CN113087067B - Terahertz water rearrangement intelligent monitoring system and intelligent monitoring method - Google Patents

Abstract

The invention discloses an intelligent monitoring system and an intelligent monitoring method for terahertz water rearrangement, including a first preparation device, a second preparation device and a server; the electromagnetic wave intensity of the terahertz wave generated by the first terahertz water preparation component is the first initial electromagnetic wave intensity value, and the first terahertz detector obtains the first current electromagnetic wave intensity value; the second preparation device is used as the control device of the preparation process, the electromagnetic wave intensity of the terahertz wave generated by the second terahertz water preparation component is the second initial electromagnetic wave intensity value, and the second terahertz detector obtains the second current electromagnetic wave intensity value; if (the first current electromagnetic wave intensity value-the first current electromagnetic wave intensity value)-(the second current electromagnetic wave intensity value-the second current electromagnetic wave intensity value) is greater than 0, the water molecule rearrangement prompt message is sent to the user terminal. As a control group experiment is set up, it can effectively prove that water can absorb terahertz electromagnetic waves and cause molecular rearrangement.

Description

Terahertz water rearrangement intelligent monitoring system and intelligent monitoring method

Technical Field

The invention relates to the technical field of internet, in particular to a terahertz water rearrangement intelligent monitoring system and an intelligent monitoring method.

Background

The production and life of human beings can not be separated from water, and with the development of scientific technology, people find that the spatial configuration of water molecules can be changed by carrying out physical treatment on common water, for example, the water molecules of the common water are rearranged in the spatial configuration through a certain treatment step to form terahertz water, and devices capable of preparing the terahertz water exist in the prior art.

However, the existing terahertz water preparation device only emits terahertz waves into water, and whether the water absorbs the terahertz waves or not is not effectively monitored, so that rearrangement of water molecules is realized. Therefore, the existing terahertz water preparation device cannot effectively monitor whether the water absorbs the terahertz waves or not.

Disclosure of Invention

The embodiment of the invention provides a terahertz water rearrangement intelligent monitoring system and an intelligent monitoring method, and aims to solve the problem that a terahertz water preparation device in the prior art cannot effectively monitor whether water absorbs terahertz waves or not.

In a first aspect, an embodiment of the present invention provides a terahertz water rearrangement intelligent monitoring system, which includes 2 preparation devices, which are sequentially marked as a first preparation device and a second preparation device; the first preparation device and the second preparation device are in communication connection with the server;

the first preparation device comprises a first shell, a first hollow bracket arranged in the first shell and a first cover plate covering the first shell; the first cover plate is provided with a first water inlet pipe and a first control switch for controlling the opening and closing of the first water inlet pipe; a first microporous filter plate is arranged in the first shell and divides a first closed space formed by tightly covering the first cover plate on the first shell into a first pressurizing cavity and a first water storage cavity; a first terahertz water preparation assembly is arranged in the first hollow support and is used for preparing terahertz water in the first pressurizing cavity and the first water storage cavity to obtain terahertz water; the first preparation device further comprises a first terahertz detector arranged on the lower end face of the first cover plate and used for detecting the electromagnetic wave intensity in the current environment;

the second preparation device comprises a second shell, a second hollow bracket arranged in the second shell and a second cover plate covering the second shell; a detachable metal separation plate is arranged in the second shell, a second closed space formed by tightly covering the second cover plate on the second shell is divided into an upper chamber and a lower chamber by the detachable metal separation plate, dry pottery clay is contained in the upper chamber, and the laying height of the dry pottery clay contained in the upper chamber is the same as the height of water contained in the first pressurizing chamber; a second terahertz water preparation assembly is arranged in the second hollow support; the second preparation device further comprises a second terahertz detector arranged on the lower end face of the second cover plate and used for detecting the electromagnetic wave intensity in the current environment.

