CN111304714A - Conveying device for copper bus - Google Patents

Abstract

The invention belongs to the technical field of tinning of copper buses, and particularly relates to a conveying device for copper buses. The conveying device comprises a first rubber wheel and a second rubber wheel, wherein the first rubber wheel is used for conveying a copper bus placed on the first rubber wheel; the conductive rotating shaft is arranged at intervals with the first rubber wheel; and the elastic conductive component is arranged on the conductive rotating shaft and is provided with a plurality of abutting parts which can be close to or far away from the first rubber wheel along with the rotation of the conductive rotating shaft, and the abutting parts can abut against the surfaces of the corresponding copper buses along with the rotation of the conductive rotating shaft. The conveying device is provided with the elastic conductive component, the conveying device is provided with a plurality of abutting parts which can rotate along with the conductive rotating shaft and are close to or far away from the first rubber wheel, and the abutting parts can be in contact with the surfaces of the corresponding copper buses, so that all the copper buses can be simultaneously connected with a power supply, the fixed points are improved into multi-point contact, the uniformity of the thickness of a tin layer is ensured in a tin coating process, and the problems of overhigh local current and blackened surfaces of the copper buses due to poor contact are avoided.

Description

Conveying device for copper bus

Technical Field

The invention belongs to the technical field of tinning of copper buses, and particularly relates to a conveying device for copper buses.

Background

Copper bus (also called copper bus) is a conductive connecting carrier widely used in the industrial fields of electricians, electric power, electricity and the like. The working environment of the copper bus is mostly outdoor or factory workshop, and the environments often have a large amount of water vapor and condensation, so that the copper bus is easy to oxidize and corrode. In order to prevent oxidation of the copper bus bar and to ensure electrical conductivity, the surface or the connecting portion of the copper bus bar is often tin-coated, and a thin layer of tin is uniformly plated on the surface of the copper bus bar.

However, the existing technology for coating tin on the copper bus has the following problems that firstly, the adopted electrolyte has the problem of environmental protection and has larger smell; secondly, the traditional tinning technology mostly adopts static rack plating, the plating efficiency is low, the production speed is slow, and the production line can only produce 1-2t per day; thirdly, the traditional tinning technology cannot carry out full-automatic assembly line production, and the labor intensity of workers is high.

Chinese patent document CN107245750A discloses a copper bar continuous tin plating production line, which comprises a feeding conveying part, a tin plating part and a blanking stacking part arranged from left to right in sequence; the waste gas aspiration channel is installed to tin-plating part upper end, and waste gas aspiration channel is connected and carries out purification treatment with the exhaust-gas treatment tower, and waste water pipeline is installed to tin-plating part's lower extreme, and waste water pipeline and water treatment system are connected and carry out purification treatment. In the patent, a cathode plate is connected to a passive feeding device and allows a passing copper bar to carry a cathode current, the cathode plate is connected with a power supply cathode, and when the copper bar is conveyed, the copper bar is directly conducted and also becomes a cathode; this passive material feeding unit communicates with the cathode plate in tinned whole process, when the copper bar does not carry out tin plating process and carries out other processings, still communicates with the cathode plate, has increased the energy consumption of production line, and the problem of being hindered by the electricity easily appears simultaneously, has reduced the security of operation. In addition, still exist among the prior art, because the copper bar is not absolute leveling, can only contact two points when contacting with the compression roller of circular telegram, easily make the copper bar appear the problem that the surface blackened because of electrically conductive inhomogeneous.

Disclosure of Invention

Therefore, the technical problem to be solved by the invention is to overcome the defects that in the prior art, in the process of tinning the copper bus, the copper bus and the cathode substrate are always communicated in the whole preparation process, so that the energy consumption is increased, the operation safety is poor, the surface of the copper bus is easy to blacken due to uneven conduction, and the like, so that the invention provides the conveying device for the copper bus.

Therefore, the invention provides the following technical scheme.

