CN215925131U - Titanium blue and titanium blue assembly for film plating machine and film plating machine - Google Patents
Titanium blue and titanium blue assembly for film plating machine and film plating machine Download PDFInfo
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- CN215925131U CN215925131U CN202121477818.4U CN202121477818U CN215925131U CN 215925131 U CN215925131 U CN 215925131U CN 202121477818 U CN202121477818 U CN 202121477818U CN 215925131 U CN215925131 U CN 215925131U
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Abstract
The utility model relates to the technical field of titanium blue, in particular to a titanium blue component for a film plating machine and the film plating machine. The titanium blue comprises a plurality of titanium blue units arranged at intervals along a first direction, soluble coating metal balls are loaded in each titanium blue unit, the plurality of titanium blue units are used for being electrically connected with a power supply of a film coating machine respectively, and the first direction is perpendicular to the film feeding direction. Because the current on the titanium blue is relatively uniform, the thickness of a metal coating formed on the film is relatively uniform when the film enters a film coating machine and is electroplated by the titanium blue.
Description
Technical Field
The utility model relates to the technical field of titanium blue, in particular to a titanium blue component for a film plating machine and the film plating machine.
Background
The titanium blue is made of high-quality TA2 industrial pure titanium, the purity of the titanium reaches 99.7%, the corrosion resistance is strong, and the titanium blue is suitable for various electrolytic baths. Specifically, during the electroplating process, the positive electrode of the power supply is connected to the titanium blue, so that the titanium blue acts as the anode in the electroplating.
In the related art, when the titanium blue works in an electrolytic tank, the electrolytic speed of the electrolyte solution is inconsistent due to the uneven current on the titanium blue, and when a film is plated with copper, the copper plating layer on the surface of the film is uneven, which affects the use stability of the film product.
SUMMERY OF THE UTILITY MODEL
The application discloses a titanium blue, titanium blue subassembly and coating machine for coating machine, because the electric current on this titanium blue is more even, so when the film got into the coating machine and electroplated through this titanium blue, the thickness of the metallic coating that forms on the film also can be more even.
In a first aspect, the application discloses a titanium blue for coating machine, the titanium blue includes along the blue unit of a plurality of titanium that the first direction interval set up, each all load soluble cladding material metal ball in the blue unit of titanium, and a plurality of the blue unit of titanium be used for with coating machine's power is connected electrically respectively, the first direction perpendicular to advances the membrane direction.
Wherein, this titanium blue includes along the blue unit of a plurality of titanium that first direction interval set up, and a plurality of titanium blue unit is connected with the power electricity respectively to reduce the loss of electric current in the transmission course, and then make the electric current size on every titanium blue unit all more even, and make the electric current size on each titanium blue unit more close, the electric current on whole titanium blue this moment also can be more even. When the titanium blue is applied to the film coating machine, the film enters the film coating machine along the film feeding direction and passes through the titanium blue, and the current on the titanium blue is relatively uniform, so that the electrolysis speed of the plating solution in the film coating machine is relatively uniform, and the thickness of a metal coating formed on the film is relatively uniform.
Optionally, a gap is formed between adjacent titanium blue units, and the extending direction of the gap is parallel to the film feeding direction. It can be understood that, because the titanium blue units are arranged along the first direction and the extending direction of the gap is parallel to the film feeding direction, each titanium blue unit is relatively regular, and the titanium blue units are convenient to process and manufacture.
Optionally, a gap is formed between adjacent titanium blue units, and the extending direction of the gap intersects with the film feeding direction. It can be understood that the extending direction of the gap is intersected with the film feeding direction, so that any area on the surface of the film can pass through the titanium blue when the film passes through the titanium blue, and the condition that partial area on the surface of the film does not pass through the titanium blue is avoided, so that a metal coating can be formed on any area on the surface of the thin surface, and the film product is ensured to have better quality.
Further, the titanium blue unit is of a trapezoidal structure.
It can be understood that the first side surface and the second side surface of the titanium blue unit with the trapezoid structure are parallel and are both planar, so that the titanium blue unit is conveniently and electrically connected with a power supply through the first side surface or the second side surface, and the titanium blue units can be arranged tightly, so that the space for installing the titanium blue by a film plating machine is saved.
Furthermore, the part of each titanium blue unit electrically connected with the power supply is positioned on the same side of the titanium blue along the film feeding direction.
It can be understood that the position of each titanium blue unit electrically connected with the power supply is positioned at the same side of the titanium blue along the film feeding direction, so that the wiring of the titanium blue is conveniently arranged at the same side of the titanium blue, the wiring is convenient, and the installation efficiency is convenient to improve.
Furthermore, two opposite sides of each titanium blue unit along the film feeding direction are used for being connected with the power supply.
It can be understood that the current is input to both sides of the titanium blue unit along the film feeding direction, so that the current of the titanium blue unit along the film feeding direction is relatively uniform, and the thickness of a metal coating formed on the film is relatively uniform.