In a second aspect, an embodiment of the present invention provides an intelligent monitoring method for a terahertz water rearrangement intelligent monitoring system, including:

controlling the first terahertz water preparation assembly and the second terahertz water preparation assembly to be started and to be closed after a preset starting time threshold is started, wherein the working powers of terahertz waves generated by the first terahertz water preparation assembly and the second terahertz water preparation assembly are the same; wherein the electromagnetic wave intensity of the terahertz waves generated by the first terahertz water preparation component is a first initial electromagnetic wave intensity value, the electromagnetic wave intensity of the terahertz waves generated by the second terahertz water preparation component is a second initial electromagnetic wave intensity value, and the second initial electromagnetic wave intensity value is equal to the first initial electromagnetic wave intensity value;

acquiring a first current electromagnetic wave intensity value in the first pressurizing cavity through a first terahertz detector, and acquiring a second current electromagnetic wave intensity value in the upper cavity through a second terahertz detector;

sending the first initial electromagnetic wave intensity value, the second initial electromagnetic wave intensity value, the first current electromagnetic wave intensity value and the second current electromagnetic wave intensity value to a server;

obtaining a first difference intensity value in the server by the first difference intensity value = first current electromagnetic wave intensity value-first current electromagnetic wave intensity value, and obtaining a second difference intensity value in the server by the second difference intensity value = second current electromagnetic wave intensity value-second current electromagnetic wave intensity value;

obtaining a difference value between the first difference intensity value and the second difference intensity value as a comparison difference value;

and if the contrast difference value is larger than 0, the server sends the water molecule rearrangement prompt information to a user side in communication connection with the server.

The embodiment of the invention provides a terahertz water rearrangement intelligent monitoring system and an intelligent monitoring method, wherein the terahertz water rearrangement intelligent monitoring system comprises 2 preparation devices which are sequentially marked as a first preparation device and a second preparation device; the system also comprises a server; the method comprises the steps that terahertz water is prepared from water in a first pressurizing cavity and a first water storage cavity through a first terahertz water preparation assembly in a first preparation device, so that terahertz water is obtained, the electromagnetic wave intensity of terahertz waves generated by the first terahertz water preparation assembly is a first initial electromagnetic wave intensity value, and a first current electromagnetic wave intensity value in the first pressurizing cavity is obtained through a first terahertz detector; taking second preparation equipment as comparison group equipment in the preparation process, transmitting terahertz electromagnetic waves into the upper cavity through a second terahertz water preparation assembly in a second preparation device, wherein the electromagnetic wave intensity of the terahertz waves generated by the second terahertz water preparation assembly is a second initial electromagnetic wave intensity value, and acquiring a second current electromagnetic wave intensity value in the upper cavity through a second terahertz detector; and obtaining a first difference intensity value by the first difference intensity value = first current electromagnetic wave intensity value-first current electromagnetic wave intensity value, obtaining a second difference intensity value by the second difference intensity value = second current electromagnetic wave intensity value-second current electromagnetic wave intensity value, and sending the water molecule rearrangement prompt message to a user side in communication connection with the server if the difference value between the first difference intensity value and the second difference intensity value is larger than 0. Due to the fact that a control group experiment is arranged, the fact that water can absorb terahertz electromagnetic waves and molecular rearrangement occurs can be effectively proved.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without creative efforts.

Fig. 1 is a structural block diagram of a terahertz water rearrangement intelligent monitoring system provided in an embodiment of the present invention;

fig. 2 is an overall structural diagram of a first preparation device and a second preparation device in the terahertz water rearrangement intelligent monitoring system provided in the embodiment of the present invention;

fig. 3 is a partial structure diagram of a terahertz water rearrangement intelligent monitoring system provided in the embodiment of the present invention;

fig. 4 is a partial structure diagram of a terahertz water rearrangement intelligent monitoring system provided in the embodiment of the present invention;

fig. 5 is a partial structure diagram of a terahertz water rearrangement intelligent monitoring system provided in the embodiment of the present invention;