The invention provides a copper bus conveying device, which comprises,

the first rubber wheel is used for conveying the copper bus placed on the first rubber wheel;

the conductive rotating shaft is arranged at intervals with the first rubber wheel;

and the elastic conductive component is arranged on the conductive rotating shaft and is provided with a plurality of abutting parts which can be close to or far away from the first rubber wheel along with the rotation of the conductive rotating shaft, and the abutting parts can abut against the surfaces of the corresponding copper buses along with the rotation of the conductive rotating shaft.

The elastic conductive component comprises a plurality of conductive elastic sheets which are arranged on the conductive rotating shaft at intervals along the axial direction of the conductive rotating shaft,

the conductive wheel is arranged at the end part of the conductive elastic sheet and used as a butting part.

The conductive rotating shaft is arranged in parallel with the first rubber wheel;

the conductive elastic sheet is vertical to the conductive rotating shaft; and/or the presence of a gas in the gas,

the number of the abutting parts corresponds to the number of the copper buses one by one.

The conductive wheel is filled with conductive fluid;

preferably, the conductive fluid is a low melting point alloy;

preferably, the low melting point alloy is an indium gallium alloy or an indium gallium tin alloy.

The conveying device of the copper bus bar further comprises a conveying device,

the second rubber wheel is fixedly connected to the conductive rotating shaft, can be close to or far away from the first rubber wheel along with the rotation of the conductive rotating shaft, and can be abutted against the surface of the copper bus along with the rotation of the conductive rotating shaft.

The conveying device of the copper bus also comprises a conductive supporting assembly, wherein the conductive supporting assembly comprises a first conductive supporting piece and a second conductive supporting piece, and the two ends of the first conductive supporting piece, which are close to the conductive rotating shaft, are arranged on the conductive rotating shaft and are used for fixing the two ends of the second rubber wheel;

the second conductive supporting piece is connected with and fixed on the first conductive supporting pieces at two ends of the second rubber wheel, and an elastic conductive piece assembly is arranged on the second conductive supporting piece;

preferably, the first conductive support member and the second conductive support member are both conductive metals.

The first conductive support piece is vertical to the conductive rotating shaft;

the second conductive support is perpendicular to the first conductive support.

The conveying device of the copper bus bar further comprises a conveying device,

the first power unit is fixedly connected with the conductive rotating shaft and drives the conductive rotating shaft to rotate through the first power unit;

the power supply is connected with the conductive rotating shaft;

and the second power unit is connected with the first rubber wheel and drives the first rubber wheel to rotate through the second power unit.

Further, the first power unit is a cylinder;

the second power unit is a speed reducing motor, and the speed reducing motor drives the first rubber wheel to rotate through the gears meshed with each other.

Furthermore, electrically conductive shell fragment includes first linkage segment and the second linkage segment that connects gradually, and when butt portion butt in corresponding copper busbar surface, first linkage segment sets up for copper busbar slope, and the second linkage segment is on a parallel with the copper busbar.

The technical scheme of the invention has the following advantages:

1. the invention provides a copper bus conveying device, which comprises a first rubber wheel, a second rubber wheel and a third rubber wheel, wherein the first rubber wheel is used for conveying a copper bus placed on the first rubber wheel; the conductive rotating shaft is arranged at intervals with the first rubber wheel; and the elastic conductive component is arranged on the conductive rotating shaft and is provided with a plurality of abutting parts which can be close to or far away from the first rubber wheel along with the rotation of the conductive rotating shaft, and the abutting parts can abut against the surfaces of the corresponding copper buses along with the rotation of the conductive rotating shaft. The conveying device is provided with the elastic conductive component, the conveying device is provided with a plurality of abutting parts which can rotate along with the conductive rotating shaft and are close to or far from the first rubber wheel, the abutting parts can be in contact with the surfaces of the corresponding copper buses, all the copper buses can be simultaneously connected with a power supply, the fixed points are improved into multi-point contact, the uniformity of the thickness of a tin layer is ensured in a tin coating process, and the problems that in the existing tin coating copper bus process, because the copper buses are not absolutely flat, when an integral compression roller is used for conducting electricity, the actual conductive contact is point contact, each roller can only contact 2 points on the copper buses, poor contact of the copper buses is caused, and the problems that local current is too high and the surfaces are blackened are caused in processing are solved.

