CN109825862B - Continuous cold oil soaking workstation - Google Patents

Abstract

The utility model provides a continuous immersion cooling oil workstation, including the immersion oil groove, erect the material conveying device and the oily cold machine on the immersion oil groove, the immersion oil groove is including the oil pocket that goes out of two relative settings and set up the oil return chamber between two oil pockets, and material conveying device sets up in the top of oil return pocket, is provided with the oil board between oil pocket and the oil return chamber, goes out the oil pocket and links to each other with the liquid outlet of the oily cold machine, and the oil return pocket links to each other with the inlet of the oily cold machine. The oil enters the oil outlet cavity through the oil cooler, the liquid level in the oil outlet cavity rises and then flows through the oil passing plate to enter the oil return cavity, heat in the oil return cavity enters the oil outlet cavity through heat transfer of the oil passing plate because the oil return cavity is arranged between the two oil outlet cavities, volatilization of the oil caused by too high temperature rising of the oil in the oil return cavity is avoided, the temperature of the oil discharged through the oil passing plate in the oil outlet cavity is higher, convection of the oil in the oil outlet cavity is avoided, solidification of the oil caused by too low temperature of the oil in the oil outlet cavity is avoided, and waste of the oil is reduced by reducing volatilization and solidification of the oil.

Description

Continuous cold oil soaking workstation

Technical Field

The invention relates to electroplating oil immersion equipment, in particular to a continuous cold oil immersion workstation.

Background

Electroplating (Electroplating) is a process of plating a thin layer of other metals or alloys on the surface of some metals by utilizing the electrolysis principle, and is a process of adhering a metal film on the surface of the metal or other material parts by utilizing the electrolysis so as to play roles of preventing the oxidation of the metals, improving the wear resistance, the conductivity, the reflectivity, the corrosion resistance, the beautiful appearance and the like.

In order to avoid oxidation generated after continuous electroplating, oil liquid is coated on the surface of a product to isolate air, and a protective agent in the soaking and cooling process has the characteristics of easy volatilization, solidification and low working temperature (-20 ℃), the temperature of the existing oil soaking workstation is difficult to ensure in the using process, so that the oil liquid volatilizes and solidifies to cause waste of the oil liquid, and the prior art has improvement.

Disclosure of Invention

In order to solve the technical problems, the invention provides a continuous cold oil soaking workstation, which ensures that the temperature of oil meets the working temperature through a special liquid outlet and reflux mode and reduces the waste of the oil.

In order to achieve the above purpose, the technical scheme of the invention is as follows: the utility model provides a continuous immersion cooling oil workstation, is including the immersion oil groove, erect the feeding mechanism on the immersion oil groove and be used for the oily endless oily cold machine, the immersion oil groove is including the oil pocket of two relative settings and set up two return oil chamber between the oil pocket, feeding mechanism sets up the top of return oil pocket, be provided with the oil board between oil pocket and the return oil chamber, the oil pocket with the liquid outlet of oily cold machine links to each other, the return oil chamber with the inlet of oily cold machine links to each other.

Through adopting above-mentioned technical scheme, fluid is carried to the play intracavity through the oil cooler, and the fluid level in the play oil pocket is risen back fluid and is walked the oilplate and get into the oil return intracavity, because the oil return chamber sets up between two play oil pockets, the heat in the oil return intracavity gets into out the oil pocket through the heat transfer of oilplate, avoids the oil temperature in the oil return pocket to rise too fast and leads to the fluid volatilize, and the temperature that goes out the oilplate and go out in the play oil pocket is higher, thereby the fluid in the oil pocket forms the convection current in the oil pocket of going out, thereby avoid the low temperature of oil in the oil pocket and lead to the fluid to solidify, through the waste that reduces the volatilize and the solidification of fluid.

The invention is further provided with: a Y-shaped connecting pipe is arranged between the two oil outlet cavities, and the oil cooler is communicated with the oil outlet cavities through the Y-shaped connecting pipe.