Further, the titanium blue unit is provided with a first side surface and a second side surface which are oppositely arranged along the film feeding direction, the length of the first side surface along the first direction is A, A is more than or equal to 300mm and less than or equal to 350mm, and/or the length of the second side surface along the first direction is B, and B is more than or equal to 300mm and less than or equal to 350 mm.
It can be understood that the length of the first side surface along the first direction is 300mm-350mm, and the length of the second side surface along the first direction is 300mm-350mm, so that the titanium blue unit is not too small on the basis of ensuring that the metal coating formed on the film is relatively uniform, and the processing and manufacturing of the titanium blue unit are facilitated.
Furthermore, the titanium blue also comprises an insulating fixed support, the insulating fixed support comprises a rectangular frame and a plurality of partition plates, the partition plates are arranged in the rectangular frame along the first direction, so that a plurality of accommodating spaces are formed in the rectangular frame, and each accommodating space is embedded with one titanium blue unit.
It can be understood that the titanium blue units are fixed on the insulating fixing bracket, so that the titanium blue is convenient to be integrally installed in a coating machine for use.
Furthermore, the insulating fixed bolster still includes the bottom plate, the bottom plate along the direction of height lid of rectangle frame is established on the rectangle frame to with one side of the open-ended of rectangle frame is blocked.
It can be understood that the titanium blue unit can be supported by the bottom plate and can be fixed by the bottom plate to increase the fixing strength, so that the titanium blue unit can be prevented from falling out of the accommodating space, and the use stability of the titanium blue is increased.
Furthermore, the rectangular frame comprises a first frame edge and a second frame edge which are oppositely arranged along the film feeding direction, the first frame edge and the second frame edge are both made of square tubes, the side wall of the first frame edge, which is close to the titanium blue unit, is provided with a wire passing hole, and/or the side wall of the second frame edge, which is close to the titanium blue unit, is provided with a wire passing hole.
It can be understood that the first frame edge and the second frame edge are made of square tubes, the side wall of the first frame edge close to the titanium blue unit and the side wall of the second frame edge close to the titanium blue unit are provided with wire passing holes, and a lead on one side of the titanium blue unit close to the first frame edge and a lead on one side of the second frame edge can be led into the respective square tubes through the wire holes and then led out from the end faces of the respective square tubes, so that the leads are prevented from being placed on the titanium blue in a disordered manner.
In a second aspect, the present application discloses a titanium blue assembly, which comprises a plurality of titanium blues as described in the first aspect, wherein the plurality of titanium blues are arranged at intervals along the film feeding direction.
It can be understood that the titanium blue component comprises a plurality of titanium blues arranged at intervals along the film feeding direction, so that the film can pass through more titanium blues along the film feeding direction, and the thickness of a metal coating formed on the film can meet the conductive requirement.
Furthermore, a gap is formed between the adjacent titanium blue units, the extending direction of the gap is parallel to the film feeding direction, and the extending directions of the gaps of the adjacent titanium blue units are staggered.
It can be understood that the extending directions of the gaps of the adjacent titanium blues are staggered, so that any area on the surface of the thin film passes through the titanium blues when the thin film passes through the titanium blue assembly, and a metal coating is formed on any area on the surface of the thin surface, so as to ensure that the thin film product has good quality.
In a third aspect, the application discloses a coater comprising the titanium blue assembly of the second aspect.
It can be understood that, when the film passes through the titanium blue component, any area on the surface of the film passes through the titanium blue component, so that a metal coating is formed on any area on the surface of the thin surface, and the thickness of the metal coating formed on the film can better meet the conductive requirement, so that the film coating machine can produce a film product with higher quality.
Furthermore, the film coating machine is used for electroplating the film, and further comprises an unreeling device, an electrolytic tank and a reeling device, wherein the titanium blue components are oppositely arranged and positioned in the electrolytic tank, and the film is conveyed out of the unreeling device, passes through the titanium blue components which are oppositely arranged and is conveyed into the reeling device.
The film is conveyed out of the unwinding device, then enters the electrolytic bath, is electroplated between the titanium blue components which are oppositely arranged, and finally enters the winding device for winding, so that the automatic processing of the film can be realized, and the film coating efficiency is improved.
Drawings
In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to these drawings without creative efforts.
