CN213060311U - Magnetic rotary water ion generator - Google Patents

Abstract

The utility model relates to a magnetism water ion generator that spins, including cyclic annular and take magnetic electrode ring and negative pole subassembly, the negative pole subassembly includes the negative pole needle, the upper end of negative pole needle is located under the electrode ring, just the axis of negative pole needle with the central axis of electrode ring overlaps mutually. This magnetism spins water ion generating device's electrode ring area magnetism, and discharge takes place in magnetic field, makes the electric field take place to force the rapid deflection, forms an electric arc face, can more effectively collect hydrone all around, simultaneously, greatly increased electric arc and fluidic contact surface, in addition, after magnetic field and electric field strength reached certain degree, can form ion wind, fluid passes through the electric arc face with higher speed to increase the formation of beneficial component and improve the formation speed of beneficial component.

Description

Magnetic rotary water ion generator

Technical Field

The utility model relates to an electron device field especially relates to a magnetism water ion generating device that spins.

Background

The arc striking point of the current water ion generating device is generally a fixed point or is deviated to one side, on one hand, the service life of the electrode is short, meanwhile, the beneficial components are generated less, the speed of the fluid passing through the arc is slow, and the efficiency of producing the beneficial components is low.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a magnetism water ion generator soon to solve above-mentioned technical problem.

In order to realize the purpose, the technical scheme of the utility model is that: the utility model provides a magnetism whirlpool water ion generator, includes cyclic annular and takes magnetic electrode ring and negative pole subassembly, the negative pole subassembly includes the negative pole needle, the upper end of negative pole needle is located under the electrode ring, just the axis of negative pole needle with the central axis of electrode ring overlaps mutually.

Preferably, the negative electrode assembly further includes a first thermoelectric device and a negative electrode positioning seat, the negative electrode positioning seat is mounted on the top of the first thermoelectric device, and the lower end of the negative electrode pin is vertically and fixedly mounted on the negative electrode positioning seat.

Preferably, the electrode ring includes a first annular support electrode and a first insulating electromagnetic coil, a first coil groove is formed in a side wall of the first support electrode, and the first insulating electromagnetic coil is wound in the first coil groove.

Preferably, the lower end of the inner wall of the central hole of the first support electrode uniformly extends downwards and inwards to form at least two discharge needle heads, and the discharge needle heads are positioned on the periphery above the negative pole needles.

Preferably, the number of the discharge needles is four.

Preferably, the electrode ring includes an annular second support electrode and a magnetic sleeve ring made of a magnetic material, a side wall of the second support electrode is recessed inward to form a magnetic ring sleeve groove, and the magnetic sleeve ring is sleeved in the magnetic ring sleeve groove.

Preferably, the electrode ring is a ring piece made of annular strong magnetic material or is formed by overlapping at least two ring pieces made of annular strong magnetic material.

Preferably, the lower part of the inner wall of the central hole of the electrode ring is provided with a chamfer.

Preferably, the magnetic-spin water ion generating device further includes a transition pole assembly, the transition pole assembly includes a transition pole, a transition pole positioning seat and a second thermoelectric device, the electrode ring includes an annular third support electrode and a second insulating electromagnetic coil, a third coil groove is formed in a side wall of the third support electrode, the second insulating electromagnetic coil is wound in the third coil groove, the transition pole is located between the negative pole needle and the third support electrode and located on one side of the central axis of the negative pole needle, a free end of the transition pole is perpendicular to the central axis of the negative pole needle, a fixed end of the transition pole is vertically and fixedly mounted at one end of the transition pole positioning seat, and the other end of the transition pole positioning seat is fixedly mounted on the second thermoelectric device.

The utility model discloses magnetism of magnetic rotation water ion generating device's electrode ring area, discharge and take place in magnetic field, make the electric field take place to force the rapid deflection, form an electric arc face, can more effectual collection hydrone all around, simultaneously, greatly increased electric arc and fluidic contact surface, in addition, after magnetic field and electric field strength reached the certain degree, can form ion wind, fluid passes electric arc face with higher speed to increase the formation of beneficial composition and improve the generating speed of beneficial composition.