fig. 6 is a partial structure diagram of a terahertz water rearrangement intelligent monitoring system provided in the embodiment of the present invention;

fig. 7 is a partial structure diagram of a terahertz water rearrangement intelligent monitoring system provided in the embodiment of the present invention;

fig. 8 is a partial structure diagram of a terahertz water rearrangement intelligent monitoring system provided in the embodiment of the present invention;

fig. 9 is a partial structure diagram of a terahertz water rearrangement intelligent monitoring system provided in the embodiment of the present invention;

fig. 10 is a schematic circuit structure diagram of a first preparation apparatus in the terahertz water rearrangement intelligent monitoring system according to the embodiment of the present invention;

fig. 11 is a schematic circuit structure diagram of a second preparation apparatus in the terahertz water rearrangement intelligent monitoring system according to the embodiment of the present invention;

fig. 12 is a flowchart of an intelligent monitoring method of the terahertz water rearrangement intelligent monitoring system according to the embodiment of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, not all, embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It will be understood that the terms "comprises" and/or "comprising," when used in this specification and the appended claims, specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, and/or groups thereof.

It is also to be understood that the terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used in the specification of the present invention and the appended claims, the singular forms "a," "an," and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise.

It should be further understood that the term "and/or" as used in this specification and the appended claims refers to and includes any and all possible combinations of one or more of the associated listed items.

Referring to fig. 1 to 11, as shown in the drawings, an embodiment of the present invention provides a terahertz water rearrangement intelligent monitoring system, which includes 2 preparation apparatuses, which are sequentially denoted as a first preparation apparatus 100 and a second preparation apparatus 200; the system further comprises a server 300, wherein the first preparation device 100 and the second preparation device 200 are both in communication connection with the server 300;

the first preparation apparatus 100 includes a first casing 110, a first hollow support 120 disposed in the first casing 110, and a first cover plate 130 covering the first casing 110; the first cover plate 130 is provided with a first water inlet pipe 131 and a first control switch 132 for controlling the opening and closing of the first water inlet pipe 131; a first microporous filter plate 140 is disposed in the first casing 110, and the first microporous filter plate 140 divides a first closed space formed by tightly covering the first cover plate 130 on the first casing 110 into a first pressurization chamber 101 and a first water storage chamber 102; a first terahertz water preparation assembly 150 is arranged in the first hollow support 120 and is used for preparing terahertz water from the water in the first pressurizing cavity 101 and the water in the first water storage cavity 102 to obtain terahertz water; the first manufacturing apparatus 100 further includes a first terahertz detector 160 disposed on a lower end surface of the first cover plate 130, and configured to detect an electromagnetic wave intensity in a current environment;

the second preparation apparatus 200 includes a second housing 210, a second hollow bracket 220 disposed in the second housing 210, and a second cover plate 230 covering the second housing 210; a detachable metal partition plate 240 is arranged in the second shell 210, the detachable metal partition plate 240 divides a second closed space formed by tightly covering the second cover plate 230 on the second shell 210 into an upper chamber 201 and a lower chamber 202, dry pottery clay is contained in the upper chamber 201, and the laying height of the dry pottery clay contained in the upper chamber 201 is the same as the height of water contained in the first pressurizing chamber 101; a second terahertz water preparation assembly 250 is arranged in the second hollow support 220; the second manufacturing apparatus 200 further includes a second terahertz detector 260 disposed on a lower end surface of the second cover plate 230, and configured to detect an electromagnetic wave intensity in a current environment.

