CN219430155U - Energy-saving electrophoresis device for electrophoresis line - Google Patents

Abstract

The utility model discloses an energy-saving electrophoresis device for an electrophoresis line, which comprises a tank body, a liquid suction pipe, a conveying pump, a conveying pipe and a plurality of electrophoresis pipes, wherein the tank body is provided with a liquid suction pipe; the inner walls at the two ends of the groove body in the length direction are inclined structures, and the distance between the inner walls at the two ends of the groove body is gradually increased along the height direction; the electrophoresis tubes are connected into the tank body, and the concentration of the electrophoresis tubes in the tank body is gradually sparse from the middle to the direction close to the inclined plane structure; the liquid outlet of the tank body is connected with the delivery pump through a liquid pumping pipe; the conveying pipe is arranged at the bottom of the tank body and extends along the extending direction of the tank body, a plurality of liquid spraying pipes are connected to the conveying pipe at intervals along the length direction of the conveying pipe, and the liquid spraying pipes are arranged at an acute angle relative to the bottom wall of the tank body, so that the electrophoresis tank liquid in the tank body can perform circulation motion. The method not only eliminates the phenomenon of uneven solid content easily occurring in the electrophoresis tank liquid, thereby improving the uniformity of electrophoresis electrochemical reaction, but also saves energy relatively.

Description

Energy-saving electrophoresis device for electrophoresis line

Technical Field

The utility model relates to the technical field of electrophoresis tanks, in particular to an energy-saving electrophoresis device for an electrophoresis line.

Background

The electrophoresis tank can be used for the section bar to carry out electrophoresis electrochemical reaction, thereby generating an electrophoresis film on the surface of the workpiece so as to improve the comprehensive performance of the surface of the workpiece. And based on the electrophoresis tank being of a long tank structure, the electrophoresis paint is unevenly distributed in the electrophoresis tank, so that the electrophoresis tank liquid can have uneven solid content, and the uniformity of electrophoresis electrochemical reaction is easily reduced. At this time, although uniformity of the electrophoretic electrochemical reaction can be slightly adjusted by setting the concentration of the electrophoretic anode tube or the electrophoretic cathode tube, the efficiency is small and a large power consumption is required to be increased.

Disclosure of Invention

In order to overcome the defects of the prior art, the utility model aims to provide an energy-saving electrophoresis device for an electrophoresis line, which not only eliminates the phenomenon of uneven solid content easily occurring in electrophoresis tank liquid, thereby improving the uniformity of electrophoresis electrochemical reaction, but also saves energy relatively.

The utility model adopts the following technical scheme:

the energy-saving electrophoresis device for the electrophoresis line comprises a tank body, a liquid suction pipe, a conveying pump, a conveying pipe and a plurality of electrophoresis pipes; the inner walls at two ends of the groove body in the length direction are of inclined structures, and the distance between the inner walls at two ends of the groove body is gradually increased along the height direction; the electrophoresis tubes are connected into the tank body, and the concentration of the electrophoresis tubes in the tank body is gradually sparse from the middle to the direction close to the inclined surface structure; the liquid outlet of the tank body is connected with the delivery pump through the liquid suction pipe; the conveyer pipe is located the bottom of cell body, and follows the extending direction of cell body extends, the conveyer pipe is connected with a plurality of hydrojet pipes along self length direction interval, hydrojet pipe's orientation for the diapire of cell body is the acute angle setting, so that electrophoresis tank liquid in the cell body can carry out circulation motion.

Further, the caliber of the conveying pipe is larger than that of an outlet of the conveying pump, and the outlet of the conveying pump is connected with the conveying pipe through a flaring section; the axis of the delivery tube is arranged coaxially with the outlet of the delivery pump.

Further, the conveying pipes are arranged in parallel at intervals along the horizontal direction, and the conveying pumps are respectively connected with the conveying pipes.

Further, the bottom of the tank body is filled with a buried layer, the part, located in the tank body, of the conveying pipe is buried by the buried layer, and the liquid spraying pipe penetrates through the buried layer and leaks into the tank body.

Further, the buried layer is a concrete layer.

Further, the liquid outlet of the tank body is arranged at the top of the tank body.

Further, the liquid outlet of the tank body is arranged right above the conveying pump.

Further, the liquid suction pipe is of a straight pipe structure and is vertically arranged.

Further, the orientation of the liquid spraying pipe is less than or equal to 45 degrees relative to the acute angle A between the bottom walls of the tank body.

Compared with the prior art, the utility model has the beneficial effects that:

1. the inner walls at the two ends in the length direction of the groove body are of inclined structures, and the distance between the inner walls at the two ends of the groove body is gradually increased along the height direction; therefore, the workpiece can slowly enter the electrophoresis tank liquid along with the chain, so as to provide a basic condition for convenient operation of the workpiece.