Through adopting above-mentioned technical scheme, the liquid pressure in the Y-shaped connecting pipe is the same, and when the liquid level of one of them goes out the oil pocket is higher than another one and goes out the oil pocket, because the higher oily chamber hydraulic pressure of play of liquid level is higher, behind the Y-shaped connecting pipe received pressure, more fluid flow direction goes to the lower oily chamber of play of liquid level, guarantees that the liquid level of two play oil pockets keeps the parallel and level.

The invention is further provided with: the bottom of the oil outlet cavity is provided with a baffle plate, and the baffle plate is provided with sieve holes.

Through adopting above-mentioned technical scheme, on the one hand, avoid the condensate of fluid to get into the oil pocket that goes out, on the other hand utilizes the effect of interlayer baffle to make the fluid pass through the mesh even and get into the oil pocket that goes out.

The invention is further provided with: the oil return cavity is provided with a plurality of isolation cavities along the conveying direction of the conveying device, a partition plate is arranged between the isolation cavities, and a return port connected with the oil cooler is arranged in the isolation cavity positioned at the starting position of the conveying direction of the conveying device.

Through adopting above-mentioned technical scheme, the isolation chamber liquid level height who has the backward flow mouth is minimum, and the fluid in the isolation chamber all flows towards liquid level height minimum department, and the backward flow mouth sets up in transmission direction's initial position, guarantees that the work piece is gradually immersed in the fluid, reduces the resistance that produces when work piece and liquid level contact in the motion, avoids the work piece to take place deformation.

The invention is further provided with: the partition plate is provided with a communication groove.

Through adopting above-mentioned technical scheme, the fluid in the isolation chamber flows through the intercommunication groove, reduces the loss of fluid.

The invention is further provided with: the oil outlet cavity is provided with a displacement baffle, and the displacement baffle comprises a sliding frame and a sliding block arranged on the sliding frame in a sliding manner.

By adopting the technical scheme, the speed of the oil in the oil outlet cavity entering the oil return cavity is regulated by regulating the positions and the quantity of the sliding blocks on the sliding frame in the use process.

The invention is further provided with: the width of the sliding block is equal to the distance between two adjacent separation plates.

By adopting the technical scheme, a user can conveniently control the oil to enter different isolation cavities by adjusting the position of the sliding block.

The invention is further provided with: the sliding block is arranged in a C shape and is hung on the sliding frame, and the sliding block is connected with a bolt which abuts against the sliding frame in a threaded manner.

Through adopting above-mentioned technical scheme, the setting of slider on the carriage of being convenient for is fixed.

The invention is further provided with: the displacement baffle extends towards one side of the oil passing plate and is provided with a stop block, and the stop block is flush with the upper end of the oil passing plate.

By adopting the technical scheme, the oil can enter the appointed isolation cavity.

The invention is further provided with: the two ends of the sliding frame are provided with clamping grooves for clamping the side walls of the oil outlet cavity, and locking bolts which are in butt joint with the side walls of the oil outlet cavity are connected in the clamping grooves in a threaded mode.

Through adopting above-mentioned technical scheme, the carriage passes through joint groove joint on the play oil cavity to it is fixed through the locking bolt of butt play oil cavity lateral wall, avoid the carriage to take place to rock along self length direction.

In summary, the invention has the following effects:

1. the continuous immersion cooling oil workstation adopts a special liquid outlet mode, so that the liquid level of the oil is stable and accurate, and the product selectivity or local oil sealing is facilitated;

2. the continuous immersion cooling oil workstation has compact structure and small volume, reduces the volume required by oil and reduces the cost input to the maximum extent;

3. the continuous immersion cooling oil workstation has small outline dimension, small application limit, suitability for most continuous electroplating production lines and improvement of equipment utilization rate;

4. the continuous immersion cooling oil workstation has the characteristics of compact structure, fewer parts, stable operation, low failure rate and low maintenance cost in the electroplating production process.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments or the prior art will be briefly described below.

FIG. 1 is a schematic diagram of the overall structure of a continuous immersion oil workstation;

FIG. 2 is a schematic diagram of a connection between a continuous immersion oil workstation and an oil cooler;

FIG. 3 is a schematic illustration of oil flowing in an oil cooler and an oil outlet cavity;

FIG. 4 is a schematic illustration of oil flowing in the oil cooler and the oil return chamber;

fig. 5 is a schematic view of the whole structure of the displacement baffle.

