TWI659930B - Liquid magnetization device, liquid processing activator and liquid processing equipment - Google Patents

Abstract

The invention provides a liquid magnetization device, a liquid processing activator, and a liquid processing equipment, wherein The liquid treatment activator has a flow guiding unit formed by connecting a liquid collecting base and a liquid discharging base, a liquid magnetization device is disposed inside the flow guiding unit, and a container has a lid body and a bottle body. Capable of accommodating diversion units. The liquid magnetization device has a plurality of magnets spaced coaxially and in the same polarity and opposite directions. The liquid collecting base of the flow guiding unit has a set of connection portions and is provided with a plurality of flow guiding grooves. The liquid discharging base has a first guide. The flow guiding part and a second flow guiding part, and the first flow guiding part is sleeved with the connection sleeve part, and the cover body is covered at the bottle opening and the second flow guiding part at the same time, thereby facilitating the operation of the user to carry out the liquid Activation treatment.

Description

Liquid magnetization device, liquid processing activator and liquid processing equipment

The present invention relates to the water treatment technology described in International Patent Classification No. C02F, specifically a liquid magnetization device, and a liquid treatment activator and a liquid treatment device combining the foregoing liquid magnetization device, which can improve the quality of water resources.

Due to the pollution of the earth's water resources and the deterioration of the living environment, agricultural and forestry irrigation, animal husbandry, drinking water at home, washing fruits and vegetables, beauty bathing, and even portable drinking water have been greatly affected. Most of the existing water treatment devices are water filters to filter water quality and lack energy-enhancing equipment. Even though a few water treatment devices are provided with energy-enhancing equipment, they are not portable and popular because of their large size and weight. Therefore, how to cooperate with the filtration system to use light waves and magnetic energy technology to perform diversified energy conversions and refine liquid molecules (such as water molecules) to improve and enhance the quality of water resources. Therefore, the pursuit of health and the energy-saving and environmentally friendly life of the planet has become Important issues for human survival in this century.

The purpose of the present invention is to solve the above problems, and provide a liquid magnetization device, a liquid processing activator, and a liquid processing equipment, which can reduce the liquid molecular clusters after processing, have the characteristics of antibacterial effect, reduce scale, energy saving and environmental protection.

The present invention provides a liquid magnetization device, which includes a casing and a plurality of magnets coaxially disposed inside the casing. Two adjacent magnets of the magnets are arranged at intervals with the same polarity and opposite directions.

Thereby, the mutually exclusive response of the magnet can generate a unipolar magnetic field, and provide an excellent liquid magnetization effect.

The invention also provides a liquid treatment activator, which includes a flow guiding unit, which has a liquid collecting base and a liquid discharging base connected, the liquid collecting base has a set of connecting parts, and the connecting part is provided with a plurality of guides. A flow channel, a liquid discharge base having a first flow guiding portion and a second flow guiding portion connected to each other, and the first flow guiding portion is connected to the socket portion; a liquid magnetization device is disposed inside the flow guiding unit; and A container has a bottle body to receive a flow guiding unit, and a cover body can be detached and placed on the bottle body and the liquid discharge base.

In a preferred embodiment, the liquid magnetization device is disposed at the center of the socket portion and extends into the first flow guiding portion, so that the liquid inside the flow guiding unit can be fully activated.

In actual use, after the liquid enters the liquid treatment activator, the alternating water flow swirls in the magnetic field generated by the liquid magnetization device, and is spun out in counterclockwise directions by the corresponding angled grooves at the magnetic cavity. Induced by the repulsive magnetic field again, the liquid is cut by the magnetic field lines at multiple angles and multiple times in a multi-dimensional direction, so that the negatively charged electrons are separated from the atomic nucleus, achieving a high-quality resonance effect.

The present invention further provides a liquid processing equipment, including the aforementioned liquid processing activator; a circulation pipeline connected to the cover of the liquid processing activator, and the circulation pipeline has a liquid inlet end and a liquid outlet end, and the circulation The pipeline is provided with a main diverter valve at the liquid inlet end and the liquid outlet end respectively; a filter is provided between the liquid inlet and the liquid processing activator; and a pump is provided between the filter and the liquid processing activator.

Thereby, the processing process of the liquid processing equipment can effectively filter impurities in the liquid and activate the liquid. Specifically, the liquid is first filtered through a filter, and the filtered liquid is pumped and pumped to a liquid processing activator to achieve the purpose of refining water molecules.