In the present embodiment, the first preparation apparatus 100 is a terahertz water preparation device and monitoring device, in which terahertz water is obtained by performing terahertz water preparation on water in the first pressurizing chamber 101 and the first water storage chamber 102 by the first terahertz water preparation assembly 150. Wherein, the terahertz (THz) wave is an electromagnetic wave with the frequency within the range of 0.1-10 THz (the wavelength is 3000-30 μm), coincides with millimeter wave in a long wave band and coincides with infrared light in a short wave band, is a transition region from a macroscopic classical theory to a microscopic quantum theory, is also a transition region from electronics to photonics, and is called as a terahertz gap (THz gap) of an electromagnetic spectrum. The terahertz electromagnetic wave can enable water molecule groups in the first pressurizing cavity 101 to generate resonance, the resonance can enable the water molecule groups to be activated, namely the original configuration of the water molecule groups is damaged through resonance, so that the water molecule groups containing more water molecules are converted into the water molecule groups containing less water molecules, and the preparation of the terahertz water is realized. Since the terahertz wave portion of the electromagnetic wave intensity emitted by the first terahertz water preparation assembly 150, which is the first initial electromagnetic wave intensity value, is absorbed by water to prepare the terahertz water, the first current electromagnetic wave intensity value obtained by the first terahertz detector 160 in the first pressure chamber 101 is necessarily smaller than the first initial electromagnetic wave intensity value, but it cannot be completely determined that the terahertz wave is absorbed by moisture to perform molecular rearrangement only through this determination process. A control test prepared in the second preparation apparatus 200 is required to be determined at this time.

The second preparation apparatus 200 is a control group apparatus of the preparation process in which the terahertz electromagnetic wave is also emitted into the upper chamber 201 by the second terahertz water preparation member 250, and the water in the first pressurizing chamber 101 is controlled by the dry kaolin contained in the upper chamber 201. The dry puddle can penetrate the terahertz waves, but the terahertz waves are transmitted to the upper end face of the detachable metal partition plate 240 and are reflected back, that is, the terahertz waves are not absorbed by the dry puddle and the detachable metal partition plate 240, so that the second current electromagnetic wave intensity value in the upper chamber 201 obtained by the second terahertz detector 260 is equal to or slightly less than (slightly less than the difference between the two does not exceed 2%) the second initial electromagnetic wave intensity value.

In order to determine whether the water molecules rearrange the absorption of the terahertz waves, the method can be implemented by:

controlling the first terahertz water preparation assembly 150 and the second terahertz water preparation assembly 250 to be both started and closed after a preset starting time threshold is started, wherein the working powers of terahertz waves generated by the first terahertz water preparation assembly 150 and the second terahertz water preparation assembly 250 are the same; wherein the electromagnetic wave intensity of the terahertz wave generated by the first terahertz water preparation component 150 is a first initial electromagnetic wave intensity value, the electromagnetic wave intensity of the terahertz wave generated by the second terahertz water preparation component 250 is a second initial electromagnetic wave intensity value, and the second initial electromagnetic wave intensity value is equal to the first initial electromagnetic wave intensity value;

acquiring a first current electromagnetic wave intensity value in the first pressurization cavity 101 through the first terahertz detector 160, and acquiring a second current electromagnetic wave intensity value in the upper cavity 201 through the second terahertz detector 260;

sending the first initial electromagnetic wave intensity value, the second initial electromagnetic wave intensity value, the first current electromagnetic wave intensity value and the second current electromagnetic wave intensity value to a server 300;

obtaining a first difference intensity value by the first difference intensity value = first current electromagnetic wave intensity value-first current electromagnetic wave intensity value in the server 300, and obtaining a second difference intensity value by the second difference intensity value = second current electromagnetic wave intensity value-second current electromagnetic wave intensity value in the server;

obtaining a difference value between the first difference intensity value and the second difference intensity value as a comparison difference value;

if the contrast difference value is greater than 0, the server sends the water molecule rearrangement prompt message to the user terminal 10 in communication connection with the server 300.