The invention will become more apparent from the following description when taken in conjunction with the accompanying drawings which illustrate embodiments of the invention.

Drawings

Fig. 1 is a cross-sectional view of the magnetic water-rotating ion generator according to an angle of the first embodiment of the present invention.

Fig. 2 is a structural diagram of another angle of the first embodiment of the magnetic water-rotating ion generator of the present invention.

Fig. 3 is a cross-sectional view of the magnetic water-rotating ion generator according to a second embodiment of the present invention.

Fig. 4 is a structural diagram of another angle of the second embodiment of the magnetic water-rotating ion generator of the present invention.

Fig. 5 is a sectional view of an angle of a third embodiment of the magnetic water-rotating ion generator according to the present invention.

Fig. 6 is a sectional view of an angle of a fourth embodiment of the magnetic water ion generator according to the present invention.

Fig. 7 is a sectional view of an angle of a fifth embodiment of the magnetic rotary water ion generator according to the present invention.

Fig. 8 is a cross-sectional view of the magnetic water-rotating ion generator according to the sixth embodiment of the present invention.

Fig. 9 is a structural view of the magnetic water ion generator according to another angle of the sixth embodiment of the present invention.

Detailed Description

Referring to fig. 1 and 2, the magnetic water-rotating ion generator of the present invention includes an annular and magnetic electrode ring 10 and a negative electrode assembly 20. The negative pole subassembly 20 includes negative pole needle 21, the upper end of negative pole needle 21 is located under the electrode ring 10, just the axis of negative pole needle 21 with the central axis of electrode ring 10 overlaps. In this embodiment, the cathode assembly 20 further includes a first thermoelectric device 23 and a cathode positioning seat 22, the cathode positioning seat 22 is installed on the top of the first thermoelectric device 23, and the lower end of the cathode pin 21 is vertically and fixedly installed on the cathode positioning seat 22. The electrode ring 10 includes an annular first support electrode 11 and a first insulating electromagnetic coil 12, a first coil groove 111 is formed in a side wall of the first support electrode 11, and the first insulating electromagnetic coil 12 is wound in the first coil groove 111.

Referring to fig. 1 to 4, unlike the first embodiment, at least two discharge needles 112 uniformly extend downward and inward from the lower end of the inner wall of the central hole of the first holder electrode 11, and the discharge needles 112 are located on the upper periphery of the negative electrode needle 21. In this embodiment, the number of the discharging needles 112 is four.

Referring to fig. 1, fig. 2 and fig. 5, different from the first embodiment, the electrode ring 10 includes an annular second support electrode 13 and a magnetic ring 14 made of a magnetic material, a side wall of the second support electrode 13 is recessed inward to form a magnetic ring sleeve groove 131, and the magnetic ring 14 is sleeved in the magnetic ring sleeve groove 131.

Referring to fig. 1, 2 and 6, the electrode ring 10 is a ring-shaped ring plate 101 made of a ferromagnetic material, unlike the first embodiment. The electrode ring 10 may also be formed by stacking at least two ring segments 101 made of annular ferromagnetic material.

Referring to fig. 1, 2, 6 and 7, unlike the fourth embodiment, a chamfer 102 is formed on a lower portion of an inner wall of a central hole of the electrode ring 10 (i.e., the ring piece 101).