In the figure: 1. an oil cooler; 11. a liquid outlet; 12. a liquid inlet; 13. y-shaped connecting pipes; 2. a material conveying device; 3. an oil immersion tank; 31. an oil outlet cavity; 311. a barrier baffle; 312. a sieve pore; 32. an oil return cavity; 321. an isolation chamber; 322. a partition plate; 323. a communication groove; 324. a return port; 33. an oil passing plate; 34. a displacement baffle; 341. a carriage; 3411. a clamping groove; 342. a slide block; 3421. a stop block; 343. a limit bolt; 344. a locking bolt.

Detailed Description

The invention is described in further detail below with reference to the accompanying drawings.

As shown in fig. 1 and 2, a continuous oil immersion workstation comprises an oil immersion tank 3, a material conveying device 2 arranged on the oil immersion tank 3 and an oil cooler 1 for oil circulation, wherein the oil immersion tank 3 comprises two oppositely arranged oil outlet cavities 31 and an oil return cavity 32 arranged between the two oil outlet cavities 31, the material conveying device 2 is arranged above the oil return cavity 32, an oil passing plate 33 is arranged between the oil outlet cavity 31 and the oil return cavity 32, the oil outlet cavity 31 is connected with a liquid outlet 11 of the oil cooler 1, and the oil return cavity 32 is connected with a liquid inlet 12 of the oil cooler 1; the oil is conveyed into the oil outlet cavity 31 through the oil cooler 1, after the liquid level of the oil in the oil outlet cavity 31 is raised, the oil overflows the oil plate 33 and enters the oil return cavity 32, and the material conveying device 2 drives the product to move on the oil return cavity 32, so that the product is immersed into cold oil.

In order to ensure that the liquid level between the two oil outlet cavities 31 is kept the same, a Y-shaped connecting pipe 13 is arranged between the two oil outlet cavities 31, and the oil cooler 1 is communicated with the oil outlet cavities 31 through the Y-shaped connecting pipe 13; when the liquid level of one oil outlet cavity 31 is higher than the other oil outlet cavity 31, the liquid level of the two oil outlet cavities 31 is kept level because the oil outlet cavity 31 with higher liquid level has higher hydraulic pressure, and more oil flows to the oil outlet cavity 31 with lower liquid level after the Y-shaped connecting pipe 13 receives pressure

As shown in fig. 3 and 4, in order to prevent the oil condensate from entering the oil outlet chamber 31, a baffle plate 311 is disposed at the bottom of the oil outlet chamber 31, and a mesh 312 is disposed on the baffle plate 311.

In order to reduce the resistance generated when the product contacts with the oil, the oil return cavity 32 is provided with a plurality of isolation cavities 321 along the conveying direction of the conveying device 2, a separation plate 322 is arranged between the connected isolation cavities 321, a backflow port 324 connected with the oil cooler 1 is arranged in the isolation cavity 321 positioned at the starting position of the conveying direction of the conveying device 2, and a communication groove 323 for the product and the oil to pass through is formed in the separation plate 322.

Referring to fig. 5, a displacement baffle 34 is disposed on the oil outlet chamber 31, the displacement baffle 34 includes a sliding frame 341 and a sliding block 342 slidably disposed on the sliding frame 341, the sliding block 342 is disposed in a C-shape, and is hung on the sliding frame 341, two ends of the sliding frame 341 are provided with a clamping groove 3411 for clamping the side wall of the oil outlet chamber 31, and a locking bolt 344 is screwed in the clamping groove 3411 and abuts against the side wall of the oil outlet chamber 31; the slider 342 is screwed with a limit bolt 343 abutting against the carriage 341.

In order to improve the blocking effect of the slider 342 on the oil, a stopper 3421 is extended toward the oil passing plate 33 side, and the stopper 3421 is flush with the upper end of the oil passing plate 33.

To facilitate the user's adjustment of the oil entering the designated spacer chamber 321, the width of the slider 342 is equal to the spacing between two adjacent spacer plates 322.