In a preferred embodiment, the liquid processing equipment may further be provided with at least one waveguide unit, which is matched with the characteristics of the light wave generator to pass a high-frequency oscillating water flow through a unipolar magnetic field and use resonance to increase the rate of electron transfer in the water, which can not only promote water The redox reaction can reach the most effective intermediate (activated complex), which resonates in the magnetized water flow at super speed, and can produce high-energy small molecular water.

In a preferred embodiment, the liquid processing equipment may further be provided with a mineral element release unit that can communicate with the liquid processing activator through a shunt pipe, and then pass through the diversion unit to alternately swing forward and backward in an oscillating manner to enhance the liquid activation effect.

In summary, the liquid magnetization device, liquid treatment activator and liquid treatment equipment provided by the present invention are different from the existing water treatment equipment and have the advantages of lightness and high efficiency, which not only helps to popularize and improve the quality of water resources , It can be quite helpful to human drinking, agriculture and forestry irrigation, animal husbandry, and global environmental protection.

100‧‧‧Liquid treatment activator

10‧‧‧ Diversion unit

11‧‧‧ collection base

111‧‧‧Socket

112‧‧‧ diversion trough

113‧‧‧ positioning block

12‧‧‧ Discharge base

121‧‧‧First Diversion Section

122‧‧‧Second Diversion Section

123‧‧‧through hole

124‧‧‧ limit slot

125‧‧‧O-ring

126‧‧‧Connecting port

13‧‧‧Liquid magnetization device

131‧‧‧magnet

14‧‧‧ Elastomer

15‧‧‧Screw

20‧‧‧ container

21‧‧‧ Cover

22‧‧‧ Bottle

23‧‧‧Inlet

24‧‧‧ Outlet

25‧‧‧Diversion channel

26‧‧‧ divider

30‧‧‧Circulation pipeline

31‧‧‧Inlet end

32‧‧‧ liquid outlet

33‧‧‧Main diverter valve

40‧‧‧Filter

50‧‧‧Pump

51‧‧‧Solenoid valve

60‧‧‧waveguide unit

61‧‧‧Filter media

611‧‧‧filter

62‧‧‧Anti-rust Magnetic Bar

63‧‧‧Fixed

64‧‧‧light wave generator

65‧‧‧controller

66‧‧‧Protective sleeve

67‧‧‧Insulation collar

70‧‧‧ mineral element release unit

71‧‧‧ lumen

72‧‧‧ Liquid inlet

73‧‧‧Discharge Department

74‧‧‧ filter cover

741‧‧‧Filter media

742‧‧‧accommodation space

743‧‧‧outlet

75‧‧‧Filter

751‧‧‧ bezel

76‧‧‧ mineral element body

80‧‧‧ split line

81‧‧‧time diverter valve

FIG. 1 is a perspective view of a liquid treatment activator according to the present invention.

Fig. 2 is an exploded view of the structure of a liquid treatment activator according to the present invention.

FIG. 3 is a schematic view showing a state in which the liquid treatment activator of the present invention is applied to a container.

FIG. 4 is a sectional view of a liquid treatment activator applied to a container according to the present invention.

FIG. 5 is an exploded view of a liquid treatment activator according to the present invention applied to another container.

FIG. 6 is a schematic sectional view of a lid body of a container according to the present invention.

FIG. 7 is a schematic diagram of liquid flow of a liquid treatment activator according to the present invention.

FIG. 8 is a schematic structural diagram of a liquid processing equipment according to the present invention.

FIG. 9 is a schematic structural diagram of a waveguide unit according to the present invention.

FIG. 10 is an exploded view of the structure of the mineral element release unit of the present invention.

FIG. 11 is a schematic diagram of the liquid flow of the mineral element release unit of the present invention.

Fig. 12 is a schematic diagram (a) of the liquid flow of the present invention, showing the liquid circulating back to the filter element.

FIG. 13 is a schematic diagram (2) of the liquid flow of the present invention, showing that the liquid flows back to the diversion unit.

FIG. 14 is a schematic structural diagram of another embodiment of a waveguide unit according to the present invention.

In order to facilitate the description of the specific embodiments of the present invention and achieve effects, the following expressions are given in conjunction with the drawings and specific examples. The dimensional ratios of the elements in each drawing are drawn for the convenience of those skilled in the art, and are not actual element sizes. Let me explain first.