Fig. 1 is a schematic structural view of titanium blue in the related art;
FIG. 2 is a partial enlarged view of the section C in FIG. 1;
FIG. 3 is a schematic structural diagram of a titanium blue in an example of the present application;
FIG. 4 is a schematic structural view of another titanium blue in the examples of the present application;
FIG. 5 is a schematic structural diagram of another titanium blue in the examples of the present application;
FIG. 6 is a schematic diagram of a modified structure based on FIG. 3;
FIG. 7 is a schematic diagram of a modified structure based on FIG. 4;
FIG. 8 is a schematic view of an insulating holder according to an embodiment of the present application;
FIG. 9 is a sectional view taken along line D-D in FIG. 8;
fig. 10 is a schematic view showing a structure in which an insulating fixing bracket is assembled with a titanium blue unit in an embodiment of the present application;
FIG. 11 is a schematic view of another insulating holder according to an embodiment of the present application;
FIG. 12 is a schematic diagram of the structure based on the view E in FIG. 11;
FIG. 13 is a schematic structural view of a titanium blue assembly (with the insulating mounting bracket omitted) in an embodiment of the present application;
FIG. 14 is a schematic structural view of another titanium blue assembly in an embodiment of the present application (with the insulating fixing bracket omitted);
FIG. 15 is a schematic view of a coater according to an embodiment of the present invention;
fig. 16 is a sectional view taken along line F-F in fig. 15.
Reference numerals: 1000-related titanium blue;
1-titanium blue, 11-titanium blue units, 111-a first side face, 112-a second side face, 12-gaps, 13-an insulating fixing support, 131-a rectangular frame, 1311-a first frame edge, 1312-a second frame edge, 1313-wire passing holes, 132-a partition plate, 133-a containing space and 134-a bottom plate;
100-a titanium blue component, 200-an unreeling device, 300-an electrolytic tank, 400-a reeling device and 500-a film;
x-direction of film feeding, Y-first direction.
Detailed Description
The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.
In the present invention, the terms "upper", "lower", "left", "right", "front", "rear", "top", "bottom", "inner", "outer", "center", "vertical", "horizontal", "lateral", "longitudinal", and the like indicate an orientation or positional relationship based on the orientation or positional relationship shown in the drawings. These terms are used primarily to better describe the utility model and its embodiments and are not intended to limit the indicated devices, elements or components to a particular orientation or to be constructed and operated in a particular orientation.
Moreover, some of the above terms may be used to indicate other meanings besides the orientation or positional relationship, for example, the term "on" may also be used to indicate some kind of attachment or connection relationship in some cases. The specific meanings of these terms in the present invention can be understood by those skilled in the art as appropriate.
Furthermore, the terms "mounted," "disposed," "provided," "connected," and "connected" are to be construed broadly. For example, it may be a fixed connection, a removable connection, or a unitary construction; can be a mechanical connection, or an electrical connection; may be directly connected, or indirectly connected through intervening media, or may be in internal communication between two devices, elements or components. The specific meanings of the above terms in the present invention can be understood by those of ordinary skill in the art according to specific situations.
Furthermore, the terms "first," "second," and the like, are used primarily to distinguish one device, element, or component from another (the specific nature and configuration may be the same or different), and are not used to indicate or imply the relative importance or number of the indicated devices, elements, or components. "plurality" means two or more unless otherwise specified.
Before explaining the technical scheme of the present application, an application scenario related to the embodiment of the present application is explained.
Electroplating is the process of plating a layer of other metal or alloy on the surface of some plated parts by using the principle of electrolysis. Specifically, a soluble anode (e.g., titanium blue) is generally used as the plating anode, the workpiece to be plated is used as the cathode, and a liquid containing plating metal ions is used as the plating solution. Before electroplating, the anode and the cathode are electrified, the current forms a loop among the anode, the plating solution and the cathode, and cations of plating metal are reduced on the surface of a workpiece to be plated to form a plating layer in the electroplating process.
The titanium blue is loaded with soluble plating layer metal balls (such as copper balls or chromium balls) as an electroplating anode, and after the power is switched on, the plating layer metal balls in the titanium blue are gradually dissolved and are melted into the plating solution to supplement plating layer metal ions for the plating solution, so that the plating solution has enough plating layer metal ions to meet the electroplating requirement.
In the related art, referring to fig. 1 and 2, in a film plating machine, a plurality of related titanium baskets 1000 are generally arranged along a film feeding direction, a power supply is connected to two side surfaces of each related titanium basket 1000 along a first direction, a film enters the film plating machine along the film feeding direction, and is plated through each related titanium basket 1000. Although the titanium blue 1000 can also be used as a plating anode normally, since the power supply is connected to two side surfaces of the titanium blue 1000 along the first direction, the current will have a certain loss during transmission, and therefore the current on the titanium blue 1000 will gradually decrease from two sides to the middle along the first direction, so that the thickness of the plating layer on the plated film becomes thinner gradually from two sides to the middle along the first direction, that is, the thickness of the plating layer on the film is uneven.
Based on the above, the inventor improves the related titanium blue to solve the problem of uneven thickness of the coating on the film.
The technical solution of the present application will be further described with reference to the following embodiments and accompanying drawings.
Referring to fig. 3, fig. 3 is a schematic structural diagram of a titanium blue in an embodiment of the present application, and a sign "+" in fig. 3 represents a positive electrode of a power supply. Specifically, the application discloses a titanium blue for a film coating machine, wherein the titanium blue 1 comprises a plurality of titanium blue units 11 arranged at intervals along a first direction Y, the plurality of titanium blue units 11 are used for being electrically connected with a power supply (not shown) of the film coating machine respectively, and the first direction Y is perpendicular to a film feeding direction X.