2. The concentration of the electrophoresis tubes in the groove body is gradually sparse from the middle to the direction close to the inclined plane structure, so that the electrophoresis electrochemical reaction at the position close to the inclined plane structure part is relatively mild, and the electrophoresis electrochemical reaction at the middle part of the groove body is relatively severe, so that the actual situation that the workpiece is not completely immersed in the electrophoresis groove liquid when being positioned in the inclined plane structure is matched, and the waste of electric energy is avoided.

3. Based on the fact that the electrophoresis tank liquid is prone to uneven circulation distribution of the electrophoresis tank liquid when the tank body is large, so that the electrophoresis tank liquid is prone to uneven solid content in the electrophoresis tank liquid, the conveying pipe is arranged at the bottom of the tank body and extends along the extending direction of the tank body, the conveying pipe is connected with a plurality of liquid spraying pipes at intervals along the length direction of the conveying pipe, the orientation of the liquid spraying pipes is arranged at an acute angle relative to the bottom wall of the tank body, and therefore the electrophoresis tank liquid in the tank body can perform circulation motion; that is, the liquid spraying pipes directly act on the bottom of the tank body, so that turbulence phenomenon is promoted, and the solid-liquid mixing of the electrophoresis tank liquid is more balanced, so that the uniformity of the electrophoresis electrochemical reaction is improved. The electrophoresis tank liquid of the tank body is circularly conveyed to the conveying pump through the conveying pump and the liquid suction pipe, namely, the circulation movement of the liquid in the tank body is promoted in an internal circulation mode, so that the arrangement mode is effective and simple.

Drawings

Fig. 1 is a schematic structural view of an energy-saving electrophoresis apparatus for an electrophoresis line according to the present utility model; at this time, the buried layer is not filled;

FIG. 2 is an enlarged view of a portion of FIG. 1 at A;

FIG. 3 is a cross-sectional view of FIG. 1, when the buried layer has been filled; wherein, the broken line in the figure is the path of the circulation of the electrophoresis tank liquid;

FIG. 4 is a partial enlarged view at B of FIG. 3;

FIG. 5 is an effect diagram of the chain of FIG. 3;

fig. 6 is a schematic structural diagram at C of fig. 5.

In the figure: 1. a tank body; 11. a liquid outlet; 12. an inclined plane structure; 2. a liquid suction pipe; 3. a transfer pump; 4. a delivery tube; 5. an electrophoresis tube; 6. a liquid spraying pipe; 7. a flaring section; 8. a buried layer; 9. and (3) a chain.

Detailed Description

The present utility model will be further described with reference to the accompanying drawings and detailed description, wherein it is to be understood that, on the premise of no conflict, the following embodiments or technical features may be arbitrarily combined to form new embodiments.

It will be understood that when an element is referred to as being "fixed to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may be present. The use of "vertical," "horizontal," "left," "right," and similar expressions are for illustrative purposes only and are not meant to be the only embodiment.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this utility model belongs. The terminology used in the description of the utility model herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the utility model. The term "and/or" as used herein includes any and all combinations of one or more of the associated listed items.

Fig. 1 to 4 show an energy-saving electrophoresis apparatus for an electrophoresis line according to a preferred embodiment of the present utility model. The electrophoresis apparatus comprises a tank body 1, an extracting tube 2, a delivery pump 3, a delivery tube 4 and a plurality of electrophoresis tubes 5 (the electrophoresis tubes 5 can be electrophoresis anode tubes or electrophoresis cathode tubes). The inner walls at both ends of the slot body 1 in the length direction are inclined structures 12, and the distance between the inner walls at both ends of the slot body 1 is gradually increased along the height direction. The electrophoresis tubes 5 are connected into the tank body 1, and the concentration of the electrophoresis tubes 5 in the tank body 1 is gradually sparse from the middle to the direction close to the inclined surface structure 12; the liquid outlet 11 of the tank body 1 is connected with the delivery pump 3 through the liquid suction pipe 2; the conveyer pipe 4 is located the bottom of cell body 1 to extend along the extending direction of cell body 1, conveyer pipe 4 is connected with a plurality of hydrojet pipes 6 along self length direction interval, and the orientation of hydrojet pipe 6 is the acute angle setting for the diapire of cell body 1, so that the electrophoresis tank liquid in the cell body 1 can carry out the circulation motion.