Referring to fig. 8 and 9, the magnetic water-rotating ion generating device includes an annular and magnetic electrode ring 10, a negative electrode assembly 20, and a transition electrode assembly 30. The negative pole subassembly 20 includes negative pole needle 21, the upper end of negative pole needle 21 is located under the electrode ring 10, just the axis of negative pole needle 21 with the central axis of electrode ring 10 overlaps. Specifically, the transition pole assembly 30 includes a transition pole 31, a transition pole positioning seat 32, and a second thermoelectric device 33. The electrode ring 10 includes an annular third support electrode 15 and a second insulating electromagnetic coil 16, a third coil groove 151 is formed in a side wall of the third support electrode 15, and the second insulating electromagnetic coil 16 is wound in the third coil groove 151. The transition pole 31 is located between the negative pole needle 21 and the third support electrode 15 and is located on one side of the central axis of the negative pole needle 21. The free end of the transition pole 31 is perpendicular to the central axis of the negative pole pin 21, the fixed end of the transition pole 31 is vertically and fixedly mounted at one end of the transition pole positioning seat 32, and the other end of the transition pole positioning seat 32 is fixedly mounted on the second thermoelectric device 33.

The utility model discloses magnetism of magnetic rotation water ion generating device's electrode ring area, discharge and take place in magnetic field, make the electric field take place to force the rapid deflection, form an electric arc face, can more effectual collection hydrone all around, simultaneously, greatly increased electric arc and fluidic contact surface, in addition, after magnetic field and electric field strength reached the certain degree, can form ion wind, fluid passes electric arc face with higher speed to increase the formation of beneficial composition and improve the generating speed of beneficial composition.

The present invention has been described in connection with the preferred embodiments, but the present invention is not limited to the embodiments disclosed above, and various modifications, equivalent combinations, which are made according to the essence of the present embodiment, should be covered.

Claims (9)

1. A kind of magnetic rotation water ion generating device, characterized by: including annular and take magnetic electrode ring and negative pole subassembly, the negative pole subassembly includes the negative pole needle, the upper end of negative pole needle is located under the electrode ring, just the axis of negative pole needle with the central axis of electrode ring overlaps mutually.

2. A magnetic water ion generator according to claim 1, wherein: the negative electrode assembly further comprises a first thermoelectric device and a negative electrode positioning seat, the negative electrode positioning seat is installed at the top of the first thermoelectric device, and the lower end of the negative electrode pin is vertically and fixedly installed on the negative electrode positioning seat.

3. A magnetic water ion generator according to claim 2, wherein: the electrode ring comprises a first annular support electrode and a first insulating electromagnetic coil, a first coil groove is formed in the side wall of the first support electrode, and the first insulating electromagnetic coil is wound in the first coil groove.

4. A magnetic water ion generator according to claim 3, wherein: the lower end of the inner wall of the central hole of the first support electrode uniformly extends downwards and inwards to form at least two discharge needle heads, and the discharge needle heads are positioned on the periphery above the negative pole needles.

5. The magnetic water ion generator according to claim 4, wherein: the number of the discharging needle heads is four.

6. A magnetic water ion generator according to claim 2, wherein: the electrode ring comprises an annular second support electrode and a magnetic sleeve ring made of a magnetic material, the side wall of the second support electrode is recessed inwards to form a magnetic ring sleeve groove, and the magnetic sleeve ring is sleeved in the magnetic ring sleeve groove.

7. A magnetic water ion generator according to claim 2, wherein: the electrode ring is a ring piece made of annular strong magnetic materials or is formed by overlapping at least two ring pieces made of annular strong magnetic materials.

8. A magnetic water ion generator according to claim 7, wherein: and the lower part of the inner wall of the central hole of the electrode ring is provided with a chamfer.

9. A magnetic water ion generator according to claim 1, wherein: the transition pole assembly comprises a transition pole, a transition pole positioning seat and a second thermoelectric device, the electrode ring comprises an annular third support electrode and a second insulating electromagnetic coil, a third coil groove is formed in the side wall of the third support electrode, the second insulating electromagnetic coil is wound in the third coil groove, the transition pole is located between the negative pole needle and the third support electrode and located on one side of the central axis of the negative pole needle, the free end of the transition pole is perpendicular to the central axis of the negative pole needle, the fixed end of the transition pole is vertically and fixedly installed at one end of the transition pole positioning seat, and the other end of the transition pole positioning seat is fixedly installed on the second thermoelectric device.

Images