Specifically, when the associated titanium blue 1000 is integral, U is the supply voltage, R1Resistance between the power supply connection of the associated titanium blue 1000 and the power supply, I1For the current between the power supply connection of the associated titanium blue 1000 and the power supply, R2Electricity between the middle of the associated titanium blue 1000 and the power supplyResistance, I2For the current between the middle of the titanium blue 1000 and the power supply, according to the formula I ═ U/R, the larger the resistance is, the smaller the current is, because of R1Less than R2And is thus I1Is greater than I2While R is due to the titanium blue 1000 in question as a whole1And R2The difference between them will be large, so that I1And I2The difference between the two titanium blue units is larger, and the difference between the electrolysis efficiency close to the middle of the related titanium blue 1000 and the electrolysis efficiency far away from the middle of the related titanium blue 1000 is larger, so that the plating layer on the conductive film is uneven, the titanium blue 1 in the embodiment of the application comprises a plurality of titanium blue units 11 arranged at intervals along the first direction Y, the plurality of titanium blue units 11 are respectively electrically connected with a power supply, R3Is the resistance between the power supply connection of each titanium blue cell 11 and the power supply, I3For the current, R, between the power supply connection of each titanium blue cell 11 and the power supply4Resistance between the middle of each Ti blue cell 11 and the power supply, I4For the current between the middle of each ti blue cell 11 and the power supply, the larger the resistance, the smaller the current, since R is known from the formula I ═ U/R3Less than R4And is thus I3Is greater than I4Albeit with I3And I4There will also be a difference between them, but since the resistance of each titanium blue cell 11 is less than the resistance of the associated titanium blue 1000, R will be3And R4Difference between them compared with R1And R2The difference between them will also be small, so that I3And I4Difference of each other is compared with1And I2The difference between the two is also small, the current magnitude of each ti blue unit 11 is relatively close, and the current is relatively uniform throughout the ti blue 1. When the titanium blue 1 is applied to a film coating machine, a film enters the film coating machine along the film feeding direction X and passes through the titanium blue 1, and the current on the titanium blue 1 is relatively uniform, so that the electrolytic speed of a plating solution in the film coating machine is relatively uniform, and the thickness of a metal plating layer formed on the film is relatively uniform.
The titanium blue units 11 are arranged at intervals to prevent the adjacent titanium blue units 11 from contacting, and the titanium blue units 11 are prevented from being communicated with each other, so that each titanium blue unit 11 is independently and electrically connected with a power supply, the current on each titanium blue unit 11 is close to the current on the whole titanium blue 1, and the current on the whole titanium blue 1 is uniform.
It should be noted that, the connection manner of the ti blue unit 11 and the power supply may be that the ti blue unit 11 is welded with one end of a lead (not shown), and then the other end of the lead is electrically connected with the power supply of the film plating machine, so as to complete the electrical connection between the ti blue unit 11 and the power supply; the blue unit 11 of titanium and the power connected mode also can be for welding terminal (not shown) on the blue unit 11 of titanium, be connected the one end of wire and terminal electricity, then the other end of wire and the power of coating machine are connected electrically to accomplish the blue unit 11 of titanium and be connected with the electricity of power, wherein, the setting of terminal, the user of being convenient for fixes the wire through terminal and the blue unit 11 of titanium, can improve the convenience of installation, thereby improve the packaging efficiency. Of course, the titanium blue unit 11 can be connected to the power supply in other ways, and the application is not limited in this respect.
It should be noted that each titanium blue unit 11 is connected to a power supply, specifically, each titanium blue unit 11 is connected to the positive electrode of the power supply, so that the titanium blue 1 serves as a plating anode.
In addition, the titanium blue 1 can be directly installed in a film plating machine for use, and certainly, the titanium blue units 11 can also be fixed together through an insulating fixing bracket, and then the insulating fixing bracket is installed in the film plating machine, so as to improve the assembly efficiency of the film plating machine.
With reference to fig. 3, in some embodiments, a gap 12 is formed between adjacent ti blue units 11, and the extending direction of the gap 12 is parallel to the film feeding direction X. Since the titanium blue units 11 are arranged along the first direction Y and the extending direction of the gap 12 is parallel to the film feeding direction X, each titanium blue unit 11 is relatively regular, for example, the titanium blue units 11 in fig. 3 are all rectangular titanium blue units 11, thereby facilitating the processing and manufacturing of the titanium blue units 11.
In addition, when the size of each titanium blue unit 11 is the same, the titanium blue unit 11 can be generalized, so that the titanium blue unit 11 can be produced in batch, and the production cost is reduced; more importantly, the size of each titanium blue unit 11 is the same, and each titanium blue unit 11 is electrically connected with a power supply, so that the current on each titanium blue unit 11 is closer to or kept consistent, the current on the titanium blue 1 is more uniform, and the thickness of a metal coating formed on the film is more uniform.
