CN116499163B

CN116499163B - Solvent oil production device

Info

Publication number: CN116499163B
Application number: CN202310725259.1A
Authority: CN
Inventors: 胡建昌; 张伟华; 韩延伟; 张凯杰; 张聪
Original assignee: Dongying Senbo New Energy Co ltd
Current assignee: Dongying Senbo New Energy Co ltd
Priority date: 2023-06-19
Filing date: 2023-06-19
Publication date: 2023-11-21
Anticipated expiration: 2043-06-19
Also published as: CN116499163A

Abstract

The invention discloses a solvent oil production device, which relates to the technical field of solvent oil production, and has the advantages of being capable of replacing low-temperature cooling liquid and being convenient for cooling the solvent oil, and the technical scheme is as follows: including handling the bucket and setting up inlet tube, first change groove on handling the bucket top, the bottom of handling the bucket is equipped with outlet pipe, the second changes the groove, first change inslot rotation is connected with first communicating pipe, second changes inslot rotation and is connected with the second communicating pipe, be equipped with the cooler that is used for placing solvent oil between first communicating pipe and the second communicating pipe, the top of handling the bucket is equipped with first support, be equipped with the feed liquor pipe on the first support, the top mouth of pipe and the feed liquor pipe intercommunication of first communicating pipe and rather than rotating to be connected, be equipped with the fluid-discharge tube on the second support, the bottom mouth of pipe and the fluid-discharge tube intercommunication of second communicating pipe and rather than rotating to be connected, the inner wall one side of handling the bucket is equipped with temperature sensor, be equipped with on the handling the bucket and be used for driving first communicating pipe pivoted driving piece.

Description

Solvent oil production device

Technical Field

The invention relates to the technical field of solvent oil production, in particular to a solvent oil production device.

Background

Solvent naphtha is one of five major classes of petroleum products. The solvent oil has very wide application. The most used is paint solvent oil (commonly called paint solvent oil), and then is edible oil, printing ink, leather, pesticide, insecticide, rubber, cosmetics, spice, medicine, electronic component and other solvent oils. About 400 to 500 solvents are currently on the market, with about half of the solvent oil (hydrocarbon solvents, benzene compounds) being available. A cooling process is required at the time of solvent oil production.

When the solvent oil is produced, the cooling treatment is needed, the temperature of the cooling liquid is increased due to heat exchange between the solvent oil and the cooling liquid, and the cooling of the solvent oil is affected if the low-temperature cooling liquid cannot be replaced.

Disclosure of Invention

The invention aims to provide a solvent oil production device which has the advantages of being capable of replacing low-temperature cooling liquid and facilitating cooling treatment of solvent oil.

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

the invention provides a solvent oil production device which comprises a treatment barrel, a water inlet pipe and a first rotating groove, wherein the water inlet pipe and the first rotating groove are arranged at the top end of the treatment barrel, the water outlet pipe and the second rotating groove are arranged at the bottom end of the treatment barrel, a first communicating pipe is rotationally connected with the first rotating groove, a second communicating pipe is rotationally connected with the second rotating groove, a cooler for placing solvent oil is arranged between the first communicating pipe and the second communicating pipe, the first communicating pipe and the second communicating pipe are both communicated with the cooler, a first support is arranged at the top end of the treatment barrel, a liquid inlet pipe is arranged on the first support, a top end pipe orifice of the first communicating pipe is communicated with the liquid inlet pipe and is rotationally connected with the liquid inlet pipe, a second support is arranged at the bottom end of the treatment barrel, a liquid outlet pipe orifice of the second communicating pipe is communicated with the liquid outlet pipe and is rotationally connected with the liquid outlet pipe, a temperature sensor is arranged on one side of the inner wall of the treatment barrel, a driving piece for driving the first communicating pipe is arranged on the inner wall of the treatment barrel, and a stop valve is arranged on the water outlet pipe.

