CN213865450U - Vacuum low-temperature evaporation separation device - Google Patents

Abstract

The utility model relates to an evaporation and separation device technical field specifically is a vacuum low temperature evaporation and separation device, including unable adjustment base, unable adjustment base's surface and the position that is close to the front end are equipped with the first support post of symmetric distribution, sliding connection has first movable plate between two first support posts, the bottom of first movable plate is equipped with rectangular beam, rectangular beam's bottom sliding connection has T shape movable block, the bottom of T shape movable block is equipped with the bung, the vertical connecting rod that is equipped with in middle part at bung inner wall top, the bottom of connecting rod is equipped with cylindricality crystal collecting groove, unable adjustment base's surface and the vertical support solid piece that is equipped with symmetric distribution in position that is close to the front end middle part, the top of supporting solid piece is equipped with the evaporation separation bucket. According to the vacuum low-temperature evaporation separation device, the vacuum machine vacuumizes the evaporation separation barrel through the vacuum-pumping pipe, so that the boiling point of waste water in the barrel is reduced, and the energy-saving effect is realized.

Description

Vacuum low-temperature evaporation separation device

Technical Field

The utility model relates to an evaporation separation device technical field specifically is a vacuum low temperature evaporation separation device.

Background

With the development of industries such as coal chemical industry, petrochemical industry and the like, the generated wastewater amount is more and more, the wastewater can be discharged or recycled only through treatment, the wastewater treatment mainly comprehensively applies physical, chemical or biochemical processes such as membrane separation, drying and the like, solid impurities in the wastewater are concentrated to be high in concentration, most of water can be recycled, a small amount of water along with solid waste is left, evaporation crystallization is further adopted for treatment, so that the solid waste is formed, most of existing evaporation crystallization devices directly heat and evaporate the wastewater, the boiling point of water in normal air pressure is higher than that of water in low air pressure, so that energy consumed in normal heating and evaporation is higher, and accordingly, a vacuum low-temperature evaporation separation device is provided.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a vacuum low temperature evaporation separator to it is direct to carrying out the heating evaporation to waste water mostly to propose current evaporation crystallization device in solving above-mentioned background art, and the boiling point of normal atmospheric pressure normal heating evaporation time consumption's the higher problem of energy.

In order to achieve the above object, the utility model provides a following technical scheme:

a vacuum low-temperature evaporation separation device comprises a fixed base, wherein first supporting upright columns which are symmetrically distributed are arranged on the surface of the fixed base and close to the front end, first U-shaped sliding grooves are formed in the opposite side surfaces of the two first supporting upright columns and are positioned on the middle upper portion, first lead screws are rotationally connected in the first U-shaped sliding grooves, first servo motors are arranged at the tops of the first supporting upright columns, the end portions of output shafts of the first servo motors penetrate through the tops of the first supporting upright columns and are coaxially connected with the first lead screws, a first moving plate is slidably connected between the two first supporting upright columns, second supporting upright columns which are symmetrically distributed are arranged on the surface of the fixed base and close to the rear end, the second supporting upright columns are the same as the first supporting upright columns, and a second moving plate is slidably connected between the two second supporting upright columns, the bottom of the first movable plate and the bottom of the second movable plate are provided with rectangular crossbeams, the bottom of each rectangular crossbeam is provided with a second U-shaped chute, a second screw rod is rotatably connected in the second U-shaped chute, the end part of each rectangular crossbeam is provided with a second servo motor, the end part of an output shaft of the second servo motor penetrates through the end part of each rectangular crossbeam and is coaxially connected with the second screw rod, the bottom of each rectangular crossbeam is slidably connected with a T-shaped moving block, the bottom of each T-shaped moving block is provided with a barrel cover, the middle part of the top of the inner wall of the barrel cover is vertically provided with a connecting rod, the bottom of each connecting rod is provided with a cylindrical crystal collecting tank, symmetrically distributed supporting and fixing blocks are vertically arranged on the surface of the fixed base and at positions close to the middle part of the front end, the tops of the supporting and fixing blocks are provided with evaporation separation barrels, and the positions on the outer walls, the outer wall that evaporation separation bucket was passed on the top of steam recovery pipe extremely the inner wall of evaporation separation bucket, the outer wall of evaporation separation bucket and the position that is close to the top still are equipped with feed liquor pipe and vacuum tube, the bottom of evaporation separation bucket is equipped with the fluid-discharge tube, the zone of heating has been seted up at the middle part of evaporation separation bucket side, the top of fluid-discharge tube with the zone of heating intercommunication, the top of hot steam input tube with the zone of heating intercommunication.

