state, and in order to achieve the cooling effect, the flowing cooling liquid is introduced into the target liquid cooling fixing component 4, so that the target liquid cooling fixing component 4 can be rapidly cooled, the target liquid cooling fixing component 4 and the target 28 are protected, and the service life is prolonged.

In this embodiment, the target liquid cooling fixing assembly 4 includes a liquid cooling pipe fitting 6 installed on the base 1, a clamping member 7 installed at one end of the liquid cooling pipe fitting 6, and a connecting pipe fitting 8 installed at the other end of the liquid cooling pipe fitting 6, wherein one end of the liquid cooling pipe fitting 6 where the clamping member 7 is installed protrudes into the vacuum pipe bending fitting 2, one end of the liquid cooling pipe fitting 6 where the connecting pipe fitting 8 is installed is exposed outside the vacuum pipe bending fitting 2, the clamping member 7 is provided with a clamping groove 9, and one end of the target 28 is installed in the clamping groove 9. Specifically, the connecting pipe fitting 8 is used for connecting an external cooling liquid guiding pipeline, the temperature of the clamping piece 7 is extremely high in the process of bombarding the target material 28 by positive ions, and the liquid cooling pipe fitting 6 is used for guiding flowing cooling liquid to effectively and quickly cool the clamping piece 7, so that the sputtering work is ensured to be normally carried out, and the production efficiency is improved.

In this embodiment, liquid inlet nozzle 10 and liquid outlet nozzle 11 are installed to connecting pipe 8, liquid cooling pipe 6 is equipped with inlet channel 12, first liquid cooling chamber 13 with inlet channel 12 intercommunication, second liquid cooling chamber 14 with first liquid cooling chamber 13 intercommunication and liquid outlet channel 15 with second liquid cooling chamber 14 intercommunication, inlet nozzle 10 and inlet channel 12 intercommunication, liquid outlet nozzle 11 and liquid outlet channel 15 intercommunication, inlet channel 12 sets up inside liquid outlet channel 15, inlet channel 12 and the coaxial setting of liquid outlet channel 15, the coolant liquid flows through inlet nozzle 10 in proper order, inlet channel 12, first liquid cooling chamber 13, second liquid cooling chamber 14, liquid outlet channel 15 and liquid outlet nozzle 11, install sealing washer 16 between holder 7 and the liquid cooling pipe 6. Specifically, first liquid cooling chamber 13 and second liquid cooling chamber 14's shape is cylindrical, and thickness is less, and the bottom surface area is bigger than the thickness promptly, and the effective cooling area to holder 7 can be increaseed in first liquid cooling chamber 13 and second liquid cooling chamber 14's design for the coolant liquid stops the time extension inside liquid cooling pipe fitting 6, and it is effectual to cool down.

In this embodiment, first liquid cooling chamber 13 is enclosed by holder 7 and liquid cooling pipe fitting 6 and establishes and forms, and centre gripping recess 9 is located one side of holder 7, and first liquid cooling chamber 13 is located the opposite side of holder 7. Concretely, after the coolant liquid got into first liquid cooling chamber 13, direct and holder 7 contact, and in order to strengthen the cooling effect, the thickness design of holder 7 between centre gripping recess 9 and the first liquid cooling chamber 13 is less, first liquid cooling chamber 13 and second liquid cooling chamber 14 are through the through-hole intercommunication, the coolant liquid gets into second liquid cooling chamber 14 after getting into first liquid cooling chamber 13 and staying the moment, flow out after second liquid cooling chamber 14 stays the moment, can realize rapid cooling to fixed subassembly 4 of target liquid cooling, protect fixed subassembly 4 of target liquid cooling and target 28, and long service life.

In this embodiment, the target liquid-cooling fixing assembly 4 further includes an insulating cylinder 17, and the insulating cylinder 17 is enclosed outside the clamping member 7 and the liquid-cooling pipe 6. Specifically, the insulating cylinder part 17 is made of ceramic materials, the insulating cylinder part 17 can prevent the arc striking component 5 from being directly punctured, the controllability of the arc striking component 5 and the target liquid cooling fixing component 4 is kept, the arc striking component 5 drives the target 28 to generate arc spots, the target 28 is bombarded by positive ions, and the coating of the base material is completed.

In this embodiment, the arc striking assembly 5 includes a driving member 18 mounted on the substrate 1, a rod member 19 connected to an output end of the driving member 18, and an arc striking component 20 disposed at an end of the rod member 19 away from the driving member 18, the arc striking component 20 includes a supporting end 21 fixed to the rod member 19 and a bending end 22 integrally formed with the supporting end 21, and the driving member 18 is used for driving the bending end 22 to abut against or be away from the target 28. Preferably, the driving member 18 is formed by using an air cylinder or an electric cylinder and then matching with a related conventional transmission mechanism; the rod piece 19 is connected with an arc-leading power supply, the driving piece 18 is used for driving the rod piece 19 to rotate by a preset angle, the bending end 22 is abutted against the target material 28 to generate arc spots, then the driving piece 18 drives the bending end 22 to return, the target material 28 starts to be ablated, namely positive ions start to bombard the target material 28, sputtered target material atoms move along the central axis of the vacuum elbow pipe fitting, the target material atoms are sputtered to the surface of the base material to deposit to form a coating, the coating of the base material is completed, the target material ablation is further controlled by controlling the action of the driving piece 18, and controllability is enhanced.