Through adopting above-mentioned technical scheme, pour into water or coolant liquid into the processing bucket through the inlet tube, then pour into solvent oil from the feed liquor pipe, solvent oil then can pass through the feed liquor pipe in proper order, first communicating pipe gets into the cooler this moment, then discharge from the fluid-discharge tube through the second communicating pipe from the cooler, when solvent oil is in the cooler, through the water or the coolant liquid in the processing bucket with the cooler carry out the heat exchange, can cool off the solvent oil in the cooler, when solvent oil gets into the cooler, drive first communicating pipe through the driving piece and rotate, first communicating pipe drives the cooler and rotates in the processing bucket this moment, at this moment the cooler then can carry out the disturbance to the water or the coolant liquid in the processing bucket, at this moment can increase the effect of water or the coolant liquid in the processing bucket and the cooler carries out the heat exchange, can detect the temperature of water or the coolant liquid in the processing bucket through temperature sensor, when the temperature of water or the coolant liquid in the processing bucket risees, only need open the stop valve, can be followed to discharge the water or the coolant liquid of high temperature in the processing bucket, then close and can be poured into the low temperature through the low-temperature valve and can the cooling liquid in the processing bucket simply reach the purpose that can be changed.

Preferably, the driving piece comprises a first gear coaxially and fixedly connected to the outer wall of the first communication pipe, the first gear is located above the treatment barrel, an inverted U-shaped mounting frame is arranged at the top end of the treatment barrel, a motor is arranged on the mounting frame, and a second gear meshed with the first gear is arranged at one end of a rotating shaft of the motor.

Preferably, the cooler includes cooling drum and fixed connection be used for sealing the apron of cooling drum bung hole on cooling drum top, the bottom of first communication pipe and the top center fixed connection of apron, at this moment, set up the first intercommunication groove that is used for first communication pipe and cooling drum intercommunication on the apron, the top of second communication pipe and the bottom center fixed connection of cooling drum, the second intercommunication groove that is used for communicating second communication pipe and cooling drum is seted up to the bottom of cooling drum, coaxial a plurality of separation dishes that are equipped with in the cooling drum, and each separation dish all follow the vertical direction of cooling drum from last down interval distribution, each the recess dislocation distribution on the separation dish is all seted up on the top, and adjacent two separation dishes.

Preferably, the cooling barrel is internally and coaxially provided with a baffle disc for dividing the cooling barrel into a first area and a second area, the first area is positioned above the second area, the outer wall of the cooling barrel is provided with U-shaped dispersing pipes, pipe openings at two ends of each dispersing pipe are respectively communicated with the first area and the second area, the separation discs are respectively positioned in the first area and are respectively positioned above the dispersing pipes, at the moment, the first communication pipes are communicated with the first area, the second communication pipes are communicated with the second area, the dispersing pipes are in a plurality, and all dispersing pipes are uniformly distributed along the circumference of the baffle disc.

Preferably, the inner wall of the treatment barrel is connected with a movable plate in a vertical sliding manner, the temperature sensor is arranged on the movable plate, and when the cooling barrel rotates, a driving piece for driving the movable plate to vertically move up and down is arranged on the cooling barrel and is positioned above the dispersing pipe.

Preferably, the driving piece comprises two annular grooves which are obliquely arranged on the outer wall of the cooling barrel, the two annular grooves are distributed up and down, one ends of the two annular grooves are intersected and communicated, a connecting column is horizontally arranged at one end of the moving plate, which is close to the cooling barrel, and an oval block located in one annular groove is rotationally connected with one end, which is far away from the moving plate, of the connecting column.

Preferably, the cooler comprises a spiral conduit arranged between the first communicating pipe and the second communicating pipe, pipe orifices at two ends of the spiral conduit are respectively communicated with the first communicating pipe and the second communicating pipe, a placing plate is vertically connected with one side of the inner wall of the treatment barrel in a sliding manner, the temperature sensor is arranged on the placing plate, when the spiral conduit rotates, the spiral conduit is connected with the placing plate through a transmission piece, and the transmission piece is used for driving the placing plate to vertically move up and down.