Referring to fig. 4, in other embodiments, a gap 12 is formed between adjacent titanium blue units 11, and an extending direction Z of the gap 12 intersects with the film feeding direction X. The film is conveyed in the film coating machine along the film feeding direction X, and if a partial area on the surface of the film does not pass through the titanium blue 1 along the film feeding direction X all the time, no metal coating or less metal coatings are formed on the partial area, so that the quality of a film product is influenced. In this embodiment, the extending direction Z of the gap 12 intersects with the film feeding direction X, that is, the extending direction Z of the gap 12 forms an included angle with the film feeding direction X, so that when the film passes through the titanium blue 1, any area on the surface of the film passes through the titanium blue 1, and a situation that a partial area on the surface of the film does not pass through the titanium blue 1 does not exist, so that a metal coating is formed on any area on the surface of the thin surface, and a film product is ensured to have good quality.
It should be noted that the ti blue unit 11 may have a triangular structure, a parallelogram structure, or a trapezoid structure. Because the triangular structure, the parallelogram structure and the trapezoidal structure are all relatively regular, the titanium blue unit 11 is easy to process, and the production efficiency of the titanium blue 1 can be improved. Of course, the titanium blue unit 11 may also be in other irregular structures, and a user may make the titanium blue unit according to a specific structure or an actual requirement of the device, and the application is not limited in this respect.
When the titanium blue unit 11 has a trapezoid structure, the first side surface 111 and the second side surface 112 (the left side surface and the right side surface in fig. 4) of the titanium blue unit 11 having the trapezoid structure are parallel and planar, so that the titanium blue unit is conveniently electrically connected to a power supply through the first side surface 111 or the second side surface 112. In addition, when a plurality of titanium blues 1 are arranged along the film feeding direction X, the first side surface 111 and the second side surface 112 (the left side surface and the right side surface in the figure 4) are parallel and are both planes, so that the titanium blues 1 can be arranged tightly, the space for installing the titanium blues 1 by the film plating machine is saved, the production cost of the film plating machine can be reduced, and the whole volume of the film plating machine is miniaturized.
Furthermore, the titanium blue unit 11 is provided with a first side surface 111 and a second side surface 112 which are oppositely arranged along the film feeding direction X, the length of the first side surface 111 along the first direction Y is A, and A is more than or equal to 300mm and less than or equal to 350 mm. The length of the first side surface 111 along the first direction Y is 300mm-350mm, so that the titanium blue unit 11 cannot be too small on the basis of ensuring that a metal coating formed on the film is relatively uniform, and the processing and manufacturing of the titanium blue unit 11 are facilitated.
It should be noted that the length of the first side surface 111 along the first direction Y may be 300mm, 305mm, 310mm, 315mm, 320mm, 325mm, 330mm, 335mm, 340mm, 345mm, 350mm, etc., as long as it can ensure that the coating on the film is relatively uniform, the ti blue unit 11 is not too small, which is convenient for the processing and manufacturing of the ti blue unit 11, and the length of the first side surface 111 along the first direction Y is not specifically limited herein.
Further, the length of the second side surface 112 along the first direction Y is B, wherein B is more than or equal to 300mm and less than or equal to 350 mm. The length of the second side surface 112 along the first direction Y is 300mm-350mm, so that the titanium blue unit 11 is not too small on the basis of ensuring that the metal plating formed on the film is relatively uniform, and the processing and manufacturing of the titanium blue unit 11 are facilitated.
It should be noted that the length of the second side surface 112 along the first direction Y may be 300mm, 305mm, 310mm, 315mm, 320mm, 325mm, 330mm, 335mm, 340mm, 345mm, 350mm, etc., as long as it can ensure that the coating on the film is relatively uniform, the ti blue unit 11 is not too small, which is convenient for the processing and manufacturing of the ti blue unit 11, and the length of the second side surface 112 along the first direction Y is not specifically limited herein.
With reference to fig. 4, the portion of each ti blue cell 11 electrically connected to the power supply is located on the same side of the ti blue 1 along the film feeding direction X. The part of each titanium blue unit 11 electrically connected with the power supply is located on the same side of the titanium blue 1 along the film feeding direction X, specifically, the part can be located on the left side of the titanium blue 1 or the right side of the titanium blue 1 in fig. 4, and as the left side of the titanium blue 1 or the right side of the titanium blue 1 is used as the outer side of the titanium blue 1, the length of the wiring can be shorter, and the cost can be saved; in addition, the position of each titanium blue unit 11 electrically connected with the power supply is located on the same side of the titanium blue 1 along the film feeding direction X, so that the wiring of the titanium blue 1 is conveniently arranged on the same side of the titanium blue 1, the wiring is convenient, and the installation efficiency is convenient to improve.
