CN211099544U - Magnetic separation water outlet device of nano zero-valent iron reactor - Google Patents

Abstract

The utility model discloses a magnetic separation water outlet device of a nanometer zero-valent iron reactor, which comprises a conical shell, the upper end of the conical shell is in threaded connection with a sealing threaded ring, the sealing threaded ring is in sealed welding on the lateral side of a top cover, the center of the top cover is in sealed welding with a motor base, the motor base is connected with a motor gland through a plurality of connecting bolts, a motor body is clamped between the motor base and the motor gland, the output end of the motor body passes through the top cover to be connected with a threaded connector, a crankshaft sealing ring is arranged between the output end of the motor gland and the top cover, the threaded connector is in threaded connection with a stirring rod connector, a stirring rod carrier rod is welded at the center of one end of the stirring rod connector, which is far away from the threaded connector, a plurality of stirring rod bodies are connected on the outer side of the stirring rod, is a novel and practical magnetic separation water outlet device of the nano zero-valent iron reactor.

Description

Magnetic separation water outlet device of nano zero-valent iron reactor

Technical Field

The invention belongs to the technical field of magnetic separation of reactors, and particularly relates to a magnetic separation water outlet device of a nano zero-valent iron reactor.

Background

In the prior art, the magnetic separation of the nano zero-valent iron reactor is mostly to arrange a separation area in the reactor and then separate the reactor by using an electromagnet, and the way is influenced by design and is easy to cause the situations of magnetic field dispersion, weak magnetic field intensity and weak adsorption, so the invention provides a magnetic separation water outlet device of the nano zero-valent iron reactor to solve the problems.

Disclosure of Invention

The invention aims to solve the problems and provide a magnetic water separation device of a nano zero-valent iron reactor, which solves the existing defects.

In order to solve the above problems, the present invention provides a technical solution:

the utility model provides a nanometer zero-valent iron reactor magnetic separation goes out water installation, includes the toper casing, the upper end threaded connection of toper casing has sealed screw ring, sealed screw ring seal welding is on the avris of top cap, the center department seal welding of top cap has the motor cabinet, the motor cabinet is connected with the motor gland through a plurality of connecting bolt, the centre gripping has motor body between motor cabinet and the motor gland, motor body's output passes the top cap and is connected with the threaded connection head, be equipped with the spindle seal circle between motor gland's output and the top cap, threaded connection head threaded connection has the stirring rod connector, the one end center department welding that the threaded connection head was kept away from to the stirring rod connector has the stirring rod carrier bar, be connected with a plurality of stirring rod bodies on the stirring rod carrier bar outside, the stirring rod body includes square alloy pole, middle part through groove, groove, The square alloy rod welding device comprises a connecting hinge and a stirring rod welding head, wherein one end of the square alloy rod is connected with the stirring rod welding head through the connecting hinge, the stirring rod welding head is welded on the outer side of a stirring rod carrier rod, the inner side of the stirring rod welding head is in threaded connection with a transmission connecting threaded rod, one end, far away from the stirring rod welding head, of the transmission connecting threaded rod is connected with a bearing connector through a connector welding plate, the bearing connector is fixed on the inner side of a connecting bearing, and the connecting bearing is fixed on a suction plate pressure head through a bearing welding frame.

Preferably, a threaded pipe is welded at the center of one side of the suction plate pressure head, which is far away from the bearing welding frame, the threaded pipe is in threaded connection with a core rod connector, a core rod body is welded on the core rod connector, the core rod body is inserted inside the columnar electromagnet, a wire groove is arranged inside one end of the core rod body, which is far away from the suction plate pressure head, a connecting wire is arranged in the wire groove, one end of the connecting wire penetrates through the core rod body and is electrically connected with the columnar electromagnet, one end of the connecting wire, which is far away from the columnar electromagnet, penetrates through the wire groove and is electrically connected with an electromagnet wire box, a bottom perforation is arranged at the center of the bottom of the conical shell, the electromagnet wire box is fixed on the outer side of the bottom of the conical shell through a wire box sealing shell, and the, the core bar sealing fixing block is sealed on the inner wall of the suction plate base, and the suction plate base is welded at the center of the bottom of the conical shell in a sealing mode.