Preferably, the transmission member includes a horizontal column horizontally disposed on a side of the placement plate near the spiral duct, and an end of the horizontal column remote from the placement plate extends into the spiral duct, where the end of the horizontal column is located between the upper and lower opposite sides of the outer wall of the spiral duct.

Preferably, the horizontal column is coaxially and rotatably connected with a rotary drum, and two opposite sides of the outer wall of the spiral conduit are contacted with the outer wall of the rotary drum.

Preferably, the bottom mouth of pipe intercommunication of outlet pipe has the hose, and the one end that the hose kept away from the outlet pipe is equipped with the liquid reserve tank, one side of liquid reserve tank is equipped with the bin, and communicates through the connecting pipe between bin and the liquid reserve tank, be equipped with the valve on the connecting pipe, all be equipped with the suction pump on connecting pipe, the hose.

The invention has the beneficial effects that: the water or the cooling liquid is injected into the treatment barrel through the water inlet pipe, then the solvent oil is injected from the liquid inlet pipe, at the moment, the solvent oil sequentially enters the cooler through the liquid inlet pipe and the first communication pipe, then the solvent oil is discharged from the liquid outlet pipe through the second communication pipe, when the solvent oil is positioned in the cooler, the solvent oil in the cooler can be cooled through heat exchange between the water or the cooling liquid in the treatment barrel and the cooler, when the solvent oil enters the cooler, the first communication pipe is driven to rotate through the driving piece, at the moment, the first communication pipe drives the cooler to rotate in the treatment barrel, at the moment, the cooler can disturb the water or the cooling liquid in the treatment barrel, at the moment, the heat exchange effect between the water or the cooling liquid in the treatment barrel and the cooler can be increased, the temperature of the water or the cooling liquid in the treatment barrel can be detected through the temperature sensor, when the temperature of the water or the cooling liquid in the treatment barrel is increased, at the moment, the high-temperature water or the cooling liquid in the treatment barrel can be discharged from the water outlet pipe through the heat exchange valve only by opening the stop valve, and then the water or the cooling liquid can be simply replaced through the water inlet pipe or the cooling liquid in the treatment barrel.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, it being obvious that the drawings in the following description are only some embodiments of the invention, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic structural view of the present embodiment;

fig. 2 is a schematic structural view of a dispersion tube according to the present embodiment;

fig. 3 is a schematic structural view showing a cooling tub of the present embodiment;

fig. 4 is a schematic structural view of the mobile plate according to the present embodiment;

fig. 5 is a schematic structural view of the second bracket according to the present embodiment;

FIG. 6 is a schematic view of the structure of the present embodiment for embodying a spiral catheter;

fig. 7 is a schematic structural diagram of the storage box according to the present embodiment.

Reference numerals illustrate:

in the figure: 1. a treatment barrel; 2. a water inlet pipe; 3. a first rotating groove; 4. a water outlet pipe; 5. a second rotary groove; 6. a first communication pipe; 7. a second communicating pipe; 8. a first bracket; 9. a liquid inlet pipe; 10. a second bracket; 12. a liquid discharge pipe; 13. a temperature sensor; 14. a stop valve; 15. a first gear; 16. a mounting frame; 17. a motor; 18. a second gear; 19. a cooling barrel; 20. a cover plate; 21. a first communication groove; 22. a second communication groove; 23. a separation plate; 24. a groove; 25. a baffle disc; 26. a dispersion tube; 27. a moving plate; 28. an annular groove; 29. a connecting column; 30. an oval block; 31. a spiral catheter; 32. placing a plate; 33. a horizontal column; 34. a rotating drum; 35. a hose; 36. a liquid storage tank; 38. a storage tank; 39. a connecting pipe; 40. a valve; 41. a water pump; 42. a first zone; 43. a second region.