That is, by the above comparison, when the comparison difference value is greater than 0, it can be determined that the terahertz wave is mostly absorbed by water and water molecule rearrangement is transmitted. This is because the first difference intensity value is not close to 0 if the terahertz wave is absorbed by the bulk of water, and the second difference intensity value is equal to 0 or close to 0 if the terahertz wave is not absorbed by the dry puddle, so that when the difference between the first difference intensity value and the second difference intensity value (i.e., the control difference value) is greater than 0, it can be determined that the terahertz wave is absorbed by the bulk of water and water molecule rearrangement is transmitted.

In one embodiment, as shown in fig. 1 to 11, the first terahertz water preparation assembly 150 includes a first control board 151, a first motor 152, a first electromagnet 153 and a first inflator 154, which are disposed in the first hollow support 120, the first motor 152 is connected to the first electromagnet 153 through a first connecting shaft 155 and drives the first electromagnet 153 to rotate, and the first inflator 154 inputs gas to pressurize the first pressurizing chamber 101; a first terahertz antenna 156 is fixedly arranged on the outer wall of the first hollow bracket 120; a first air pressure sensor 157 communicated with the first pressurizing cavity 101 is further arranged on the side wall of the first hollow bracket 120; a first water level detector 158 and a second water level detector 159 are respectively disposed on the side walls of the first hollow bracket 120, the first water level detector 158 is used for detecting the water level of the first pressurized cavity 101, and the second water level detector 159 is used for detecting the water level of the first water storage cavity 102;

the first control board 151 is electrically connected to the first motor 152, the first electromagnet 153, the first inflator 154, the first air pressure sensor 157, the first water level detector 158, the second water level detector 159, the first terahertz antenna 156, the first terahertz detector 160, and the first control switch 132, respectively.

In this embodiment, the first water level detector 158 provided on the sidewall of the first hollow bracket 120 may communicate with the first pressurizing chamber 101, the water level in the first pressurizing chamber 101 does not exceed the first water level detector 158, and water as a conductor connects the two electrodes of the first water level detector 158, so that the first water level detector 158 may detect that the water level in the first pressurizing chamber 101 has not exceeded the first water level detector 158, and if the two electrodes of the first water level detector 158 are not connected, that is, it may indicate that the water level in the first pressurizing chamber 101 has not exceeded the first water level detector 158, the first water level detector 158 may accurately detect that the water level in the first pressurizing chamber 101 has not exceeded the first water level detector 158; the second water level detector 159 provided on the side wall of the first hollow bracket 120 may communicate with the first water storage chamber 102, and the second water level detector 159 detects the water level in the first water storage chamber 102 in the same manner as the first water level detector 158. Wherein, the wavelength of the electromagnetic wave emitted by the first terahertz antenna 156 is 15-600 μm.