Preferably, the first moving plate and the second moving plate are the same, the two ends of the first moving plate are both provided with fixing lugs, and the fixing lugs are located in the first U-shaped sliding grooves and are in threaded connection with the first screw rods.

Preferably, the fixed block in the middle of the T-shaped moving block is positioned in the second U-shaped sliding groove and is in threaded connection with the second screw rod.

Preferably, the length of the second U-shaped chute is more than twice the diameter of the inner wall of the evaporation separation barrel.

Preferably, when the barrel cover and the evaporation separation barrel are closed, the bottom of the cylindrical crystal collecting tank is attached to the bottom of the inner wall of the evaporation separation barrel, and the outer diameter of the cylindrical crystal collecting tank is matched with the inner diameter of the evaporation separation barrel.

Preferably, the top end of the steam recovery pipe is of an arc structure, and the radian of the arc structure is the same as that of the inner wall of the evaporation separation barrel.

Preferably, the outer wall of the evaporation separation barrel and the position close to the bottom are provided with symmetrically distributed positioning lugs, and the end parts of the hot steam input pipe and the steam recovery pipe respectively penetrate through the two positioning lugs.

Preferably, the outer walls of the hot steam input pipe, the steam recovery pipe, the liquid inlet pipe, the liquid discharge pipe and the vacuumizing pipe are all provided with control valves.

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

this vacuum low temperature evaporation separator, input hot steam to the zone of heating through the hot steam input tube, thereby carry out thermal treatment to waste water, the vacuum machine passes through evacuation pipe and will evaporate the interior evacuation of separation bucket, thereby reduce the boiling point of waste water in the bucket, make waste water rapid heating up and evaporate, realize energy-conserving effect, drive first movable plate and second movable plate respectively through two sets of first servo motor and two sets of first lead screws and carry out axial displacement, take out cylindricality crystallization collecting vat from the evaporation separation bucket, can remove cylindricality crystallization collecting vat to unable adjustment base's rear end department through second servo motor and second lead screw, thereby convenient to use person clears up solid waste.

Drawings

Fig. 1 is a schematic structural view of the whole first state of the present invention;

fig. 2 is a structural diagram of the whole second state of the present invention;

fig. 3 is a schematic view of an assembly structure of the first support column, the second support column, the first moving plate and the second moving plate of the present invention;

FIG. 4 is a schematic view of the sectional structure of the evaporation separation barrel of the present invention;

FIG. 5 is a schematic view of a part of the structure of the present invention;

fig. 6 is a schematic view of an assembly structure of the rectangular cross beam, the second lead screw and the second servo motor in the present invention;

fig. 7 is a schematic view of an assembly structure of the T-shaped moving block, the barrel cover, the connecting rod and the cylindrical crystal collecting tank of the present invention;

in the figure: the device comprises a fixed base 1, a first supporting upright post 2, a first U-shaped chute 20, a second supporting upright post 3, a first screw rod 4, a first servo motor 5, a first moving plate 6, a second moving plate 7, a rectangular cross beam 8, a second U-shaped chute 80, a second screw rod 9, a second servo motor 10, a T-shaped moving block 11, a barrel cover 12, a connecting rod 13, a cylindrical crystallization collecting tank 14, a supporting fixed block 15, an evaporation separation barrel 16, a hot steam input pipe 160, a steam recovery pipe 161, a liquid inlet pipe 162, a liquid outlet pipe 163, a heating layer 164, a positioning lug 165 and a vacuumizing pipe 166.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and to simplify the description, but do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore should not be construed as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically limited otherwise.