Description of the embodiments

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

The utility model provides a solvent oil's apparatus for producing, as in fig. 1 and 2, including handling bucket 1 and the inlet tube 2 of setting on handling bucket 1 top, first rotary tank 3, the bottom of handling bucket 1 is equipped with outlet pipe 4, second rotary tank 5, first rotary tank 3 internal rotation is connected with first communicating pipe 6, second rotary tank 5 internal rotation is connected with second communicating pipe 7, be equipped with the cooler that is used for placing solvent oil between first communicating pipe 6 and the second communicating pipe 7, and first communicating pipe 6, second communicating pipe 7 all communicates with the cooler, the top of handling bucket 1 is equipped with first support 8, and be equipped with feed liquor pipe 9 on the first support 8, the top mouth of pipe and the feed liquor pipe 9 intercommunication of first communicating pipe 6 are connected rather than rotating, the bottom of handling bucket 1 is equipped with second support 10, and be equipped with fluid-discharge tube 12 on the second support 10, the bottom mouth of pipe and fluid-discharge tube 12 intercommunication and rather than rotating connection of second communicating pipe 5 internal wall one side of handling bucket 1 are equipped with temperature sensor 13, be equipped with the outlet pipe 14 that is used for driving first communicating pipe 6 pivoted on handling bucket 1, be equipped with stop valve on 4.

As shown in fig. 1 and 2, water or cooling liquid is injected into the treatment barrel 1 through the water inlet pipe 2, then solvent oil is injected from the liquid inlet pipe 9, at this time, the solvent oil sequentially passes through the liquid inlet pipe 9 and the first communication pipe 6 to enter the cooler, then is discharged from the liquid discharge pipe 12 through the second communication pipe 7, when the solvent oil is positioned in the cooler, the solvent oil in the cooler can be subjected to cooling treatment through heat exchange between the water or cooling liquid in the treatment barrel 1 and the cooler, when the solvent oil enters the cooler, the first communication pipe 6 is driven by the driving piece to rotate, at this time, the first communication pipe 6 drives the cooler to rotate in the treatment barrel 1, at this time, the cooler can disturb the water or cooling liquid in the treatment barrel 1, at this time, the effect of heat exchange between the water or cooling liquid in the treatment barrel 1 and the cooler can be increased, the temperature of the water or cooling liquid in the treatment barrel 1 can be detected through the temperature sensor 13, when the temperature of the water or cooling liquid in the treatment barrel 1 rises, the water or cooling liquid in the treatment barrel 1 only needs to be subjected to cooling treatment by opening the stop valve 14, the water or cooling liquid in the treatment barrel 1 can be discharged from the water or cooling liquid through the water outlet pipe 14, and the cooling liquid can be conveniently replaced by simply or cooling water in the treatment barrel 2.

As shown in fig. 1 and 2, the driving member includes a first gear 15 coaxially and fixedly connected to the outer wall of the first communication pipe 6, the first gear 15 is located above the processing barrel 1, an inverted U-shaped mounting frame 16 is provided at the top end of the processing barrel 1, a motor 17 is provided on the mounting frame 16, a second gear 18 meshed with the first gear 15 is provided at one end of a rotation shaft of the motor 17, and this is intended to simply and conveniently use when the first communication pipe 6 needs to be driven to rotate, the motor 17 is only required to be opened, and the rotation shaft of the motor 17 drives the second gear 18 to rotate, and the second gear 18 can drive the first communication pipe 6 to rotate through the first gear 15 meshed with the second gear 18.

As shown in fig. 2 and 3, the cooler includes cooling barrel 19 and fixed connection is used for closing the apron 20 of cooling barrel 19 bung hole on cooling barrel 19 top, the bottom of first communication pipe 6 and the top center fixed connection of apron 20, set up the first intercommunication groove 21 that is used for communicating first communication pipe 6 and cooling barrel 19 on the apron 20 this moment, the top of second communication pipe 7 and the bottom center fixed connection of cooling barrel 19, the second intercommunication groove 22 that is used for communicating second communication pipe 7 and cooling barrel 19 is seted up to the bottom of cooling barrel 19, be equipped with a plurality of separation discs 23 in the cooling barrel 19 coaxially, and each separation disc 23 is all along the vertical direction of cooling barrel 19 from last down interval distribution, recess 24 has all been seted up on each separation disc 23's top, and the dislocation distribution of recess 24 on two adjacent separation discs 23.