The edge of the first casing 110 contacting the first cover plate 130 may further be provided with a first sealing strip 103, the first cover plate 130 tightly covers the first casing 110 to form a closed space, a first cover plate through hole is formed in the center (i.e., the center point) of the first cover plate 130, the first hollow bracket 120 may pass through the first cover plate through hole and extend out from the lower side thereof, an external thread (not shown in the figure) may be disposed on the outer side wall of the first hollow bracket 120, the bottom of the first hollow bracket 120 is provided with a plurality of first connecting posts 104 abutting against the bottom of the first casing 110, the first swivel nut 105 is sleeved on the outer side of the first hollow bracket 120 and tightened by the external thread disposed on the first hollow bracket 120, and the first cover plate 130 tightly covers the first casing 110 after the first swivel nut 105 is tightened. The first microporous filter plate 140 divides the enclosed space into a first pressurizing chamber 101 and a first water storage chamber 102, the first inflator 154 can input the external air into the first pressurizing chamber 101, and the pressure inside the first pressurizing chamber 101 can be maintained at a pressure higher than the external atmospheric pressure, so as to pressurize and filter the water inside the first pressurizing chamber 101 by the pressure, that is, the water inside the first pressurizing chamber 101 flows through the microporous filter plate 140 by the pressure and is filtered, the first water storage chamber 102 can be further provided with a first water tap 106, and the first water tap 106 can guide the water stored in the first water storage chamber 102 out for use. The first terahertz antenna 156 is used for emitting terahertz electromagnetic waves, the frequency of the electromagnetic waves emitted by the first terahertz antenna 156 is 0.5-20THz, and the wavelength of the electromagnetic waves corresponding to the frequency range of the electromagnetic waves is 15-600 μm. In order to enhance the resonance effect of the water molecular groups, the frequency of the electromagnetic wave may be further set to 2.5 to 12Thz, and the wavelength of the electromagnetic wave corresponding to the frequency range of the electromagnetic wave is 25 to 120 μm. The terahertz electromagnetic wave can cause the water molecule groups in the first pressurizing cavity 101 to generate resonance, and the resonance effect can activate the water molecule groups, that is, the original configuration of the water molecule groups is destroyed through resonance, so that the water molecule groups containing more water molecules are converted into the water molecule groups containing less water molecules. Magnetic lines of force are formed around the first electromagnet 153, the first electromagnet 153 is driven to rotate by the first motor 152, so that the water standing in the first water storage cavity 102 cuts the magnetic lines of force, the configuration of the activated water molecule groups is rearranged by the magnetic lines of force, activated water with a specific spatial configuration is formed, a large number of chain-shaped water molecule groups can be contained in the activated water, and the water molecules are rearranged according to the chain-shaped configuration to form the chain-shaped water molecule groups. Since the first motor 152 drives the first electromagnet 153 to rotate in the device, the water molecule cluster configuration in the first water storage cavity 102 can be continuously rearranged by the first electromagnet 153, so that the device can greatly improve the efficiency of rearranging the water molecule cluster configuration, that is, the generation efficiency of activated water can be greatly improved. The first control board 151 is used for sending control instructions to control the components, an MCU control chip is disposed on the first control board 151, the first air pressure sensor 157 is used for detecting the pressure in the first pressurizing chamber 101 and transmitting the pressure detection information to the first control board 151, the first control board 151 may control the stop and start of the first inflator 154 according to the pressure detection information, the first water level detector 158 may monitor the water level in the first pressurizing chamber 101, the second water level detector 159 may detect the water level in the first water storage chamber 102, the first control board 151 may acquire the water level information detected by the first water level detector 158 and the second water level detector 159, respectively, and may perform intelligent control on each component, therefore, the preparation process of the terahertz water is intelligently controlled, and the preparation efficiency of the terahertz water can be greatly improved.

In use, the first water level detector 158 first obtains the water level information of the first pressurized chamber 101, if the water level of the first pressurized chamber 101 does not exceed the first water level detector 158, the first control plate 151 sends control information to the first control switch 132 to turn on the first control switch 132 to replenish water into the first pressurized chamber 101, and if the first water level detector 158 detects that the water level of the pressurized chamber 101 does not exceed the first water level detector 158, the first control plate 151 sends control information to the first control switch 132 to turn off the first control switch 132. The first control board 151 sends control information to the first terahertz antenna 156, so that the first terahertz antenna 156 emits terahertz electromagnetic waves, and the single working time of the first terahertz antenna 156 can be set to 1-10min, so that water molecule groups in the first pressurizing cavity 101 can be resonated through the terahertz electromagnetic waves, and the water molecule groups can be activated through the resonance action. The water level information of the first water storage chamber 102 is obtained by the second water level detector 159, if the water level of the first water storage chamber 102 does not exceed the second water level detector 159, the first control board 151 sends control information to the first inflator 154, the first inflator 154 operates to raise the pressure inside the first pressurizing chamber 101, at this time, the first air pressure sensor 157 can detect the pressure inside the first pressurizing chamber 101, if the pressure inside the first pressurizing chamber 101 is higher than a certain pressure (e.g., 1.5-4 atm), the first control board 151 sends control information to stop the operation of the first inflator 154, the pressure inside the first pressurizing chamber 101 can be maintained at a certain pressure (e.g., 1.5-4 atm) by the above control process, the water inside the first pressurizing chamber 101 flows through the first microporous filter board 140 by the pressure and is filtered, the first microporous filter board 140 can filter and sterilize the water, the water flows into the first water storage cavity 102 after being filtered; if it is detected that the water level of the first storage chamber 102 is lower than the second water level detector 159 by the second water level detector 159, the first control board 151 sends out control information to stop the operation of the first inflator 154. The first control board 151 may also transmit control information to the first motor 152 to control the rotation speed of the first motor 152, and if the water level in the first water storage chamber 102 is maintained to be lower than the second water level detector 159, the first motor 152 may be controlled to be at a low rotation speed to maintain the spatial configuration of the activated water in the first water storage chamber 102, and if the water level in the first water storage chamber 102 is not maintained to be lower than the second water level detector 159 and the water in the first pressurizing chamber 101 is additionally flowed into the first water storage chamber 102, the first motor 152 may be controlled to be at a high rotation speed to promote the spatial configuration of water molecular clusters to be more efficiently rearranged.