The specific implementation process comprises the following steps:

the oil is conveyed into the oil outlet cavity 31 through the oil cooler 1, the oil is uniformly blocked by the interlayer baffle 311 and enters the oil outlet wall through the sieve holes 312, the oil level in the oil outlet cavity 31 is raised, then the oil overflows the oil plate 33 and enters the oil return cavity 32, the oil return cavity 32 is arranged between the two oil outlet cavities 31, the liquid level of the isolation cavity 321 with the return port 324 in the oil return cavity 32 is lowest, the oil in the isolation cavity 321 flows towards the lowest liquid level, and the return port 324 is arranged at the initial position in the conveying direction, so that workpieces are ensured to be immersed into the oil gradually, the resistance generated when the workpieces contact the liquid level in the motion is reduced, and the workpieces are prevented from deforming;

the heat of the oil in the oil return cavity 32 enters the oil outlet cavity 31 through the heat transfer of the oil passing plate 33, so that the volatilization of the oil caused by the too high temperature rise of the oil in the oil return cavity 32 is avoided, the temperature of the oil in the oil outlet cavity 31 passing through the oil passing plate 33 is higher, and the convection of the oil in the oil outlet cavity 31 is formed in the oil outlet cavity 31, so that the solidification of the oil caused by the too low temperature of the oil in the oil outlet cavity 31 is avoided, and the waste of the oil is reduced by reducing the volatilization and solidification of the oil.

It should be noted that modifications and improvements can be made by those skilled in the art without departing from the inventive concept, and these are all within the scope of the present invention.

Claims (5)

1. The continuous cold oil soaking workstation comprises an oil soaking groove (3), a material conveying device (2) arranged on the oil soaking groove (3) and an oil cooler (1) for oil circulation, and is characterized in that the oil soaking groove (3) comprises an oil outlet cavity (31) which is arranged oppositely and an oil return cavity (32) which is arranged between the two oil outlet cavities (31), the material conveying device (2) is arranged above the oil return cavity (32), an oil passing plate (33) is arranged between the oil outlet cavity (31) and the oil return cavity (32), the oil outlet cavity (31) is connected with a liquid outlet (11) of the oil cooler (1), and the oil return cavity (32) is connected with a liquid inlet (12) of the oil cooler (1);

the oil return cavity (32) is provided with a plurality of isolation cavities (321) along the conveying direction of the conveying device (2), a separation plate (322) is arranged between every two adjacent isolation cavities (321), and a backflow port (324) connected with the oil cooler (1) is arranged in the isolation cavity (321) positioned at the starting position of the conveying direction of the conveying device (2);

the separation plate (322) is provided with a communication groove (323) for products and oil to pass through;

the oil outlet cavity (31) is provided with a displacement baffle (34), and the displacement baffle (34) comprises a sliding frame (341) and a sliding block (342) arranged on the sliding frame (341) in a sliding manner;

the width of the sliding block (342) is equal to the interval between two adjacent separation plates (322);

the sliding block (342) extends towards one side of the oil passing plate (33) to form a stop block (3421), and the stop block (3421) is flush with the upper end of the oil passing plate (33).

2. A continuous oil immersion workstation as claimed in claim 1, characterized in that a Y-shaped connecting pipe (13) is arranged between the two oil outlet cavities (31), and the oil cooler (1) is communicated with the oil outlet cavities (31) through the Y-shaped connecting pipe (13).

3. A continuous immersion oil workstation as claimed in claim 2, characterized in that the bottom of the oil outlet chamber (31) is provided with a barrier baffle (311), and that the barrier baffle (311) is provided with mesh openings (312).

4. A continuous immersion oil workstation according to claim 3, characterized in that the slider (342) is arranged in a C-shape and is hung on the slider (341), and a limit bolt (343) abutting against the slider (341) is connected to the slider (342) in a threaded manner.

5. The continuous immersion oil workstation as recited in claim 4, characterized in that two ends of the sliding frame (341) are provided with a clamping groove (3411) for clamping the side wall of the oil outlet cavity (31), and the clamping groove (3411) is internally and threadedly connected with a locking bolt (344) abutted against the side wall of the oil outlet cavity (31).