As shown in fig. 2 and 3, when the solvent oil is injected from the liquid inlet pipe 9, the solvent oil sequentially passes through the liquid inlet pipe 9, the first communication pipe 6 and the first communication groove 21 to enter the cooling barrel 19, when the solvent oil enters the cooling barrel 19, the solvent oil is located on the uppermost first separation disc 23, then the solvent oil flows from the grooves 24 on the first separation disc 23 to the second separation disc 23, then flows from the grooves 24 on the second separation disc 23 to the third separation disc 23, and so on until the solvent oil flows out from the grooves 24 on the lowermost separation disc 23, then the solvent oil sequentially passes through the second communication groove 22 and the second communication pipe 7 to be discharged from the liquid discharge pipe 12, and in the process that the solvent oil enters the cooling barrel 19 and then is discharged from the liquid discharge pipe 12, the separation discs 23 in the cooling barrel 19 are distributed at intervals from top to bottom, and the grooves 24 on the adjacent separation discs 23 are staggered, so that when the solvent oil enters the cooling barrel 19, the solvent oil is matched with the grooves 24 on the separation discs 23 to the first separation disc 23, the cooling barrel 19 can be rotated, and the heat exchange is carried out along the cooling barrel 6 by the cooling barrel 1, and the cooling water can be conveniently carried out, and the heat exchange is carried out along the cooling barrel 6 in the cooling barrel 1.

As shown in fig. 2 and 3, a baffle plate 25 for dividing the cooling barrel 19 into a first area 42 and a second area 43 is coaxially arranged in the cooling barrel 19, the first area 42 is located above the second area 43, a U-shaped dispersing pipe 26 is arranged on the outer wall of the cooling barrel 19, pipe orifices at two ends of the dispersing pipe 26 are respectively communicated with the first area 42 and the second area 43, each separating plate 23 is located in the first area 42 and above the dispersing pipe 26, at this time, the first communicating pipe 6 is communicated with the first area 42, the second communicating pipe 7 is communicated with the second area 43, the dispersing pipes 26 are several, and each dispersing pipe 26 is uniformly distributed along the circumference of the baffle plate 25, the purpose of the arrangement is that when the solvent oil flows out from a groove 24 on the lowest separating plate 23, the solvent oil is located on the baffle plate 25, then the solvent oil located on the baffle plate 25 flows into the second area 43 through the dispersing pipe 26, then the solvent oil in the second area 43 is discharged from the liquid discharge pipe 12 through the second communication groove 22 and the second communication pipe 7 in sequence, at this time, the retention time of the solvent oil in the cooling barrel 19 can be further improved through the baffle plate 25 and the dispersing pipe 26, when the first communication pipe 6 drives the cooling barrel 19 to rotate along the rotation axis of the first communication pipe 6 through the cover plate 20, the cooling barrel 19 drives the dispersing pipe 26 to rotate along the rotation axis of the first communication pipe 6, at this time, the water or the cooling liquid in the treatment barrel 1 can be disturbed through the dispersing pipe 26, when the solvent oil on the baffle plate 25 flows into the second area 43 through the dispersing pipe 26, the water or the cooling liquid in the treatment barrel 1 exchanges heat with the dispersing pipe 26, at this time, the solvent oil in the dispersing pipe 26 is cooled through the heat exchange of the water or the cooling liquid in the treatment barrel 1 and the dispersing pipe 26, and the solvent oil can be further cooled, the use is simple and convenient.