It should be noted that the portion of each ti blue unit 11 electrically connected to the power supply may be located in the middle of the first side surface 111 or in the middle of the second side surface 112, so that the current of each ti blue unit 11 along the first direction Y is relatively uniform, which is convenient for making the thickness of the metal plating layer formed on the film relatively uniform.
It should be noted that the portion of each ti blue cell 11 electrically connected to the power supply may also be located between adjacent ti blue cells 11, but this increases the length of the trace and increases the production cost, and at the same time, the gap 12 between adjacent ti blue cells 11 may also be increased, which is not beneficial to the volume miniaturization of the ti blue 1, so the portion of each ti blue cell 11 electrically connected to the power supply is located on the same side of the ti blue 1 along the film feeding direction X.
Referring to fig. 6 and 7, two opposite sides of each ti blue unit 11 along the film feeding direction X are used for connecting with a power supply. Wherein, the both sides of each titanium blue unit 11 along advancing the relative setting of membrane direction X all are used for being connected with the power, also is that the left side and the right side of each titanium blue unit 11 in figure 6 are used for being connected with the power to all input at the both sides of titanium blue unit 11 along advancing membrane direction X and have the electric current, and then can make titanium blue unit 11 along advancing the electric current of membrane direction X relatively even, be convenient for make the thickness of the metal coating that forms on the film relatively even.
It should be noted that both sides of each ti blue unit 11, which are disposed oppositely along the film feeding direction X, are used for being connected to a power supply, specifically, the middle of the first side surface 111 and the middle of the second side surface 112 are electrically connected to the power supply, so that the current of each ti blue unit 11 along the first direction Y can be relatively uniform, and the current of each ti blue unit 11 along the film feeding direction X can also be relatively uniform, thereby better forming a metal plating layer with uniform thickness on the thin film.
Referring to fig. 8 to 10, the titanium blue 1 further includes an insulating fixing bracket 13, the insulating fixing bracket 13 includes a rectangular frame 131 and a plurality of partition boards 132, the partition boards 132 are arranged in the rectangular frame 131 along the first direction Y to form a plurality of accommodating spaces 133 in the rectangular frame 131, and each accommodating space 133 is embedded with one titanium blue unit 11.
Specifically, by providing the partition plates 132 arranged in the first direction Y between the rectangular frames 131, the partition plates 132 may partition the rectangular frames 131 into a plurality of accommodating spaces 133, which match the shapes and sizes of the titanium blue units 11, so that the titanium blue units 11 may be embedded in the accommodating spaces 133. Because the titanium blue 1 comprises the plurality of titanium blue units 11 arranged along the first direction Y, the plurality of titanium blue units 11 are fixed on the insulating fixing support 13, and the titanium blue 1 is conveniently and integrally installed in the film coating machine for use.
It should be noted that the insulating fixing bracket 13 is made of an insulating material, or is covered with an insulating layer, so that when the plurality of ti blue units 11 are fixed on the insulating fixing bracket 13, the ti blue units 11 are prevented from contacting and communicating with each other, thereby ensuring that each ti blue unit 11 is independently electrically connected with a power supply.
It should be noted that the connection manner between the ti blue unit 11 and the insulating fixing bracket 13 may be, for example, the side surface of the ti blue unit 11 and the side frame body of the rectangular frame 131 are bonded, or of course, the side surface of the ti blue unit 11 and the side frame body of the rectangular frame 131 are fixed by using screws, where fixing the side surface of the ti blue unit 11 and the side frame body of the rectangular frame 131 by using screws is convenient for detaching the ti blue unit 11, so as to facilitate supplementing copper balls or chromium balls to the ti blue unit 11, and a user may set the connection manner according to actual requirements, and the connection manner between the ti blue unit 11 and the insulating fixing bracket 13 is not specifically limited in this application.
In order to better connect each titanium blue unit 11 to the power supply, the present embodiment is further modified with an insulating fixing bracket 13.
In some embodiments, the rectangular frame 131 includes a first frame edge 1311 and a second frame edge 1312 oppositely disposed along the film feeding direction X, the first frame edge 1311 is made of a square tube, and a wire passing hole 1313 is formed in a side wall of the first frame edge 1311 close to the ti blue unit 11, so that a conducting wire on one side of the ti blue unit 11 close to the first frame edge 1311 can be led into the square tube through the wire passing hole 1313 and then led out from an end face of the square tube, and the hidden-type routing structure facilitates accommodating the conducting wire together and prevents the conducting wire from randomly resting on the ti blue unit 1.
In other embodiments, the rectangular frame 131 includes a first frame edge 1311 and a second frame edge 1312 oppositely disposed along the film feeding direction X, the second frame edge 1312 is made of a square tube, and a wire passing hole 1313 is formed in a side wall of the second frame edge 1312 close to the ti blue unit 11, so that a conducting wire on one side of the ti blue unit 11 close to the second frame edge 1312 can be led into the square tube through the wire passing hole 1313 and then led out from an end face of the square tube.