2. According to the copper bus conveying device provided by the invention, the abutting part abuts against the surface of the copper bus, so that the copper bus can be connected with the power supply through the upper tin ring section in the tin-coated copper bus process, and the copper bus is disconnected with the power supply after leaving the tin-coated process, so that the copper bus is not electrified any more, the operation safety is improved, the risk of electric injury is reduced, and meanwhile, in the process, the copper bus is not electrified after leaving the device and entering other treatment processes, the consumption of electric energy can be reduced, and the effect of saving electric energy is achieved.

This conveyer of copper bus simple structure, small can guarantee the normal clear of tinning technology, can reduce the risk of being wounded by the electricity again, improve the security of operation, are suitable for popularization and application in the tinning technology of copper bus.

3. The invention provides a copper bus conveying device.A flexible conductive component comprises a plurality of conductive elastic sheets arranged on a conductive rotating shaft at intervals along the axial direction of the conductive rotating shaft and conductive wheels arranged at the end parts of the conductive elastic sheets and used as abutting parts; the conductive elastic sheet has a good buffering effect, reduces damage to the abutting part, and prolongs the service life of the abutting part.

The conductive wheel is internally provided with conductive fluid, and the current is better transmitted to the conductive wheel through the copper shaft of the conductive wheel, so that the mode has the advantages of flexible rotation and high-efficiency conduction.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and other drawings can be obtained by those skilled in the art without creative efforts.

Fig. 1 is a schematic perspective view of a copper busbar conveying device according to embodiment 1 of the present invention;

FIG. 2 is a left side view of a copper busbar transferring apparatus according to embodiment 1 of the present invention;

FIG. 3 is a sectional front view of a copper busbar transferring apparatus according to embodiment 1 of the present invention;

FIG. 4 is a plan view of a copper busbar transfer apparatus according to embodiment 1 of the present invention;

FIG. 5 is a sectional view of a conductive wheel in embodiment 1 of the invention;

fig. 6 is a schematic structural view of a second rubber wheel in embodiment 1 of the present invention;

reference numerals:

1-an end of a conductive shaft; 2-a reduction motor; 3-a gear; 4-a conductive wheel; 5-copper bus bar; 6-conductive elastic sheet; 7-a first rubber wheel; 8-a second rubber wheel; 9-a second electrically conductive support; 10-a first electrically conductive support; 11-a conductive shaft; 12-a cylinder; 13-cylinder gusset plate;

4-1-a conductive fluid; 4-2-a first bearing; 4-3-sealing ring; 4-4-copper shaft; 4-5-a first wheel;

6-1-a first connecting segment; 6-2-a second connecting segment;

8-1-O-shaped ring; 8-2-copper roll shafts; 8-3-conductive fluid; 8-4-second bearing; 8-5-second wheel.

Detailed Description

The following examples are provided to further understand the present invention, not to limit the scope of the present invention, but to provide the best mode, not to limit the content and the protection scope of the present invention, and any product similar or similar to the present invention, which is obtained by combining the present invention with other prior art features, falls within the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

In addition, the technical features involved in the different embodiments of the present invention described below may be combined with each other as long as they do not conflict with each other.

Example 1

This embodiment provides a copper busbar transfer device, as shown in fig. 1-5, comprising,

the first rubber wheel 7 is used for conveying the copper bus 5 placed on the first rubber wheel; meanwhile, the first rubber wheel is connected with a second power unit, the second power unit is a speed reducing motor 2 in the embodiment, and the speed reducing motor drives the first rubber wheel to rotate through gears 3 meshed with each other so as to transmit a copper bus 5 placed on the speed reducing motor;

the conductive rotating shaft 11 is arranged at intervals with the first rubber wheel 7, the end part 1 of the conductive rotating shaft 11 is connected with a power supply, and meanwhile, the conductive rotating shaft 11 is fixedly connected with the first power unit 1 and is driven to rotate by the power unit; in the present embodiment, the first power unit may be the cylinder 1;