Please refer to FIG. 1 to FIG. 4. The present invention provides a liquid treatment activator 100 mainly composed of a diversion unit 10 and a container 20. The structure of each element is described as follows:

The diversion unit 10 is provided with a liquid collecting base 11, a liquid discharging base 12 and a liquid magnetizing device 13 which are sleeved with each other. The liquid collecting base 11 and the liquid discharging base 12 are detachably connected. The liquid magnetization device 13 is disposed between the liquid collection base 11 and the liquid discharge base 12. Among them, the liquid collecting base 11 has a set of connecting portions 111, and the connecting portion 111 is used for sleeve connection to the liquid discharging base 12, and the connecting portion 111 is provided with a plurality of guide grooves 112 in a radial angular interval ring. The liquid base 11 is provided with two positioning blocks 113 on the outer periphery of the socket portion 111, and each of the guide grooves 112 is inclined at equal angular intervals, so that the liquid collection base 11 and the liquid discharge base 12 pass through the guide groove 112 to each other. The communication channel 112 is used to provide a counter-clockwise swirling effect (can be changed to clockwise in other embodiments). In addition, the liquid discharge base 12 has a first flow guide portion 121 and a second flow guide portion 122, and the first flow guide portion 121 communicates with the liquid discharge port 24 through a plurality of through holes 123. In this embodiment, the first diversion portion 121 receives a socket portion 111 on which the liquid collection base 11 is sleeved, and the liquid discharge base 12 is provided with two limiting grooves 124 on the outer periphery of the first diversion portion 121. The limiting slot 124 can be engaged with the two positioning blocks 113 of the socket 111.

In addition, the second flow guiding portion 122 is sleeved with an elastic body 14 to be able to abut against a cover body 21, and the elastic body 14 normally abuts against the cover body 21, thereby improving the leak-proof effect of the cover body 21.

The flow guiding unit 10 further includes a liquid magnetization device 13 disposed at a central portion of the liquid collecting base 11 along the long axis of the liquid collecting base. Among them, a plurality of magnets 131 are arranged at an axial distance in the casing of the liquid magnetization device 13. Adjacent two magnets 131 are arranged at intervals with the same polarity facing each other, so that the adjacent two magnets 131 repel each other. In this embodiment, the number of the magnets 131 is four and each of the magnets 131 is axially disposed on a screw. 15, and the magnet 131 is positioned by a nut screwed on the screw 15, and the distance between the magnets can be adjusted to change the size of the magnetic field. The aforementioned screw 15 and the nut are non-magnetic conductive materials to facilitate positioning operations.

It is added that the nanometer catalyst unit (not shown) can be sleeved on the liquid magnetization device 13 at one end of the first diversion section 121. The nanometer catalyst unit has a tubular silicone sleeve, and At least one silicone ring is connected to the outer edge of the silicone sleeve. The material of the silicone sleeve and the silicone ring contains a nano-grade precious metal catalyst material, and at least one nano-catalyst ceramic bead is fixed in the silicone ring, which is strengthened by the nano-catalyst. Antibacterial and catalytic effects, which in turn enhance the effect of liquid magnetization.

The container 20 has a lid body 21 and a bottle body 22 for accommodating the flow guiding unit 10, so that the second flow guiding portion 122 abuts the bottle mouth of the bottle body 22. The cover 21 is partially fitted into the inside of the second flow guiding portion, and can be detached and sealed at the mouth of the bottle 22. Please refer to FIG. 1 to FIG. 4. In this embodiment, an O-ring 125 is provided on the inner edge ring of the second guide portion 122. The O-ring 125 is elastically sleeved on the cover 21 to guide the flow. The unit 10 is housed in the bottle body 22. During use, the liquid is filled in the bottle body 22, and the guide unit 10 is extended into the bottle body 22 through the cover body 21. At this time, the user can hold the bottle body 22 and oscillate up and down to make the liquid resonate at The diversion unit 10 is activated to drink the activated liquid to achieve a healthy effect.

It is worth mentioning that the diversion unit 10 can be detached separately and used with a general cup.

As shown in FIG. 5 to FIG. 7, another embodiment of the present invention is to use the aforementioned diversion unit 10 with a container 20 of another configuration. The cover 21 of the container 20 has a liquid inlet 23, a liquid outlet 24, and a diversion channel 25. The liquid inlet 23 communicates with the diversion channel 25 and does not directly communicate with the liquid outlet 24. Among them, the diversion channel 25 is concavely formed by the liquid inlet 23 in a clockwise direction, and the liquid discharge base 12 communicates with the liquid outlet 24. The diversion channel 25 is used to swirl the liquid into the bottle body 22, and finally The diversion unit 10 swirls to the pressured flow to the liquid outlet 24 and exits.