Preferably, a suction plate body is clamped between the suction plate pressure head and the suction plate base and comprises end embedded rings, a rough surface slope body and an inner cavity, the end embedded rings are arranged at two ends of the rough surface slope body and are respectively clamped in two corresponding embedded ring embedded grooves, the embedded ring embedded grooves are respectively arranged on the suction plate pressure head and the suction plate base, the rough surface slope body is arranged on the outer side of the suction plate body, the inner cavity is arranged in the suction plate body, electromagnet support plates are welded on the outer sides of conical shells corresponding to the columnar electromagnets, a plurality of annular electromagnet installation seats are arranged on the electromagnet support plates, the electromagnet installation seats are in one-to-one correspondence with each other and are connected with annular electromagnets through bolts, locking ring embedded rings are arranged on the electromagnet support plates between two adjacent electromagnet installation seats, and locking ring bodies are correspondingly clamped in the locking ring embedded rings one-to one, the inner wall of the electromagnet support plate corresponding to the conical shell is provided with a conical resistance surface, and the conical resistance surface is provided with a plurality of inclined ring surfaces.

Preferably, a rubber pad is clamped between the motor body and the motor gland.

Preferably, the top cover is hermetically connected with a feed inlet, and one end of the feed inlet, which is far away from the conical shell, is connected with a sealing cover in a threaded manner.

Preferably, the middle through groove is formed in the square alloy rod.

Preferably, a plurality of main supports are welded on the outer side of the top end of the conical shell, the lower ends of the main supports are connected with the outer side of the bottom of the conical shell through a plurality of auxiliary supports, and supporting foot plates are welded on one end, far away from the conical shell, of each main support in a one-to-one corresponding mode.

Preferably, the bottom of the conical shell is connected with a drain pipe, and a valve is arranged on the drain pipe.

The invention has the beneficial effects that:

the invention has simple and clear process of separating water, simple principle and convenient operation, and in the process of the invention, the columnar electromagnet designed by the invention can adsorb nearby zero-valent iron on the suction plate body outside the columnar electromagnet, the rough surface slope body inclined on the suction plate body can increase resistance for the falling of the zero-valent iron, and the zero-valent iron can be firmly adsorbed on the suction plate body by matching with the magnetic field suction force generated by the electromagnet, while the annular electromagnet designed by the invention can adsorb the outside zero-valent iron, the conical resistance surface corresponding to the annular electromagnet can generate larger resistance for the falling of the zero-valent iron, and the design ensures that the zero-valent iron is adsorbed after being guided by the magnetic field, the magnetic separation water outlet device has the advantages that the magnetic separation water outlet device is novel in structure and convenient to use, and is a novel and practical magnetic separation water outlet device for the nano zero-valent iron reactor.

Description of the drawings:

for ease of illustration, the invention is described in detail by the following detailed description and the accompanying drawings.

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic structural diagram of the stirring rod body according to the present invention;

FIG. 3 is an enlarged schematic view of the structure at A of the present invention;

fig. 4 is an enlarged schematic view of the structure at B of the present invention.

In the figure: 1. a conical housing; 2. sealing the threaded ring; 3. a top cover; 4. a feed inlet; 5. sealing the cover; 6. a motor base; 7. a connecting bolt; 8. a motor gland; 9. a motor body; 10. a rubber pad; 11. a crankshaft sealing ring; 12. a threaded connector; 13. a stirring rod connector; 14. stirring a rod carrying rod; 15. a stirring rod body; 16. a square alloy rod; 17. the middle part is penetrated with a groove; 18. a connecting hinge; 19. stirring a rod welding head; 20. the transmission is connected with a threaded rod; 21. welding a connector plate; 22. a bearing connector; 23. connecting a bearing; 24. a bearing welding frame; 25. a suction plate pressure head; 26. a threaded pipe; 27. a core bar connector; 28. a core bar body; 29. a columnar electromagnet; 30. a wire guide groove; 31. connecting a lead; 32. the core bar seals the fixed block; 33. a suction plate base; 34. punching the bottom; 35. an electromagnet wire box; 36. a wire box sealing shell; 37. a suction plate body; 38. an end socket ring; 39. a caulking ring and a caulking groove; 40. a rough surface slope body; 41. an inner cavity; 42. a main support; 43. an auxiliary support; 44. a foot supporting plate; 45. an electromagnet support plate; 46. an electromagnet mounting base; 47. an annular electromagnet; 48. locking a ring embedding; 49. a locking ring body; 50. a blow-off pipe; 51. a valve; 52. a tapered resistive surface; 53. an inclined torus.