As shown in fig. 2, a moving plate 27 is connected to one side of the inner wall of the treatment barrel 1 by sliding vertically, a temperature sensor 13 is arranged on the moving plate 27, when the cooling barrel 19 rotates, a driving member for driving the moving plate 27 to move vertically up and down is arranged on the cooling barrel 19, the driving member is positioned above the dispersing tube 26, and the purpose of the arrangement is that when the cooling barrel 19 rotates, the moving plate 27 is driven to move vertically up and down by the driving member on the cooling barrel 19, at this time, the temperature sensor 13 moves along with the moving plate 27, at this time, the temperature of water or cooling liquid at different height positions in the treatment barrel 1 can be detected by the temperature sensor 13 moving up and down, and the use is simple and convenient.

As shown in fig. 2, 3 and 4, the driving member includes two annular grooves 28 obliquely disposed on the outer wall of the cooling barrel 19, the two annular grooves 28 are vertically distributed, one ends of the two annular grooves 28 are intersected and communicated, one end of the moving plate 27 close to the cooling barrel 19 is horizontally provided with a connecting column 29, one end of the connecting column 29 far away from the moving plate 27 is rotationally connected with an oval block 30 located in one of the annular grooves 28, the purpose of the arrangement is that when the cooling barrel 19 rotates, the oval block 30 on the connecting column 29 is located in one of the annular grooves 28 on the cooling barrel 19, the two annular grooves 28 on the outer wall of the cooling barrel 19 are vertically distributed, and one ends of the two annular grooves 28 are intersected and communicated, so that when the cooling barrel 19 rotates, the connecting column 29 can be pushed to drive the moving plate 27 to vertically reciprocate through the cooperation of the annular grooves 28, the oval block 30 and the connecting column 29, and the use is simple and convenient.

As shown in fig. 5 and 6, alternatively, the cooler comprises a spiral conduit 31 arranged between the first communicating pipe 6 and the second communicating pipe 7, the pipe orifices at two ends of the spiral conduit 31 are respectively communicated with the first communicating pipe 6 and the second communicating pipe 7, a placing plate 32 is vertically connected with one side of the inner wall of the treatment barrel 1 in a sliding manner, the temperature sensor 13 is arranged on the placing plate 32, when the spiral conduit 31 rotates, the spiral conduit 31 and the placing plate 32 are connected through a transmission piece, the transmission piece is used for driving the placing plate 32 to vertically move up and down, the transmission piece comprises a horizontal column 33 horizontally arranged on one side of the placing plate 32 close to the spiral conduit 31, one end of the horizontal column 33, which is far away from the placing plate 32, extends into the spiral conduit 31, and one end of the horizontal column 33 is positioned between two sides of the outer wall of the spiral conduit 31, which are vertically opposite.

As shown in fig. 5 and 6, when the solvent oil is injected from the liquid inlet pipe 9, the solvent oil sequentially passes through the liquid inlet pipe 9 and the first communication pipe 6 to enter the spiral conduit 31, then the solvent oil in the spiral conduit 31 is discharged from the liquid discharge pipe 12 through the second communication pipe 7, when the solvent oil is located in the spiral conduit 31, the water or cooling liquid in the treatment barrel 1 exchanges heat with the spiral conduit 31, the solvent oil in the spiral conduit 31 can be cooled at the moment, when the rotating shaft of the motor 17 drives the first communication pipe 6 to rotate, the first communication pipe 6 drives the spiral conduit 31 to rotate along the rotating axis of the first communication pipe 6, at the moment, the water or cooling liquid in the treatment barrel 1 can be disturbed through the rotating spiral conduit 31, so that the effect of heat exchange between the water or cooling liquid in the treatment barrel 1 and the spiral conduit 31 can be increased, when the spiral conduit 31 rotates, the horizontal column 33 is arranged on the placement plate 32, and therefore, when the spiral conduit 31 rotates, the temperature sensor plate 13 is driven by the horizontal column 33 and the rotating shaft of the motor 17, and the vertical sensor plate 13 is driven to move along the rotating shaft, and the temperature sensor plate 32 is not moved along the rotating shaft, and the vertical plate 13 is placed along the rotating direction, and the vertical plate 13 is moved along the vertical position, and the vertical position is not to move the vertical plate 13, and the vertical plate 13 is moved along the vertical position and the vertical position is moved, and the vertical position is moved to the vertical position and the sensor plate 13.