In addition, the cover body 21 is further provided with a separator 26, which is sleeved on the second guide portion 122 so that the liquid inlet 23 and the liquid outlet 24 are not connected to each other, and communicate with the liquid outlet through the through hole 123 Port 24 and second A plurality of communication ports 126 are provided in a radial ring of the flow guiding portion 122, and the communication ports 126 communicate with the liquid inlet 23 and the inside of the bottle body 22.

According to this, when the liquid is introduced into the bottle body 22 from the liquid inlet 23 of the lid 21, the liquid first swirls in a clockwise direction along the diversion channel 25, and then swirls to flow through the communication port 126 of the second diversion portion 122 When the liquid flows down to the bottom of the bottle body 22 (in a closed state), the liquid will swirl back upward, and will be guided counterclockwise by the guide groove 112 of the sleeve portion 111, and due to the With a small aperture, the liquid will be spirally introduced into the first diversion section 121 under pressure, and finally output from the liquid outlet 24 for external use.

In this way, the liquid flow swirling direction in the bottle body 22 and the liquid flow swirling direction of the diversion unit 10 are opposite to each other, and the liquid swirling flow of the diversion groove 112 is multi-dimensionally cut by the magnetic lines of force of the liquid magnetization device 13, which is prone to swirl Resonance, and due to the narrow tube effect, enhance the liquid flow velocity, and then refine the molecular cluster structure, increase the penetration force to make the human body or animals and plants more effective absorption in use.

Please refer to FIG. 8 to FIG. 14. The present invention further provides an embodiment of a liquid processing device, which is combined with the aforementioned liquid processing activator 100, and the liquid processing activator 100 includes a diversion unit 10 and a diversion unit 10. Housed in a container 20.

The liquid processing equipment includes a circulation pipeline 30, a filter 40, a pump 50, at least a waveguide unit 60, and a mineral element release unit 70.

The circulation pipeline 30 communicates with the liquid processing activator 100 and is connected to the cover 21, and the circulation pipeline 30 has a liquid inlet 31 and a liquid outlet 32, wherein the liquid inlet 31 receives the liquid input to the outside, wherein The external liquid can be water or tea to be filtered, and the circulation pipeline 30 is provided with a main diverter valve 33 at the liquid inlet 31 and the liquid outlet 32, respectively. And outlet end 32.

The filter element 40 communicates with the circulation pipeline 30 and is disposed between the liquid inlet 31 and the liquid processing activator 100, and is used for receiving and filtering the liquid at the liquid inlet 31. A plurality of filter materials are arranged in the filter element 40 along the axial direction (Not shown). In this embodiment, the filter material may be a far-infrared filter material, which provides impurities with a small aperture to filter external liquids, and releases far-infrared in the liquid to increase the energy of the liquid.

The pump 50 is provided between the filter 40 and the liquid processing activator 100, and is mainly used as a driving force to extract and transmit the filtered liquid introduced by the filter 40 to the liquid processing activator 100 for activation, and the liquid activated by the liquid processing activator 100 Through the main diverter valve 33, it can be selected to be used by the liquid outlet 32 or continued to circulate in the circulation line 30.

The pump 50 is electrically connected with a solenoid valve 51. The solenoid valve 51 is used to sense the pressure of the liquid output from the pump 50. When the pressure is too high, the solenoid valve 51 will automatically power off to maintain the safe operation of the pump 50.

The waveguide unit 60 communicates with the circulation pipeline 30 and is disposed between the pump 50 and the liquid treatment activator 100, and is used for filtering again. In this embodiment, the number of the waveguide units 60 is one, and in other embodiments, it may be plural. Each. The waveguide unit 60 may be an empty tube made of a metal material with good anti-rust properties. The waveguide unit 60 is provided with multiple filter materials 61 and multiple anti-rust magnetic rods 62 in the axial direction. Each filter material 61 is a far-infrared filter material. A plurality of filter holes 611 are provided for the liquid to pass through the waveguide unit 60.