The specific implementation mode is as follows:

as shown in fig. 1 to 4, the following technical solutions are adopted in the present embodiment: a magnetic separation water outlet device of a nano zero-valent iron reactor comprises a conical shell 1, wherein the upper end of the conical shell 1 is in threaded connection with a sealing threaded ring 2, the sealing threaded ring 2 is in sealing welding on the side of a top cover 3, the center of the top cover 3 is in sealing welding with a motor base 6, the motor base 6 is connected with a motor gland 8 through a plurality of connecting bolts 7, a motor body 9 is clamped between the motor base 6 and the motor gland 8, the output end of the motor body 9 penetrates through the top cover 3 to be connected with a threaded connector 12, a shaft sealing ring 11 is arranged between the output end of the motor gland 8 and the top cover 3, the threaded connector 12 is in threaded connection with a stirring rod connector 13, a stirring rod carrier rod 14 is welded at the center of one end of the stirring rod connector 13, which is far away from the threaded connector 12, a plurality of stirring rod bodies 15 are connected on, the stirring rod body 15 comprises a square alloy rod 16, a middle through groove 17, a connecting hinge 18 and a stirring rod welding head 19, one end of the square alloy rod 16 is connected with the stirring rod welding head 19 through the connecting hinge 18, the stirring rod welding head 19 is welded on the outer side of the stirring rod carrier rod 14, the inner side of the stirring rod welding head 19 is in threaded connection with a transmission connecting threaded rod 20, one end, far away from the stirring rod welding head 19, of the transmission connecting threaded rod 20 is connected with a bearing connector 22 through a connector welding plate 21, the bearing connector 22 is fixed on the inner side of a connecting bearing 23, and the connecting bearing 23 is fixed on a suction plate pressure head 25 through a bearing welding frame 24.

Wherein, a threaded pipe 26 is welded at the center of one side of the suction plate pressure head 25 far away from the bearing welding frame 24, the threaded pipe 26 is in threaded connection with a core rod connector 27, a core rod body 28 is welded on the core rod connector 27, the core rod body 28 is inserted inside a columnar electromagnet 29, a wire guide groove 30 is arranged inside one end of the core rod body 28 far away from the suction plate pressure head 25, a connecting wire 31 is arranged in the wire guide groove 30, one end of the connecting wire 31 passes through the core rod body 28 to be electrically connected with the columnar electromagnet 29, one end of the connecting wire 31 far away from the columnar electromagnet 29 passes through the wire guide groove 30 and a bottom perforation 34 to be electrically connected on an electromagnet wire box 35, the bottom perforation 34 is arranged at the center of the bottom of the conical shell 1, the electromagnet 35 is fixed on the outer side of the bottom of the conical shell 1 through a wire box sealing shell 36, the outer side of one end of, the core bar sealing fixing block 32 is sealed on the inner wall of the suction plate base 33, and the suction plate base 33 is sealed and welded at the center of the bottom of the conical shell 1.

Wherein, a suction plate body 37 is clamped between the suction plate pressure head 25 and the suction plate base 33, the suction plate body 37 comprises end caulking rings 38, a rough surface slope body 40 and an inner cavity 41, the end caulking rings 38 are arranged at two ends of the rough surface slope body 40, the end caulking rings 38 are respectively clamped in two corresponding caulking ring caulking grooves 39, the caulking ring caulking grooves 39 are respectively arranged on the suction plate pressure head 25 and the suction plate base 33, the rough surface slope body 40 is arranged on the outer side of the suction plate body 37, the inner cavity 41 is arranged inside the suction plate body 37, an electromagnet support plate 45 is welded on the outer side of the conical shell 1 corresponding to the columnar electromagnet 29, a plurality of annular electromagnet installation seats 46 are arranged on the electromagnet support plate 45, the electromagnet installation seats 46 are in one-to-one correspondence bolted connection with annular electromagnets 47, electromagnet locking rings 48 are arranged on the electromagnet support plate 45 between two adjacent electromagnet installation seats 46, the locking ring embedding rings 48 are correspondingly clamped with locking ring bodies 49 one by one, the inner wall of the electromagnet support plate 45 corresponding to the conical shell 1 is provided with a conical resistance surface 52, and the conical resistance surface 52 is provided with a plurality of inclined ring surfaces 53.