Referring to fig. 5 and 6, the chain 9 for conveying the work is constructed to be similar to the contour of the inner wall of the tank 1, i.e., both ends of the chain 9 located in the tank 1 are inclined, and the interval between both ends is gradually increased in the height direction. When the work piece is conveyed into the tank body 1 by the chain 9, the work piece firstly enters the electrophoresis tank liquid obliquely downwards for soaking, then horizontally moves for a certain distance, and then leaves the electrophoresis tank liquid obliquely upwards. During this time, the electric charges carried by the electrophoresis tube 5 and the chain 9 are opposite to each other, so that the electric charges of the work piece and the electrophoresis tank solution are opposite to each other, and the electrophoresis electrochemical reaction is promoted to generate an electrophoresis film on the surface of the work piece. In this embodiment, in order to facilitate insertion of the electrophoresis tube 5 into the tank body 1, the electrophoresis tube 5 has a U-shaped structure and is inserted upside down into the tank body 1.

Importantly, the inner walls at the two ends in the length direction of the tank body 1 are inclined structures 12, and the distance between the inner walls at the two ends of the tank body 1 is gradually increased along the height direction; so that the work piece can follow the chain 9 gently into the bath solution to provide a basic condition for convenient operation of the work piece. The concentration of the electrophoresis tubes 5 in the tank body 1 is gradually sparse from the middle to the direction close to the inclined surface structure 12, so that the electrophoresis electrochemical reaction at the position close to the inclined surface structure 12 is relatively mild, and the electrophoresis electrochemical reaction at the middle part of the tank body 1 is relatively intense, so as to match the actual situation that a workpiece is not completely immersed in the electrophoresis tank liquid when being positioned in the inclined surface structure 12, and avoid wasting electric energy. Based on the fact that the circulation distribution of the electrophoresis tank liquid is uneven when the tank body 1 is large, so that the uneven solid content of the electrophoresis tank liquid is easy to occur in the electrophoresis tank liquid, the conveying pipe 4 is arranged at the bottom of the tank body 1 and extends along the extending direction of the tank body 1, the conveying pipe 4 is connected with a plurality of liquid spraying pipes 6 at intervals along the length direction of the conveying pipe 4, the orientation of the liquid spraying pipes 6 is arranged at an acute angle relative to the bottom wall of the tank body 1, and the electrophoresis tank liquid in the tank body 1 can perform circulation motion; that is, the liquid spraying pipes 6 directly act on the bottom of the tank body 1, so that turbulence phenomenon is promoted, and the solid-liquid mixing of the electrophoresis tank liquid is more balanced, so that the uniformity of the electrophoresis electrochemical reaction is improved. The electrophoresis tank liquid of the tank body 1 is circularly conveyed to the conveying pump 3 through the conveying pump 3 and the liquid suction pipe 2, namely, the circulation movement of the liquid in the tank body 1 is promoted in an internal circulation mode, so that the arrangement mode is effective and simple.

Based on the fact that the outlet aperture of the delivery pump 3 is generally smaller, resulting in a faster flow rate, and the length of the delivery tube 4 is longer, during long distance delivery, the high resistance caused by the high flow rate results in the need to select a delivery pump 3 of high power according to the fluid resistance formula, thereby increasing production costs. Preferably, the caliber of the delivery tube 4 is greater than the caliber of the outlet of the delivery pump 3, the outlet of the delivery pump 3 being connected to the delivery tube 4 by a flared section 7. The arrangement is based on the fact that the caliber of the conveying pipe 4 is larger than that of the outlet of the conveying pump 3, and the outlet of the conveying pump 3 is connected with the conveying pipe 4 through the flaring section 7, so that the speed of the electrophoresis tank liquid is slower when the electrophoresis tank liquid is conveyed in the conveying pipe 4 with a large length, and the power of the conveying pump 3 is allowed to be reduced to reduce the production cost. Further, the axis of the delivery tube 4 is arranged coaxially with the outlet of the delivery pump 3; so that no bending section exists between the delivery pump 3 and the delivery pipe 4, thereby further reducing the fluid resistance, and further reducing the energy consumption, namely further reducing the power of the delivery pump 3 and the production cost.

In order to increase the turbulence degree of the electrophoresis tank liquid in the tank body 1 and thereby further increase the uniformity of the electrophoresis electrochemical reaction, it is preferable that the plurality of transport pipes 4 are provided, and the plurality of transport pipes 4 are arranged in parallel with each other at a spacing in the horizontal direction, and the plurality of transport pipes 4 are connected with respective transport pumps 3, respectively, as seen in fig. 1.

In order to make the resistance to the flow of the liquid at the bottom of the tank body 1 smaller, so as to promote the stability of the circulation movement of the electrophoresis tank liquid; preferably, the bottom of the tank body 1 is filled with a buried layer 8, the part of the conveying pipe 4 located in the tank body 1 is buried by the buried layer 8, and the liquid spraying pipe 6 penetrates through the buried layer 8 and leaks into the tank body 1. The buried layer 8 is preferably a concrete layer, but it is understood that the buried layer 8 may be made of other materials.