As shown in fig. 5 and 6, the horizontal column 33 is coaxially and rotatably connected with a rotary drum 34, and two opposite sides of the outer wall of the spiral duct 31 are contacted with the outer wall of the rotary drum 34, so that the friction resistance between the horizontal column 33 and the outer wall of the spiral duct 31 can be reduced through the rotary drum 34, and the use is simple and convenient.

As shown in fig. 1, fig. 2 and fig. 7, a hose 35 is connected to the bottom end pipe orifice of the water outlet pipe 4, a liquid storage tank 36 is disposed at one end of the hose 35 far away from the water outlet pipe 4, a storage tank 38 is disposed at one side of the liquid storage tank 36, the liquid storage tank 38 is connected to the liquid storage tank 36 through a connecting pipe 39, a valve 40 is disposed on the connecting pipe 39, and a water suction pump 41 is disposed on the connecting pipe 39 and the hose 35, so that when the high-temperature water or cooling liquid in the treatment tank 1 is discharged from the water outlet pipe 4, the water suction pump 41 on the hose 35 is opened, at this time, the water or cooling liquid discharged from the water outlet pipe 4 enters the liquid storage tank 36 through the hose 35, at this time, the high-temperature water or cooling liquid can be collected by the liquid storage tank 36, and after the high-temperature water or cooling liquid is collected in the liquid storage tank 36 along with the multiple discharges of the water outlet pipe 4, the water or cooling liquid in the liquid storage tank 36 at this time enters the liquid storage tank 38 through the connecting pipe 39, and then the water suction pump 41 on the valve 40 is opened, and the water suction pump 41 on the hose 35 is opened, and the water outlet pipe 4 is discharged from the water outlet pipe 4 or cooling liquid outlet pipe 36 is discharged from the water tank 36, and the water tank is discharged into the water tank 36.

It will be apparent to those skilled in the art that various modifications and variations can be made to the present invention without departing from the spirit or scope of the invention. Thus, it is intended that the present invention also include such modifications and alterations insofar as they come within the scope of the appended claims or the equivalents thereof.

Claims

1. The utility model provides a solvent oil's apparatus for producing, its characterized in that includes processing drum (1) and sets up inlet tube (2) on processing drum (1) top, first change groove (3), the bottom of processing drum (1) is equipped with outlet pipe (4), second change groove (5), first change groove (3) internal rotation is connected with first connecting pipe (6), second change groove (5) internal rotation is connected with second communicating pipe (7), be equipped with the cooler that is used for placing solvent oil between first connecting pipe (6) and second communicating pipe (7), and first connecting pipe (6), second communicating pipe (7) all communicate with the cooler, the top of processing drum (1) is equipped with first support (8), and is equipped with feed-in pipe (9) on first support (8), the top mouth of pipe and feed-in pipe (9) of first change and be connected rather than rotating, the bottom of processing drum (1) is equipped with second support (10), and is equipped with on second support (10) second support (12), the bottom of first connecting pipe (7) and second communicating pipe (7) all communicate with the cooler, be equipped with on the first connecting pipe (6) and be equipped with on one side of rotation drive connecting pipe (13) and be equipped with on the processing drum (1), a stop valve (14) is arranged on the water outlet pipe (4);

the cooler comprises a cooling barrel (19) and a cover plate (20) fixedly connected to the top end of the cooling barrel (19) and used for sealing a barrel opening of the cooling barrel (19), wherein the bottom end of a first communication pipe (6) is fixedly connected with the center of the top end of the cover plate (20), at the moment, a first communication groove (21) used for communicating the first communication pipe (6) with the cooling barrel (19) is formed in the cover plate (20), the top end of a second communication pipe (7) is fixedly connected with the center of the bottom end of the cooling barrel (19), a second communication groove (22) used for communicating the second communication pipe (7) with the cooling barrel (19) is formed in the bottom end of the cooling barrel (19), a plurality of separation discs (23) are coaxially arranged in the cooling barrel (19), the separation discs (23) are all distributed from top to bottom at intervals along the vertical direction of the cooling barrel (19), grooves (24) are formed in the top ends of the separation discs (23), and the grooves (24) on two adjacent separation discs (23) are distributed in a staggered mode;