Referring to fig. 1-7, the present invention provides a technical solution:

a vacuum low-temperature evaporation separation device comprises a fixed base 1, first supporting upright columns 2 which are symmetrically distributed are arranged on the surface of the fixed base 1 and close to the front end, first U-shaped chutes 20 are respectively arranged on the opposite side surfaces of the two first supporting upright columns 2 and on the middle upper portion, first lead screws 4 are rotatably connected in the first U-shaped chutes 20, first servo motors 5 are arranged on the tops of the first supporting upright columns 2, the end portions of output shafts of the first servo motors 5 penetrate through the tops of the first supporting upright columns 2 and are coaxially connected with the first lead screws 4, the first lead screws 4 are driven to rotate through the first servo motors 5, so that first movable plates 6 drive rectangular cross beams 8 to move and further drive cylindrical crystal collecting tanks 14 to move, first movable plates 6 are slidably connected between the two first supporting upright columns 2, and second supporting upright columns 3 which are symmetrically distributed are arranged on the surface of the fixed base 1 and close to the rear end, the second supporting upright columns 3 are the same as the first supporting upright columns 2, a first servo motor 5 is also arranged at the tops of the second supporting upright columns 3, a second moving plate 7 is connected between the two second supporting upright columns 3 in a sliding manner, the first moving plate 6 and the second moving plate 7 play a role in fixing two ends of a rectangular cross beam 8, rectangular cross beams 8 are arranged at the bottoms of the first moving plate 6 and the second moving plate 7, a second U-shaped chute 80 is formed in the bottom of the rectangular cross beam 8, a second lead screw 9 is rotatably connected in the second U-shaped chute 80, a second servo motor 10 is arranged at the end part of the rectangular cross beam 8, the end part of an output shaft of the second servo motor 10 penetrates through the end part of the rectangular cross beam 8 and is coaxially connected with the second lead screw 9, the second lead screw 9 is driven to rotate by the second servo motor 10, so that a cylindrical crystal collecting tank 14 is driven by a T-shaped moving block 11, and, the bottom of the T-shaped moving block 11 is provided with a barrel cover 12, the barrel cover 12 can seal an evaporation separation barrel 16, the middle part of the top of the inner wall of the barrel cover 12 is vertically provided with a connecting rod 13, the bottom of the connecting rod 13 is provided with a cylindrical crystal collecting tank 14, crystals formed by evaporation of wastewater are collected through the cylindrical crystal collecting tank 14, the surface of the fixed base 1 and the position close to the middle part of the front end are vertically provided with symmetrically distributed supporting fixed blocks 15, the top of the supporting fixed block 15 is provided with the evaporation separation barrel 16 for evaporation crystallization treatment of wastewater, the outer wall of the evaporation separation barrel 16 and the position close to the top are provided with a symmetrically distributed hot steam input pipe 160 and a steam recovery pipe 161, the top end of the steam recovery pipe 161 penetrates through the outer wall of the evaporation separation barrel 16 to the inner wall of the evaporation separation barrel 16, evaporated steam in the wastewater is collected through the steam recovery pipe 161, and liquefaction of the generated steam in the evaporation separation barrel 16 is avoided, the outer wall of evaporation and separation bucket 16 and the position that is close to the top still are equipped with feed liquor pipe 162 and evacuation pipe 166, inject waste water into evaporation and separation bucket 16 through feed liquor pipe 162, the other end and the vacuum machine of evacuation pipe 166 are connected, carry out vacuum treatment in the evaporation and separation bucket 16, the bottom of evaporation and separation bucket 16 is equipped with fluid-discharge tube 163, zone of heating 164 has been seted up at the middle part of evaporation and separation bucket 16 side, the top and the zone of heating 164 intercommunication of fluid-discharge tube 163, the water that makes the thermal steam liquefaction form can discharge, the top and the zone of heating 164 intercommunication of thermal steam input tube 160, input thermal steam to zone of heating 164 through thermal steam input tube 160, thereby carry out heat treatment to waste water.

In this embodiment, the first moving plate 6 is the same as the second moving plate 7, and the two ends of the first moving plate 6 are both provided with fixing bumps, the fixing bumps are located in the first U-shaped sliding groove 20 and are in threaded connection with the first screw rod 4, and the first moving plate 6 is driven to move by the first screw rod 4.