Preferably, the rectangular frame 131 includes a first frame edge 1311 and a second frame edge 1312 oppositely arranged along the film feeding direction X, the first frame edge 1311 and the second frame edge 1312 are made of square tubes, a wire passing hole 1313 is formed on a side wall of the first frame edge 1311 close to the ti blue unit 11, and a wire passing hole 1313 is formed on a side wall of the second frame edge 1312 close to the ti blue unit 11, so that a lead of the ti blue unit 11 close to one side of the first frame edge 1311 and a lead of one side close to the second frame edge 1312 can be led into the respective square tubes through the wire passing holes 1313 and then led out from end faces of the respective square tubes, and the lead is prevented from being randomly placed on the ti blue 1.
Referring to fig. 11 and 12, the insulating fixing bracket 13 further includes a bottom plate 134, and the bottom plate 134 is covered on the rectangular frame 131 along a height direction (a vertical direction in fig. 12) of the rectangular frame 131 to block one side of the opening of the rectangular frame 131.
The bottom plate 134 is covered on the rectangular frame 131 along the height direction of the rectangular frame 131, so that the insulating fixing bracket 13 with only one side open is formed between the bottom plate 134 and the rectangular frame 131, the titanium blue unit 11 can be supported by the bottom plate 134, and the titanium blue unit 11 can also be fixed by means of the bottom plate 134, so as to increase the fixing strength, thereby preventing the titanium blue unit 11 from falling out of the accommodating space 133, and increasing the use stability of the titanium blue 1.
In addition, when the titanium blue 1 is applied to a film plating machine, the titanium blue 1 arranged oppositely is usually installed in the film plating machine, at this time, the film passes through between the titanium blue 1 arranged oppositely, in order that the titanium blue 1 acts on the film better, the opening of the insulating fixing support 13 of the titanium blue 1 is opposite to the film, that is, the bottom plate 134 is opposite to the film, so that the copper balls or chromium balls in the titanium blue 1 are closer to the film, and the film can be plated conveniently.
Referring to fig. 13 and fig. 14, the present embodiment further discloses a titanium blue component 100, where the titanium blue component 100 includes a plurality of titanium blues 1 as described above, and the plurality of titanium blues 1 are disposed at intervals along the film feeding direction X.
The titanium blue component 100 comprises a plurality of titanium blue 1 arranged at intervals along the film feeding direction X, so that the film can pass through more titanium blue 1 along the film feeding direction X, and the thickness of a metal coating formed on the film can meet the conductive requirement. It should be noted that the number of the titanium blue components 100 may specifically include 2, 3, 4, 5, 6, 7, 8, 9, 10, etc., as long as the thickness of the metal plating layer formed on the thin film can satisfy the conductive requirement, and the number of the titanium blue 1 in the titanium blue components 100 is not specifically limited in this application.
In some embodiments, referring to fig. 13, a gap 12 is formed between adjacent ti blue units 11, and the extending direction of the gap 12 is inclined to the film feeding direction X. The extending direction of the gap 12 and the film feeding direction X are obliquely arranged, so that when the film passes through the titanium blue 1, any area on the surface of the film can pass through the titanium blue 1, the condition that partial area on the surface of the film does not pass through the titanium blue 1 is avoided, and a metal coating is formed on any area on the surface of the thin surface, so that the film product is guaranteed to have better quality.
In other embodiments, referring to fig. 14, a gap 12 is formed between adjacent titanium blue units 11, the extending direction of the gap 12 is parallel to the film feeding direction X, and the extending directions of the gaps 12 of adjacent titanium blue 1 are staggered. When the extending direction of the gap 12 is parallel to the film feeding direction X, after the film passes through the first titanium blue 1, the region of the film opposite to the gap 12 may not be plated with a metal coating or form a thinner metal coating, so that the extending directions of the gaps 12 of the adjacent titanium blues 1 are staggered, and when the film passes through the titanium blue component 100, any region on the surface of the film passes through the titanium blue 1, so that any region on the surface of the thin surface may be formed with a metal coating, thereby ensuring that the film product has better quality.
Referring to fig. 15 and 16, the present embodiment further discloses a coater, which includes the titanium blue component 100 described above. When the film 500 passes through the titanium blue component 100, any area on the surface of the film 500 passes through the titanium blue 1, so that a metal coating is formed on any area on the surface of the film 500, and the thickness of the metal coating formed on the film 500 can better meet the conductive requirement, so that the film coating machine can manufacture a film product with higher quality.
Further, the film plating machine further comprises an unwinding device 200, an electrolytic bath 300 and a winding device 400, the titanium blue components 100 are oppositely arranged and are positioned in the electrolytic bath 300, the film 500 is conveyed out of the unwinding device 200, then enters the electrolytic bath 300, is electroplated among the oppositely arranged titanium blue components 100, and finally enters the winding device 400 for winding. It should be noted that the coating machine may further include other devices, such as a film conveying device, a cleaning device, or a film flattening device, and the like, and a user may perform installation according to actual needs, which is not described herein again.