baffle discs (25) used for dividing the cooling barrel (19) into a first area (42) and a second area (43) are coaxially arranged in the cooling barrel (19), the first area (42) is positioned above the second area (43), U-shaped dispersing pipes (26) are arranged on the outer wall of the cooling barrel (19), pipe orifices at two ends of each dispersing pipe (26) are respectively communicated with the first area (42) and the second area (43), the separation discs (23) are respectively positioned in the first area (42) and are respectively positioned above the dispersing pipes (26), at the moment, the first communicating pipes (6) are communicated with the first area (42), the second communicating pipes (7) are communicated with the second area (43), the number of the dispersing pipes (26) is a plurality, and the dispersing pipes (26) are uniformly distributed along the circumferential direction of the baffle discs (25);

a movable plate (27) is vertically connected to one side of the inner wall of the treatment barrel (1) in a sliding manner, the temperature sensor (13) is arranged on the movable plate (27), and when the cooling barrel (19) rotates, a driving piece for driving the movable plate (27) to vertically move up and down is arranged on the cooling barrel (19) and is positioned above the dispersing pipe (26);

the driving piece comprises two annular grooves (28) obliquely arranged on the outer wall of the cooling barrel (19), the two annular grooves (28) are distributed up and down, one ends of the two annular grooves (28) are intersected and communicated, a connecting column (29) is horizontally arranged at one end of the moving plate (27) close to the cooling barrel (19), and an oval block (30) positioned in one annular groove (28) is rotationally connected to one end of the connecting column (29) far away from the moving plate (27);

injecting water or cooling liquid into the treatment barrel (1) through the water inlet pipe (2), and then injecting solvent oil from the liquid inlet pipe (9);

when the first communication pipe (6) drives the cooling barrel (19) to rotate along the rotation axis of the first communication pipe (6) through the cover plate (20), the cooling barrel (19) drives the dispersing pipe (26) to rotate along the rotation axis of the first communication pipe (6), at the moment, water or cooling liquid in the treatment barrel (1) can be disturbed through the dispersing pipe (26), and when solvent oil on the baffle plate (25) flows into the second area (43) through the dispersing pipe (26), the water or cooling liquid in the treatment barrel (1) exchanges heat with the dispersing pipe (26), and the solvent oil in the dispersing pipe (26) is cooled;

when the cooling barrel (19) rotates, the connecting column (29) can be pushed to drive the moving plate (27) to vertically reciprocate up and down through the matching of the annular groove (28), the elliptic block (30) and the connecting column (29).

2. A solvent oil production device according to claim 1, wherein the driving member comprises a first gear (15) coaxially and fixedly connected to the outer wall of the first communication pipe (6), the first gear (15) is located above the treatment barrel (1), an inverted U-shaped mounting frame (16) is arranged at the top end of the treatment barrel (1), a motor (17) is arranged on the mounting frame (16), and a second gear (18) meshed with the first gear (15) is arranged at one end of a rotating shaft of the motor (17).

3. A solvent oil production device according to claim 1, wherein a hose (35) is communicated with a bottom end pipe orifice of the water outlet pipe (4), one end of the hose (35) far away from the water outlet pipe (4) is provided with a liquid storage tank (36), one side of the liquid storage tank (36) is provided with a storage tank (38), the storage tank (38) is communicated with the liquid storage tank (36) through a connecting pipe (39), a valve (40) is arranged on the connecting pipe (39), and water pumps (41) are arranged on the connecting pipe (39) and the hose (35).