As shown in FIG. 9, the filter materials 61 are spaced apart from each other, and the rust-proof magnetic energy rods 62 are fixed between every two filter materials 61, wherein the magnetic field energy of each rust-proof magnetic energy rods 62 can activate the liquid and further refine the molecular clusters of the liquid. Structure, to enhance the effect of rapid absorption of permeation, and a fixed base 63 is provided on each side of the top and bottom of each filter medium 61. In the embodiment of the present invention, a convex block is provided at the bottom of each fixed base 63, so that convex blocks can be used to cooperate with unevenness. The method is installed in the filter holes 611 of each filter material 61, so that each fixing seat 63 can receive and fix the end of each rust-proof magnetic energy rod 62, and the rust-proof magnetic energy rods 62 are stably installed in the waveguide unit 60 axially.

In addition, one end of the waveguide unit 60 remote from the filter 40 is electrically connected with a light wave generator 64 for introducing light wave energy into the liquid. Specifically, the light wave generator 64 is electrically connected to a controller 65, and the controller 65 controls the operating time of the light wave generator 64 and generates low-watt power. In addition, a protective sleeve 66 is provided on the outer periphery of the waveguide unit 60, and two ends of the waveguide unit 60 are respectively provided with an insulating collar 67, and the two insulating collars 67 are used to respectively connect the circulating pipeline 30. When the light wave generator 64 When conducting, it prevents leakage of current.

The mineral element release unit 70 is disposed between the liquid treatment activator 100 and the filter element 40, and the mineral element release unit 70 communicates with the circulation pipeline 30 and the liquid treatment activator 100 through a branch pipe 80. Among them, the shunt pipe 80 is provided with a primary shunt valve 81 between the circulation pipe 30 and the mineral element release unit 70. The secondary shunt valve 81 is used to rotate the liquid in the circulation control pipe 30 to the mineral element release unit 70, and The mineral element release unit 70 has an inner cavity 71, which is connected to a liquid inlet portion 72 and a liquid outlet portion 73 of one of the bypass pipes 80, respectively, and the inner cavity 71 is provided with a filter cover 74 and a filter core 75 in the axial direction. A plurality of mineral element bodies 76 are provided between the filter cover 74 and the filter core 75.

The top of the filter cover 74 is provided with a filter material 741, and the filter cover 74 is provided with an accommodating space 742 and a plurality of liquid outlet holes 743. The accommodating space 742 is used to place the mineral element body 76 and communicate with the filter material 741, and the liquid outlet hole 743 The ring is arranged around the filter cover 74 so that the accommodation space 742 and the inner cavity 71 communicate with each other.

The filter core 75 may be nano-silver ion activated carbon. The top of the filter core 75 is sleeved on the filter cover 74, and a plurality of baffles 751 are provided on the top of the filter core 75, and are set in the accommodation space 742 of the filter cover 74 for The stable mineral element body 76 is accommodated between the filter cover 74 and the filter core 75 to prevent the mineral element body 76 from detaching into the inner cavity 71.

Please refer to Figure 8 to Figure 12. When in use, the main diverter valve 33 of the circulation pipeline 30 opens the liquid inlet 31 to input external liquid. At this time, the liquid will first pass to the filter 40 for filtering and be in the liquid. The far-infrared rays are released to increase the energy of the liquid, and the pump 50 can provide power to extract the liquid to the waveguide unit 60 and filter it again. The magnetic field energy of the rust-proof magnetic rods 62 in the waveguide unit 60 will activate the liquid, and then refine the liquid. The molecular cluster structure enhances the effect of rapid absorption of penetration, and the activation of the light wave generator 64 can further strengthen the liquid energy and refinement effect.

Subsequently, the liquid is guided to the liquid processing activator 100, and the liquid flow in the bottle body 22 and the liquid flow in the flow guide unit 10 may be opposite to each other, and the liquid in the flow guide 112 is subject to the liquid magnetization device. The magnetic field lines of 13 are multi-dimensionally cut, and it is easy to generate cyclotron resonance to refine the molecular cluster structure. Finally, it is exported from the liquid outlet 24 to the circulation pipeline 30. At this time, the liquid can be opened and closed through the main diverter valve 33, which can choose the activated liquid Output from the liquid outlet 32 for external use, or return to the filter 40 to continue circulation.

Please cooperate with Figures 11 and 13, when the user wants to increase the mineral content in the liquid, he can open the sub-dividing valve 81 of the diverting pipe 80, so that the liquid flows to the diverting pipe 80 and enters the mineral element release. In the unit 70, the liquid flows through the filter material 741 of the filter cover 74 and is introduced into the containing space 742, and the mineral element body 76 releases minerals in the liquid. In the embodiment, the mineral element body 76 may be nano-calcium ion beads, thereby releasing calcium ions in the liquid, and the liquid will flow into the inner cavity 71 through the liquid outlet hole 743 and enter the filter 75 to be filtered, and finally be filtered by the filter. The output of the heart 75 flows to the liquid processing activator 100 to continue activation, thereby increasing the activity of the liquid again, making it easier for the organism to absorb and promote growth during use.