In this embodiment, vacuum elbow piece 2 includes curved tube 23 and two straight tubes 24, and two straight tubes 24 are fixed in the both ends of curved tube 23 respectively, and two straight tubes 24 all communicate with curved tube 23, and base 1 installs in the one end that curved tube 23 was kept away from to one of them straight tube 24, and curved tube 23 and two straight tubes 24 all are equipped with intermediate layer cavity 25, and the intermediate layer cavity 25 of curved tube 23 communicates each other with the intermediate layer cavity 25 of two straight tubes 24 respectively. Specifically, in the process that target material atoms are sputtered to the surface of the substrate, the vacuum elbow fitting 2 is in a high-temperature state, the interlayer cavity 25 is used for introducing external cooling liquid, the vacuum elbow fitting 2 is cooled, the vacuum elbow fitting 2 is prevented from being burnt by high temperature, the sputtering process inside the vacuum elbow fitting 2 is ensured to be smoothly carried out, the service life is prolonged, and the reliability and the stability are improved. The arc-shaped tube 23 is in a curved arc shape, and the movement locus of charged target material atoms can be further controlled by controlling the distribution of the electromagnetic coil 3 so as to meet the coating requirements of various workpieces.

In this embodiment, the filtering component 26 is installed inside the arced tube 23, and the filtering component 26 includes a plurality of baffles 27. Impurities are mixed in the target material, the shape and the size of the baffle are set according to the characteristics of the impurities according to the stress characteristics of the impurities in an electromagnetic field, and the baffle 27 is used for stopping and filtering the impurities so as to improve the purity of a plating layer of a workpiece and greatly improve the yield.

All the technical features in the embodiment can be freely combined according to actual needs.

The above embodiments are preferred implementations of the present invention, and the present invention can be implemented in other ways without departing from the spirit of the present invention.

Claims (8)

1. The utility model provides a magnetism return bend mechanism of target, includes the base, its characterized in that: the device comprises a base, a vacuum elbow pipe fitting, an electromagnetic coil, a target liquid cooling fixing assembly and an arc striking assembly, wherein the target liquid cooling fixing assembly and the arc striking assembly are all installed on the base, the base is installed at one end of the vacuum elbow pipe fitting, the electromagnetic coil winds the outer wall of the vacuum elbow pipe fitting, the target liquid cooling fixing assembly is used for installing a target and cooling the target, the arc striking assembly is used for driving the target to generate arc spots, and the moving track of charged sputtering atoms is overlapped with the central axis of the vacuum elbow pipe fitting or is arranged in.

2. The magnetic bending mechanism for a target according to claim 1, wherein: the target liquid cooling fixing assembly comprises a liquid cooling pipe fitting installed on the base, a clamping piece installed at one end of the liquid cooling pipe fitting and a connecting pipe fitting installed at the other end of the liquid cooling pipe fitting, one end, provided with the clamping piece, of the liquid cooling pipe fitting protrudes into the vacuum elbow fitting, one end, provided with the connecting pipe fitting, of the liquid cooling pipe fitting is exposed out of the vacuum elbow fitting, and the clamping piece is provided with a clamping groove for clamping a target.

3. The magnetic bending mechanism for a target according to claim 2, wherein: the connecting pipe fitting is provided with a liquid inlet nozzle and a liquid outlet nozzle, the liquid cooling pipe fitting is provided with a liquid inlet channel, a first liquid cooling cavity communicated with the liquid inlet channel, a second liquid cooling cavity communicated with the first liquid cooling cavity and a liquid outlet channel communicated with the second liquid cooling cavity, the liquid inlet nozzle is communicated with the liquid inlet channel, the liquid outlet nozzle is communicated with the liquid outlet channel, the liquid inlet channel is arranged inside the liquid outlet channel, the liquid inlet channel and the liquid outlet channel are coaxially arranged, cooling liquid sequentially flows through the liquid inlet nozzle, the liquid inlet channel, the first liquid cooling cavity, the second liquid cooling cavity, the liquid outlet channel and the liquid outlet nozzle, and a sealing ring is arranged between the clamping piece and the.

4. The magnetic bending mechanism for a target according to claim 3, wherein: the first liquid cooling cavity is formed by surrounding a clamping piece and a liquid cooling pipe fitting, the clamping groove is located on one side of the clamping piece, and the first liquid cooling cavity is located on the other side of the clamping piece.

5. The magnetic bending mechanism for a target according to claim 2, wherein: the target liquid cooling fixing assembly further comprises an insulating cylinder piece, and the insulating cylinder piece is arranged on the outer side of the clamping piece and the outer side of the liquid cooling pipe fitting in a surrounding mode.

6. The magnetic bending mechanism for a target according to claim 1, wherein: the arc striking component comprises a driving piece arranged on the base, a rod piece connected with the output end of the driving piece and an arc striking part arranged at one end of the rod piece far away from the driving piece, the arc striking part comprises a supporting end fixed on the rod piece and a bending end integrally formed with the supporting end, and the driving piece is used for driving the bending end to abut against the target or to be far away from the target.

7. The magnetic bending mechanism for a target according to claim 1, wherein: the vacuum elbow comprises an arc pipe and two straight pipes, wherein the two straight pipes are fixed at two ends of the arc pipe respectively, the base is installed at one end, away from the arc pipe, of one straight pipe, the arc pipe and the two straight pipes are provided with interlayer cavities, and the interlayer cavities of the arc pipe are communicated with the interlayer cavities of the two straight pipes respectively.

8. The magnetic bending mechanism for a target according to claim 7, wherein: the arc-shaped pipe is internally provided with a blocking and filtering component which is provided with a plurality of baffles.

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