The titanium blue and the titanium blue component for the film plating machine and the film plating machine disclosed by the embodiment of the utility model are introduced in detail, the principle and the implementation mode of the utility model are explained by applying a specific embodiment, and the description of the embodiment is only used for helping to understand the utility model and the core idea thereof; meanwhile, for a person skilled in the art, according to the idea of the present invention, there may be variations in the specific embodiments and the application scope, and in summary, the content of the present specification should not be construed as a limitation to the present invention.
Claims (13)
1. The titanium blue is characterized by comprising a plurality of titanium blue units arranged at intervals along a first direction, soluble coating metal balls are loaded in each titanium blue unit, the plurality of titanium blue units are used for being electrically connected with a power supply of a film coating machine respectively, and the first direction is perpendicular to the film feeding direction.
2. The titanium blue according to claim 1, wherein a gap is formed between adjacent titanium blue units, and the extending direction of the gap is parallel to the film entering direction, or the extending direction of the gap intersects with the film entering direction.
3. The titanium blue according to claim 1, wherein the titanium blue units are of a trapezoidal structure.
4. The titanium blue according to any one of claims 1 to 3, wherein the position where each titanium blue unit is electrically connected with the power supply is located on the same side of the titanium blue along the film feeding direction.
5. The titanium blue according to claim 4, wherein two opposite sides of each titanium blue unit in the film feeding direction are used for connecting with the power supply.
6. The titanium blue according to any one of claims 1 to 3, wherein the titanium blue unit has a first side surface and a second side surface which are oppositely arranged along the film feeding direction, the length of the first side surface along the first direction is A, and is more than or equal to 300mm and less than or equal to 350mm, and/or the length of the second side surface along the first direction is B, and is more than or equal to 300mm and less than or equal to 350 mm.
7. The titanium blue according to any one of claims 1 to 3, further comprising an insulating fixing support, wherein the insulating fixing support comprises a rectangular frame and a plurality of partition plates, the plurality of partition plates are arranged in the rectangular frame along the first direction so as to form a plurality of accommodating spaces in the rectangular frame, and each accommodating space is embedded with one titanium blue unit.
8. The titanium blue according to claim 7, wherein the insulating fixing bracket further comprises a bottom plate which is provided on the rectangular frame in a covering manner in a height direction of the rectangular frame to block one side of the opening of the rectangular frame.
9. The titanium blue according to claim 7, wherein the rectangular frame comprises a first frame edge and a second frame edge which are oppositely arranged along the film feeding direction, the first frame edge and the second frame edge are both made of square tubes, a wire passing hole is formed in the side wall, close to the titanium blue unit, of the first frame edge, and/or a wire passing hole is formed in the side wall, close to the titanium blue unit, of the second frame edge.
10. A titanium blue assembly, comprising: a plurality of titanium blues according to any of the claims 1-9, a plurality of said titanium blues being spaced apart along said film advance direction.
11. The titanium blue assembly according to claim 10, wherein a gap is formed between adjacent titanium blue units, the extending direction of the gap is parallel to the film feeding direction, and the extending directions of the gaps of the adjacent titanium blue units are staggered.
12. A coating machine is characterized by comprising: the titanium blue component of claim 10 or 11.
13. A coater as claimed in claim 12 wherein said coater is adapted to electroplate a film, said coater further comprising an unwind station, an electrolytic bath and a wind-up station, said titanium basket assemblies being positioned opposite one another and in said electrolytic bath, said film passing from said unwind station, between said oppositely positioned titanium basket assemblies and into said wind-up station.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202121477818.4U CN215925131U (en) | 2021-06-30 | 2021-06-30 | Titanium blue and titanium blue assembly for film plating machine and film plating machine |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202121477818.4U CN215925131U (en) | 2021-06-30 | 2021-06-30 | Titanium blue and titanium blue assembly for film plating machine and film plating machine |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CN215925131U true CN215925131U (en) | 2022-03-01 |
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| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN202121477818.4U Active CN215925131U (en) | 2021-06-30 | 2021-06-30 | Titanium blue and titanium blue assembly for film plating machine and film plating machine |
Country Status (1)
| Country | Link |
|---|---|
| CN (1) | CN215925131U (en) |
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2021
- 2021-06-30 CN CN202121477818.4U patent/CN215925131U/en active Active
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Address after: 361100 201-1, complex building 5, No. 11, Butang Middle Road, torch high tech Zone (Tongxiang) industrial base, Xiamen, Fujian Province Patentee after: Xiamen Haichen Energy Storage Technology Co.,Ltd. Address before: 361100 201-1, complex building 5, No. 11, Butang Middle Road, torch high tech Zone (Tongxiang) industrial base, Xiamen, Fujian Province Patentee before: Xiamen Haichen New Energy Technology Co.,Ltd. |