Preferably, in order to avoid a reduction in the turbulence level of the solution in the tank 1 during the internal circulation of the electrophoretic tank solution in the tank 1 by the transfer pump 3, the liquid outlet 11 of the tank 1 is provided at the top of the tank 1. So arranged, the liquid outlet 11 is situated farther from the transfer tube 4, so that there is less interference between the two.

Preferably, in order to be able to further reduce the power of the transfer pump 3, the liquid outlet 11 of the tank 1 is provided directly above the transfer pump 3. More preferably, the liquid suction pipe 2 is of a straight pipe structure, and the liquid suction pipe 2 is vertically arranged. In this way, the straight pipe structure has smaller fluid resistance than the bent pipe structure, and the power of the transfer pump 3 can be reduced.

Preferably, in order to enable the liquid spraying tube 6 to generate a circulating motion of the electrophoresis tank liquid, the liquid spraying tube 6 is oriented at an acute angle A which is less than or equal to 45 degrees relative to the bottom wall of the tank body 1, wherein the acute angle A can also be 30 degrees, 15 degrees, 5 degrees and the like.

The above embodiments are only preferred embodiments of the present utility model, and the scope of the present utility model is not limited thereto, but any insubstantial changes and substitutions made by those skilled in the art on the basis of the present utility model are intended to be within the scope of the present utility model as claimed.

Claims (9)

1. An energy-saving electrophoresis device for an electrophoresis line, characterized in that: comprises a tank body (1), a liquid suction pipe (2), a delivery pump (3), a delivery pipe (4) and a plurality of electrophoresis pipes (5); the inner walls at two ends of the groove body (1) in the length direction are inclined structures (12), and the distance between the inner walls at two ends of the groove body (1) is gradually increased along the height direction; the electrophoresis tubes (5) are connected into the tank body (1), and the concentration of the electrophoresis tubes (5) in the tank body (1) is gradually sparse from the middle to the direction approaching the inclined surface structure (12); the liquid outlet (11) of the tank body (1) is connected with the conveying pump (3) through the liquid suction pipe (2); the conveying pipe (4) is arranged at the bottom of the tank body (1) and extends along the extending direction of the tank body (1), the conveying pipe (4) is connected with a plurality of liquid spraying pipes (6) at intervals along the length direction of the conveying pipe, and the direction of the liquid spraying pipes (6) is arranged at an acute angle relative to the bottom wall of the tank body (1) so that the electrophoresis tank liquid in the tank body (1) can perform circulation movement.

2. The energy-efficient electrophoresis apparatus for an electrophoresis line according to claim 1, wherein: the caliber of the conveying pipe (4) is larger than that of an outlet of the conveying pump (3), and the outlet of the conveying pump (3) is connected with the conveying pipe (4) through a flaring section (7); the axis of the delivery tube (4) is arranged coaxially with the outlet of the delivery pump (3).

3. The energy-efficient electrophoresis apparatus for an electrophoresis line according to claim 2, wherein: the conveying pipes (4) are arranged in a plurality, the conveying pipes (4) are arranged at intervals in the horizontal direction and are parallel to each other, and the conveying pipes (4) are respectively connected with the conveying pumps (3).

4. The energy-efficient electrophoresis apparatus for an electrophoresis line according to claim 1, wherein: the bottom of the tank body (1) is filled with a buried layer (8), the part, located in the tank body (1), of the conveying pipe (4) is buried by the buried layer (8), and the liquid spraying pipe (6) penetrates through the buried layer (8) and leaks into the tank body (1).

5. The energy-efficient electrophoresis device for an electrophoresis line according to claim 4, wherein: the buried layer (8) is a concrete layer.

6. The energy-efficient electrophoresis apparatus for an electrophoresis line according to claim 1, wherein: the liquid outlet (11) of the tank body (1) is arranged at the top of the tank body (1).

7. The energy-efficient electrophoresis apparatus for an electrophoresis line according to claim 6, wherein: the liquid outlet (11) of the tank body (1) is arranged right above the conveying pump (3).

8. The energy-efficient electrophoresis apparatus for an electrophoresis line according to claim 7, wherein: the liquid suction pipe (2) is of a straight pipe structure, and the liquid suction pipe (2) is vertically arranged.

9. The energy-efficient electrophoresis apparatus for an electrophoresis line according to claim 1, wherein: the orientation of the liquid spraying pipe (6) is less than or equal to 45 degrees relative to an acute angle A between the bottom walls of the groove body (1).