Please refer to FIG. 14. In another embodiment provided by the present invention, the main structural difference is that the number of waveguide units 60 is three, the waveguide units 60 are arranged side by side, and the light wave generators 64 can be connected in series. Do not electrically connect the waveguide units 60 to further enhance the liquid energy and refinement effect.

The above-mentioned embodiments are only used to illustrate possible implementation modes of the present invention, and all modifications or changes that do not violate the technical core of the present invention shall fall into the scope of protection of the present invention.

Claims (10)

A liquid magnetization device includes a casing and a screw member coaxially disposed inside the casing, and two adjacent magnets of the magnets are spaced apart in the same polarity and opposite directions. The screw member At least one nut is screwed on to position one of the magnets, and the at least one nut can adjust the distance between the positioned magnet and its adjacent magnet. A liquid treatment activator includes: a flow guiding unit having a liquid collecting base and a liquid discharging base connected to each other, the liquid collecting base having a set of connection parts, and the sleeve part is provided with a plurality of connection parts. Flow guide grooves, the liquid discharge base has a first flow guide portion and a second flow guide portion, and the first flow guide portion is connected to the socket portion; The liquid magnetization device is disposed inside the flow guide unit; and a container having a bottle body to house the flow guide unit, and a cover portion fitted into the second flow guide portion, which can be Detach and cover the bottle body and the liquid discharge base. The liquid treatment activator according to claim 2, wherein the liquid magnetization device is disposed at the center of the provided socket portion and extends into the first flow guiding portion, and the liquid magnetization device is located at the first flow guiding portion A nano-catalyst unit is sleeved at one end. The liquid treatment activator according to claim 2, wherein the cover has an independent liquid inlet and a liquid outlet, and a diversion channel communicates with the liquid inlet, so that the diversion channel The liquid is introduced into the bottle body, and the liquid finally reaches the liquid outlet from the liquid discharge base of the diversion unit. The liquid treatment activator according to claim 4, wherein the diversion grooves are arranged obliquely and are arranged at equal intervals along a radial angle of the socket part, and the diversion channels and the diversion grooves are guided. The flow directions are clockwise and counterclockwise, respectively. The liquid treatment activator according to claim 4 or 5, wherein the cover body is provided with a partition sheet, the partition sheet is sleeved inside the second flow guide portion, and the second flow guide portion is radially The ring is provided with a plurality of communication ports, and communicates with the liquid inlet and the inside of the bottle body, and the separator is provided with a plurality of through holes to communicate the first flow guiding portion and the liquid outlet. A liquid processing equipment includes: a liquid processing activator as described in claim 2; a circulation pipeline connected to a cover of the liquid processing activator, and the circulation pipeline has a liquid inlet end and a A liquid outlet end, and the circulation pipeline is provided with a main diverter valve at the liquid inlet end and the liquid outlet end, respectively; a filter is provided between the liquid inlet end and the liquid processing activator; And a pump provided between the filter element and the liquid treatment activator. The liquid processing equipment according to claim 7, further comprising at least one waveguide unit connected to the circulation pipeline and disposed between the pump and the liquid treatment activator, and the waveguide unit is electrically connected with a light wave generator And the waveguide unit is provided with a plurality of rust-proof magnetic energy rods along its axial direction. The liquid processing equipment according to claim 8, wherein the waveguide unit is provided with a plurality of far-infrared filtering materials spaced apart in the axial direction, and the filtering materials are respectively provided with a fixing seat for holding the rust-proof magnetic energy rod. A protective sleeve is provided on the outer periphery of the waveguide unit, and two ends of the waveguide unit are respectively provided with an insulating collar. The liquid processing equipment according to any one of claims 7 to 9, further comprising a mineral element release unit provided between the liquid treatment activator and the filter element, and the mineral element release unit passes through a bypass pipe. The circulation pipeline and the liquid processing activator communicate with each other. The mineral element release unit has an inner cavity, and the inner cavity is provided with a filter cover and a filter core in the axial direction. A plurality of mineral element bodies are provided, and the liquid in the shunt pipeline enters the inner cavity through the filter cover.