the elastic conductive component is arranged on the conductive rotating shaft 11 and is provided with a plurality of abutting parts which can move close to or away from the first rubber wheel 7 along with the rotation of the conductive rotating shaft, and the abutting parts can abut against the surfaces of the corresponding copper buses 5 along with the rotation of the conductive rotating shaft;

among the above-mentioned conveyer, through set up the electrically conductive subassembly of elasticity on conveyer, and this electrically conductive subassembly of elasticity has a plurality of butt portions that can rotate along with electrically conductive pivot and be close to or keep away from first rubber tyer, and this butt portion can with corresponding copper busbar surface contact, can realize that all copper busbars are put through with the power simultaneously, improve to the multiple spot contact by the fixed point, guaranteed the homogeneity of tin layer thickness in last tin technology, in having overcome current last tin copper busbar technology, because the copper busbar is not absolute level and smooth, when electrically conductive with integral compression roller, actual conductive contact is the point contact, every roller can only contact 2 points on the copper busbar, lead to the copper busbar to appear contact failure's problem, lead to processing to appear local current too high, the problem that the surface blackened.

In an optional embodiment, the elastic conductive component includes a plurality of conductive elastic pieces disposed on the conductive rotating shaft at intervals along the axial direction of the conductive rotating shaft, and a conductive wheel disposed at an end of the conductive elastic piece and serving as the abutting portion. For example, as shown in fig. 1, the number of the conductive elastic pieces is 9, the conductive elastic pieces can play a role in buffering, damage to the conductive wheels is reduced, and the conductive wheels are tightly attached to the copper bus by using the deformation force of the conductive elastic pieces, so that a good conductive contact effect is ensured. More specifically, as shown in fig. 5, the conductive wheel includes a copper shaft 4-4 and two corrosion-resistant first bearings 4-2 sleeved on the copper shaft 4-4 near two ends thereof, first rotating wheels 4-5 are fixed on peripheral surfaces of the two first bearings 4-2, a seal ring 4-3 is respectively arranged between the first rotating wheel 4-5 and the copper shaft 4-4 near the two first bearings 4-2, the seal ring 4-3, the copper shaft 4-4 and the first rotating wheel 4-5 enclose a closed space for filling a conductive fluid 4-1, and current sequentially coming from the conductive elastic sheet and the copper shaft 4-4 is transmitted to the first rotating wheel 4-5 through the conductive fluid 4-1 and is finally transmitted to the copper bus through the rotating wheels 4-5; the conductive fluid 4-1 may be a low melting point alloy, such as indium gallium alloy or indium gallium tin alloy, in one embodiment, the conductive fluid 4-1 may be indium gallium alloy with a mass ratio of 14:86, and in another embodiment, the conductive fluid 4-1 may be gallium indium tin alloy with a mass ratio of 68:22: 10.

Of course, the plurality of conductive elastic pieces in the elastic conductive component assembly can be vertically connected to the conductive rotating shaft through a connecting shaft according to the requirement.

In this embodiment, the conductive shaft, the conductive spring, and the conductive wheel may be made of copper, but not limited thereto.

As shown in fig. 1 and 2, the conductive rotating shaft is arranged in parallel with the first rubber wheel; the conductive elastic sheet is perpendicular to the conductive rotating shaft, and through the arrangement, the conductive rotating shaft and the first rubber wheel can synchronously rotate, and the conductive elastic sheet is driven to be close to or far away from the copper bus when the conductive rotating shaft rotates.

The number of butt portion and the number one-to-one of copper bus set up the contact point that has increased copper bus and conductive wheel like this, improved the homogeneity of tin on the copper bus, avoided because the copper bus appears the local electric current too high, problem that the surface blackened.