Specifically, the fixed block in the middle of the T-shaped moving block 11 is located in the second U-shaped sliding groove 80 and is in threaded connection with the second lead screw 9, and the T-shaped moving block 11 is driven to move by the second lead screw 9.

Further, the length of the second U-shaped chute 80 is greater than twice the diameter of the inner wall of the evaporation and separation bucket 16, ensuring that the cylindrical crystal collection tank 14 can be moved to the rear end of the stationary base 1, thereby facilitating the cleaning of solid waste by the user.

Further, when the barrel cover 12 and the evaporation separation barrel 16 are closed, the bottom of the cylindrical crystal collection tank 14 is attached to the bottom of the inner wall of the evaporation separation barrel 16, and the outer diameter of the cylindrical crystal collection tank 14 is matched with the inner diameter of the evaporation separation barrel 16, so that all formed crystals are ensured to be in the cylindrical crystal collection tank 14.

Further, the top end of the steam recovery pipe 161 is of an arc structure, and the radian of the arc structure is the same as that of the inner wall of the evaporation separation barrel 16, so that the influence on the installation and removal of the cylindrical crystallization collecting tank 14 is avoided.

Furthermore, the outer wall of the evaporation separation barrel 16 and the position close to the bottom are provided with symmetrically distributed positioning lugs 165, and the ends of the hot steam input pipe 160 and the steam recovery pipe 161 respectively penetrate through the two positioning lugs 165, so as to fix the positions of the hot steam input pipe 160 and the steam recovery pipe 161.

In addition, the outer walls of the hot steam input pipe 160, the steam recovery pipe 161, the liquid inlet pipe 162, the liquid outlet pipe 163 and the vacuum pipe 166 are provided with control valves, so that the opening and closing of such pipes can be controlled conveniently.

When the vacuum low-temperature evaporation separation device of the embodiment is used, a user introduces wastewater into the evaporation separation barrel 16 through the liquid inlet pipe 162, then uses a vacuum machine to vacuumize the inside of the evaporation separation barrel 16 through the vacuum pipe 166, and inputs hot steam into the heating layer 164 through the hot steam input pipe 160 to heat the wastewater in the evaporation separation barrel 16, so that the wastewater is heated and evaporated in a vacuum environment, and the formed steam is recovered through the steam recovery pipe 161, thereby realizing the effect of energy conservation; solid waste formed after the wastewater is treated completely exists in the cylindrical crystallization collecting tank 14, a user drives the rectangular cross beam 8 to move upwards through the first servo motor 5 and the first screw rod 4 by the first movable plate 6 and the second movable plate 7, the cylindrical crystallization collecting tank 14 is moved out of the evaporation separation barrel 16, the T-shaped movable block 11 drives the cylindrical crystallization collecting tank 14 to move towards the rear end of the fixed base 1 through the second servo motor 10 and the second screw rod 9, and finally the cylindrical crystallization collecting tank 14 moves downwards through the first servo motor 5 and the first screw rod 4, so that the user can clean the solid waste in the cylindrical crystallization collecting tank 14 conveniently.

The foregoing shows and describes the general principles, essential features, and advantages of the invention. It should be understood by those skilled in the art that the present invention is not limited by the above embodiments, and the description in the above embodiments and the description is only preferred examples of the present invention, and is not intended to limit the present invention, and that the present invention can have various changes and modifications without departing from the spirit and scope of the present invention, and these changes and modifications all fall into the scope of the claimed invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (8)