More specifically, as shown in fig. 1 to 11, the first electromagnet 153 is a bar coil electromagnet formed by a wire wound around the first bar-shaped bracket 1531, a loop coil electromagnet formed by a wire wound around the first loop-shaped bracket 1532, or a U-coil electromagnet formed by a wire wound around the U-shaped bracket 1533; a first annular conductive sheet 1201 is fixedly arranged on the inner wall of the first hollow bracket 120, and the first electromagnet 153 is electrically connected with the first control board 151 through the first annular conductive sheet 1201. The first annular conductive sheet 1201 includes a first positive conductive sheet 12011 and a first negative conductive sheet 12012, both the first positive conductive sheet 12011 and the first negative conductive sheet 12012 are annular structures, both ends of a wire in the coil electromagnet can be electrically connected to the first positive conductive sheet 12011 and the second negative conductive sheet 12012 respectively, a first elastic conductive sheet 1536 can be disposed on the first electromagnet 153, the ends of the wire are electrically connected to the first elastic conductive sheet 1536, the first elastic conductive sheet 1536 is electrically connected to the first positive conductive sheet 12011 or the first negative conductive sheet 12012, the first elastic conductive sheet 1536 is tightly attached to the first positive conductive sheet 12011 or the first negative conductive sheet 12012 by its elastic force, and even if the first electromagnet 153 is in a rotating state, the wire in the coil electromagnet will not be electrically connected to the first annular conductive sheet 1201. The first electromagnet 153 may be a bar-shaped coil electromagnet, a ring-shaped coil electromagnet, or a U-shaped coil electromagnet, and the first control board 151 further controls the current flowing through the wire of the first electromagnet 153 to control the magnetic force of the first electromagnet 153, so as to realize more flexible and intelligent control of the rearrangement of water molecular groups, where the bar-shaped coil electromagnet has a specific structure as shown in fig. 7, the ring-shaped coil electromagnet has a specific structure as shown in fig. 6, and the U-shaped coil electromagnet has a specific structure as shown in fig. 8. The first electromagnet 153 may be a permanent magnet, but the magnetic force of the permanent magnet is fixed and cannot be changed, and the use of a coil electromagnet can change the magnetic force of the coil electromagnet by changing the magnitude of the current in the coil, thereby achieving a better use effect.

More specifically, the first electromagnet 153 is fixed to a first rotating bracket 1534, the first connecting shaft 155 is connected to the first rotating bracket 1534, and a first annular support 1535 for supporting the first rotating bracket 1534 to rotate is disposed in the first hollow bracket 120. The first rotating bracket 1534 is located on the first annular support 1535 for rotating, and the first rotating bracket 1534 and the first annular support 1535 are arranged to make the first electromagnet 153 more stable during rotation. In particular, the first annular seat 1535 may be configured as a seat including an annular flange, as shown in fig. 6; the first annular support 1535 may also be configured as a support that includes an annular bearing, as shown in fig. 9, and the first rotating support 1534 may include a groove that is configured to mate with the first annular support 1535.