As a preferred embodiment, the copper bus bar conveying device further includes a second rubber wheel 8, the second rubber wheel is fixedly connected to the conductive rotating shaft 11 and can move close to or away from the first rubber wheel along with the rotation of the conductive rotating shaft 11, and the second rubber wheel 8 can abut against the surface of the copper bus bar 5 along with the rotation of the conductive rotating shaft. In this embodiment, the material of second rubber tyer can be but not be limited to copper, and on second rubber tyer 8 suppressed the copper bus, second rubber tyer 8 and first rubber tyer 7 corresponded to each other, the second rubber tyer not only can play and push down the copper bus and increase frictional force, provides the effect of motion power for the copper bus motion, can also play electrically conductive effect simultaneously, has further guaranteed copper bus and switch on with the power.

In an optional embodiment, as shown in fig. 6, the second rubber wheel includes a copper roller shaft 8-2 and a second bearing 8-4 sleeved on the copper roller shaft and close to two ends of the copper roller shaft, a second runner 8-5 is fixed on the peripheral surface of the bearing, an O-ring 8-1 is respectively arranged between the second bearing 8-4 and the copper roller shaft 8-2 and close to the copper roller shaft, the O-ring 8-1 is used for sealing, the O-ring 8-1, the copper roller shaft 8-2 and the second runner 8-5 enclose a closed space for filling a conductive fluid 8-3, and the current from the copper roller shaft is transmitted to the second runner 8-5 through the conductive fluid and is transmitted to the copper bus 9 through the second runner 8-5; the conductive fluid may be a low melting point alloy, such as indium gallium alloy or indium gallium tin alloy, in one embodiment, the conductive fluid may be indium gallium alloy with a mass ratio of 14:86, and in another embodiment, the conductive fluid may be gallium indium tin alloy with a mass ratio of 68:22: 10. In this embodiment, the current can be better transferred to the copper bus by providing a conductive fluid in the second rubber wheel.

As a most preferred embodiment, as shown in fig. 1 to 4, the conveying device for copper bus bars further comprises a conductive supporting assembly, the conductive supporting assembly comprises a first conductive supporting member 10 and a second conductive supporting member 9, the first conductive supporting member 10 is disposed on the conductive rotating shaft near two ends thereof for fixing two ends of the second rubber wheel 8; the second conductive support member 9 is connected with and fixed on the first conductive support members at the two ends of the second rubber wheel, the elastic conductive member assembly is arranged on the second conductive support member, the first conductive support member is perpendicular to the conductive rotating shaft, the second conductive support member is perpendicular to the first conductive support member, and by arranging the conductive support members, the stress borne by the conductive rotating shaft can be reduced while the conductivity is achieved. In this embodiment, the conductive support member may be, but is not limited to, copper.

Further, two end portions of the second conductive supporting member 9 extend towards the first conductive supporting member 10 to form two spacing segments, and the second conductive supporting member 9 is vertically connected to the first conductive supporting member 10 through the two spacing segments, so that a gap is formed between the second rubber wheel 8 and the conductive elastic sheet 6, and mutual noninterference is realized.

In this embodiment, the conductive rotating shaft 11 and the elastic conductive member assembly are located on the same side of the copper bus bar 5, the first rubber wheel 7 is located on the other side of the copper bus bar 5 and is different from the conductive rotating shaft 11, and the conductive rotating shaft 11 and the first rubber wheel 7 are arranged in parallel.

Optionally, the conductive elastic sheet includes a first connection section 6-1 and a second connection section 6-2 connected in sequence, the conductive elastic sheet 6 is connected with the conductive wheel 4 through the second connection section 6-2, when the conductive wheel abuts against the surface of the corresponding copper bus, the second connection section is parallel to the copper bus, the first connection end is arranged obliquely relative to the copper bus, and the second connection section is parallel to the copper bus, so that the conductive wheel can be guaranteed to better contact the copper bus, and the conductivity is improved.