1. A vacuum low-temperature evaporation separation device is characterized in that: comprises a fixed base (1), first supporting columns (2) which are symmetrically distributed are arranged on the surface of the fixed base (1) and at positions close to the front end, first U-shaped chutes (20) are respectively arranged on two opposite side surfaces of the first supporting columns (2) and at positions on the middle upper part, first lead screws (4) are rotationally connected with the first U-shaped chutes (20), first servo motors (5) are arranged on the tops of the first supporting columns (2), the end parts of output shafts of the first servo motors (5) penetrate through the tops of the first supporting columns (2) and are coaxially connected with the first lead screws (4), a first moving plate (6) is slidably connected between the two first supporting columns (2), second supporting columns (3) which are symmetrically distributed are arranged on the surface of the fixed base (1) and at positions close to the rear end, and the second supporting columns (3) are identical to the first supporting columns (2), a second moving plate (7) is connected between the two second supporting columns (3) in a sliding manner, a rectangular cross beam (8) is arranged at the bottoms of the first moving plate (6) and the second moving plate (7), a second U-shaped chute (80) is formed in the bottom of the rectangular cross beam (8), a second lead screw (9) is connected in the second U-shaped chute (80) in a rotating manner, a second servo motor (10) is arranged at the end of the rectangular cross beam (8), the end of an output shaft of the second servo motor (10) penetrates through the end of the rectangular cross beam (8) and is coaxially connected with the second lead screw (9), a T-shaped moving block (11) is connected at the bottom of the rectangular cross beam (8) in a sliding manner, a barrel cover (12) is arranged at the bottom of the T-shaped moving block (11), a connecting rod (13) is vertically arranged in the middle of the top of the inner wall of the barrel cover (12), and a cylindrical crystal collecting tank (14) is arranged at the bottom of the connecting rod (13), the utility model discloses a steam-water separation device, including unable adjustment base (1), the surface of unable adjustment base (1) and the position that is close to the front end middle part are vertical to be equipped with the support solid piece (15) of symmetric distribution, the top of supporting solid piece (15) is equipped with evaporation separation bucket (16), the outer wall of evaporation separation bucket (16) and the position that is close to the top are equipped with hot steam input tube (160) and steam recovery tube (161) that are symmetric distribution, the top of steam recovery tube (161) passes the outer wall of evaporation separation bucket (16) extremely the inner wall of evaporation separation bucket (16), the outer wall of evaporation separation bucket (16) and the position that is close to the top still are equipped with feed liquor pipe (162) and vacuum tube (166), the bottom of evaporation separation bucket (16) is equipped with fluid-discharge tube (163), zone of heating (164) have been seted up to the middle part of evaporation separation bucket (16) side, the top of fluid-discharge tube (163) with zone of heating (164) intercommunication, the top end of the hot steam input pipe (160) is communicated with the heating layer (164).

2. The vacuum cryogenic separation device of claim 1, wherein: the first movable plate (6) is the same as the second movable plate (7), fixing lugs are arranged at two ends of the first movable plate (6), are positioned in the first U-shaped sliding groove (20) and are in threaded connection with the first screw rod (4).

3. The vacuum cryogenic separation device of claim 1, wherein: the fixed block in the middle of the T-shaped moving block (11) is positioned in the second U-shaped sliding groove (80) and is in threaded connection with the second screw rod (9).

4. The vacuum cryogenic separation device of claim 1, wherein: the length of the second U-shaped chute (80) is more than twice the diameter of the inner wall of the evaporation separation barrel (16).

5. The vacuum cryogenic separation device of claim 1, wherein: when the barrel cover (12) and the evaporation separation barrel (16) are closed, the bottom of the cylindrical crystal collecting tank (14) is attached to the bottom of the inner wall of the evaporation separation barrel (16), and the outer diameter of the cylindrical crystal collecting tank (14) is matched with the inner diameter of the evaporation separation barrel (16).

6. The vacuum cryogenic separation device of claim 1, wherein: the top end of the steam recovery pipe (161) is of an arc structure, and the radian of the arc structure is the same as that of the inner wall of the evaporation separation barrel (16).

7. The vacuum cryogenic separation device of claim 1, wherein: the outer wall of the evaporation separation barrel (16) and the position close to the bottom are provided with positioning lugs (165) which are symmetrically distributed, and the end parts of the hot steam input pipe (160) and the steam recovery pipe (161) respectively penetrate through the two positioning lugs (165).

8. The vacuum cryogenic separation device of claim 1, wherein: and control valves are arranged on the outer walls of the hot steam input pipe (160), the steam recovery pipe (161), the liquid inlet pipe (162), the liquid discharge pipe (163) and the vacuum pumping pipe (166).

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