Wherein, a rubber pad 10 is clamped between the motor body 9 and the motor gland 8.

Wherein, sealing connection has feed inlet 4 on the top cap 3, threaded connection has closing cap 5 on the one end that conical shell 1 was kept away from to feed inlet 4.

Wherein the middle through groove 17 is arranged on the square alloy rod 16.

A plurality of main supports 42 are welded on the outer side of the top end of the conical shell 1, the lower ends of the main supports 42 are connected with the outer side of the bottom of the conical shell 1 through a plurality of auxiliary supports 43, and foot support plates 44 are welded on one end, far away from the conical shell 1, of the main supports 42 in a one-to-one correspondence mode.

Wherein, the bottom of the conical shell 1 is connected with a sewage discharge pipe 50, and the sewage discharge pipe 50 is provided with a valve 51.

Specifically, the method comprises the following steps: a nanometer zero-valent iron reactor magnetic separation water device, while using, pour raw materials into the invention from the feed inlet 4 that the invention designs at first, then cover the closing cap 5, open electromagnet and electrical machinery body 9, open the valve 51 after certain time and discharge surplus water, the process of separating water of the invention is simple and clear, the principle is simple, easy to operate, in the course of the invention's operation, the column electromagnet 29 that the invention designs can adsorb nearby zero-valent iron on its outside suction plate body 37, the sloping body 40 of rough surface that the suction plate body 37 is inclined can increase the resistance for the falling of zero-valent iron, cooperate with the magnetic field suction that the electromagnet produces, make zero-valent iron adsorbed on the suction plate body 37 firmly, and the annular electromagnet 47 that the invention designs can adsorb outside zero-valent iron, the conical resistance surface 52 that the annular electromagnet 47 corresponds to can produce the greater resistance for the falling of zero-valent iron, the design ensures that the zero-valent iron can be separated from water after being guided and adsorbed by the magnetic field, the motor body 9 and the stirring rod body 15 connected with the motor body can apply a centrifugal force to the raw material, so that the zero-valent iron can be separated from the water more quickly, in addition, the bearing connection between the motor shaft and the core rod structure at the bottom also ensures that the core rod can keep the original position when the motor shaft rotates, and the design enhances the stability of the core rod in the swinging water body.

While there have been shown and described what are at present considered to be the fundamental principles of the invention and its essential features and advantages, it will be understood by those skilled in the art that the invention is not limited by the embodiments described above, which are merely illustrative of the principles of the invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the invention as defined by the appended claims and their equivalents.

Claims (8)

1. A nanometer zero-valent iron reactor magnetic separation water outlet device is characterized in that: comprises a conical shell (1), the upper end of the conical shell (1) is in threaded connection with a sealing threaded ring (2), the sealing threaded ring (2) is in sealing welding on the side of a top cover (3), the center of the top cover (3) is in sealing welding with a motor base (6), the motor base (6) is connected with a motor gland (8) through a plurality of connecting bolts (7), a motor body (9) is clamped between the motor base (6) and the motor gland (8), the output end of the motor body (9) penetrates through the top cover (3) to be connected with a threaded connector (12), a shaft sealing ring (11) is arranged between the output end of the motor gland (8) and the top cover (3), the threaded connector (12) is in threaded connection with a stirring rod connector (13), one end center of the stirring rod connector (13) far away from the threaded connector (12) is welded with a stirring rod carrier rod (14), the outer side of the stirring rod carrier rod (14) is connected with a plurality of stirring rod bodies (15), the stirring rod body (15) comprises a square alloy rod (16), a middle through groove (17), a connecting hinge (18) and a stirring rod welding head (19), one end of the square alloy rod (16) is connected with a stirring rod welding head (19) through a connecting hinge (18), the stirring rod welding head (19) is welded on the outer side of the stirring rod carrier rod (14), the inner side of the stirring rod welding head (19) is in threaded connection with a transmission connection threaded rod (20), one end of the transmission connecting threaded rod (20) far away from the stirring rod welding head (19) is connected with a bearing connecting head (22) through a connecting head welding plate (21), the bearing connection head (22) is fixed on the inner side of the connection bearing (23), the connecting bearing (23) is fixed on the suction plate pressure head (25) through a bearing welding frame (24).