The working principle of the copper bus bar conveying device is as follows: when the copper bus is placed on the first rubber wheel to start transmission, the cylinder 12 drives the conductive rotating shaft to rotate through the cylinder stress plate 13 after moving, so that the conductive wheel 4 is firstly contacted with the copper bus, then the second rubber wheel presses the copper bus, the conductive wheel has the deformation pressure of the conductive elastic sheet at the moment, the conductive wheel is flatly conducted with the copper bus, the conductive wheel is in large-area contact with the copper bus, and the copper bus is further communicated with a power supply. The second rubber wheel presses the copper bus to increase friction force, and copper bus movement power is provided.

It should be understood that the above examples are only for clarity of illustration and are not intended to limit the embodiments. Other variations and modifications will be apparent to persons skilled in the art in light of the above description. And are neither required nor exhaustive of all embodiments. And obvious variations or modifications of the invention may be made without departing from the spirit or scope of the invention.

Claims (10)

1. A copper bus bar conveying device is characterized by comprising,

the first rubber wheel is used for conveying the copper bus placed on the first rubber wheel;

the conductive rotating shaft is arranged at intervals with the first rubber wheel;

and the elastic conductive component is arranged on the conductive rotating shaft and is provided with a plurality of abutting parts which can be close to or far away from the first rubber wheel along with the rotation of the conductive rotating shaft, and the abutting parts can abut against the surfaces of the corresponding copper buses along with the rotation of the conductive rotating shaft.

2. The copper busbar conveying device according to claim 1, wherein the elastic conductive member assembly includes a plurality of conductive elastic pieces arranged on the conductive rotating shaft at intervals in an axial direction thereof, and,

the conductive wheel is arranged at the end part of the conductive elastic sheet and used as a butting part.

3. The copper busbar transfer device according to claim 2, wherein the conductive rotating shaft is arranged in parallel with the first rubber wheel;

the conductive elastic sheet is vertical to the conductive rotating shaft; and/or the presence of a gas in the gas,

the number of the abutting parts corresponds to the number of the copper buses one by one.

4. The copper busbar transfer device according to claim 2 or 3, wherein the conductive wheel is internally filled with a conductive fluid;

preferably, the conductive fluid is a low melting point alloy;

preferably, the low melting point alloy is an indium gallium alloy or an indium gallium tin alloy.

5. The copper busbar transfer device according to any one of claims 1 to 4, further comprising,

the second rubber wheel is fixedly connected to the conductive rotating shaft, can be close to or far away from the first rubber wheel along with the rotation of the conductive rotating shaft, and can be abutted against the surface of the copper bus along with the rotation of the conductive rotating shaft.

6. The copper busbar conveying device according to claim 5, further comprising a conductive support assembly, wherein the conductive support assembly comprises a first conductive support member and a second conductive support member, the first conductive support member is arranged on the conductive rotating shaft near two ends of the conductive rotating shaft and used for fixing two ends of the second rubber wheel;

the second conductive supporting piece is connected with and fixed on the first conductive supporting pieces at two ends of the second rubber wheel, and an elastic conductive piece assembly is arranged on the second conductive supporting piece;

preferably, the first conductive support member and the second conductive support member are both conductive metals.

7. The copper busbar transfer device according to claim 6, wherein the first conductive support member is perpendicular to the conductive rotating shaft;

the second conductive support is perpendicular to the first conductive support.

8. The copper busbar transfer device according to any one of claims 1 to 3, further comprising,

the first power unit is fixedly connected with the conductive rotating shaft and drives the conductive rotating shaft to rotate through the first power unit;

the power supply is connected with the conductive rotating shaft;

and the second power unit is connected with the first rubber wheel and drives the first rubber wheel to rotate through the second power unit.

9. The copper busbar transfer device according to claim 8, wherein the first power unit is a cylinder;

the second power unit is a speed reducing motor, and the speed reducing motor drives the first rubber wheel to rotate through the gears meshed with each other.

10. The copper busbar conveying device according to claim 2 or 3, wherein the conductive elastic piece comprises a first connecting section and a second connecting section which are connected in sequence, the first connecting section is obliquely arranged relative to the copper busbar when the abutting parts abut against the surfaces of the corresponding copper busbars, and the second connecting section is parallel to the copper busbar.

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