2. The magnetic separation water device of the nano zero-valent iron reactor according to claim 1, characterized in that: the bearing welding structure is characterized in that a threaded pipe (26) is welded at the center of one side, away from a bearing welding frame (24), of the suction plate pressure head (25), the threaded pipe (26) is in threaded connection with a core rod connector (27), a core rod body (28) is welded on the core rod connector (27), the core rod body (28) is inserted inside a columnar electromagnet (29), a wire guide groove (30) is formed inside one end, away from the suction plate pressure head (25), of the core rod body (28), a connecting wire (31) is arranged in the wire guide groove (30), one end of the connecting wire (31) penetrates through the core rod body (28) and is electrically connected with the columnar electromagnet (29), one end, away from the columnar electromagnet (29), of the connecting wire (31) penetrates through the wire guide groove (30) and a bottom perforation (34) and is electrically connected onto an electromagnet wire box (35), and the bottom perforation (34) is arranged at the center, the electromagnet wire box (35) is fixed on the outer side of the bottom of the conical shell (1) through a wire box sealing shell (36), the outer side of one end, close to the wire guide groove (30), of the core rod body (28) is hermetically welded on a core rod sealing fixing block (32), the core rod sealing fixing block (32) is sealed on the inner wall of a suction plate base (33), and the suction plate base (33) is hermetically welded at the center of the bottom of the conical shell (1).

3. The magnetic separation water device of the nano zero-valent iron reactor according to claim 2, characterized in that: the suction plate comprises a suction plate body (37) and a suction plate base (33), wherein the suction plate body (37) comprises end embedded rings (38), a rough surface slope body (40) and an inner cavity (41), the end embedded rings (38) are arranged at two ends of the rough surface slope body (40), the end embedded rings (38) are respectively connected in two corresponding embedded ring embedded grooves (39), the embedded ring embedded grooves (39) are respectively arranged on the suction plate pressure head (25) and the suction plate base (33), the rough surface slope body (40) is arranged on the outer side of the suction plate body (37), the inner cavity (41) is arranged in the suction plate body (37), an electromagnet support plate (45) is welded on the outer side of a conical shell (1) corresponding to the columnar electromagnet (29), and a plurality of annular electromagnet installation seats (46) are arranged on the support plate (45), the electromagnetic mounting seat is characterized in that the electromagnet mounting seats (46) are in one-to-one correspondence and are connected with annular electromagnets (47) through bolts, locking ring embedded rings (48) are arranged on the electromagnet support plates (45) between the two adjacent electromagnet mounting seats (46), locking ring bodies (49) are clamped in the locking ring embedded rings (48) in one-to-one correspondence, conical blocking surfaces (52) are arranged on the inner walls, corresponding to the conical shell (1), of the electromagnet support plates (45), and a plurality of inclined ring surfaces (53) are arranged on the conical blocking surfaces (52).

4. The magnetic separation water device of the nano zero-valent iron reactor according to claim 1, characterized in that: a rubber pad (10) is clamped between the motor body (9) and the motor gland (8).

5. The magnetic separation water device of the nano zero-valent iron reactor according to claim 1, characterized in that: the top cover (3) is connected with a feed inlet (4) in a sealing mode, and one end, far away from the conical shell (1), of the feed inlet (4) is connected with a sealing cover (5) in a threaded mode.

6. The magnetic separation water device of the nano zero-valent iron reactor according to claim 1, characterized in that: the middle through groove (17) is arranged on the square alloy rod (16).

7. The magnetic separation water device of the nano zero-valent iron reactor according to claim 1, characterized in that: the welding has a plurality of main supports (42) on the top outside of toper casing (1), the lower extreme of main support (42) is connected with the bottom outside of toper casing (1) through a plurality of auxiliary stand (43), one of serving one-to-one welding that toper casing (1) was kept away from in main support (42) has a sole (44).

8. The magnetic separation water device of the nano zero-valent iron reactor according to claim 1, characterized in that: the bottom of the conical shell (1) is connected with a sewage discharge pipe (50), and the sewage discharge pipe (50) is provided with a valve (51).

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