More specifically, the first microporous filter plate 140 is composed of a first sterilization film layer 141 and a first microporous particle layer 142. Wherein the pore diameter of the first sterilization film layer 141 is 0.10-0.22 μm, and the first microporous particle layer 142 is a medical stone particle layer. The aperture of the first sterilization film layer 141 can be set to 0.10-0.22 μm, so that water can remove bacteria through the first sterilization film layer 141, and the first microporous particle layer 142 can be used for removing residual chlorine in water and adjusting the pH value of water, thereby improving water quality. Specifically, the first microporous particle layer 142 may be a modified medical stone particle layer, the modified medical stone particle layer is prepared by modifying a medical stone particle raw material, and the modified medical stone particle is prepared by the following steps: selecting a medical stone particle raw material with the particle size of 2-6mm, drying at 220 ℃ for 35-40min through 160-.

More specifically, as shown in fig. 10, a first wireless signal transceiver 1511 is further disposed on the first control board 151, the first wireless signal transceiver 1511 may be a communication module having a wireless signal transceiving function, such as a bluetooth module or a WiFi module, a user may use an intelligent terminal to perform wireless communication with the first wireless signal transceiver 1511, the first control board 151 may send working condition information of the terahertz water rearrangement intelligent monitoring system to the intelligent terminal, and the user may send wireless control information to the first control board 151 through the intelligent terminal, so as to perform intelligent control on the terahertz water preparation apparatus through the wireless control information. Wherein, the operating frequency of the first wireless signal transceiver 1511 is outside the operating frequency range of the first terahertz antenna 156.

More specifically, the first water inlet pipe 131 is further provided with active adsorption particles 1311, and water flowing from the outside can be adsorbed by the active adsorption particles 1311 to remove impurities, so as to further improve the water quality, and the active adsorption particles 1311 may be activated carbon particles.

More specifically, an activation degree detector 1202 communicated with the first water storage cavity 102 is further disposed on the bottom surface of the first hollow support 120, and the activation degree detector 1202 is electrically connected to the first control board 151. The activation degree detector 1202 may be configured to detect the activation degree of the activated water in the first water storage cavity 102 to obtain activation degree detection information, and the first control board 151 may obtain the activation degree detection information and intelligently adjust the rotation speed and the magnetic force of the first electromagnet 153 according to the activation degree detection information.

In one embodiment, as shown in fig. 1 to 11, the second terahertz water preparing assembly 250 includes a second control board 251, a second motor 252, a second electromagnet 253 and a second inflator 254, which are disposed in the second hollow bracket 220, the second motor 254 is connected to the second electromagnet 253 through a second connecting shaft 255 and drives the second electromagnet 253 to rotate, and the second inflator 254 inputs gas to pressurize the upper chamber 201; a second terahertz antenna 256 is fixedly arranged on the outer wall of the second hollow bracket 220; a second air pressure sensor 257 communicated with the upper chamber 201 is further arranged on the side wall of the second hollow bracket 220;

the second control board 251 is electrically connected to the second motor 252, the second electromagnet 253, the second inflator 254, the second air pressure sensor 257, the second terahertz antenna 256, and the second terahertz detector 260, respectively.

In this embodiment, the second thz water preparation assembly 250 is substantially the same as the first thz water preparation assembly 150, because the upper chamber 201 is filled with dry pottery clay without water, and the first microporous filter plate 140 is replaced with a detachable metal partition plate 240 without performing a filtering function, and water inlet pipes and control switches provided on the two water level detectors and the second cover plate 230 are also removed. That is, the second terahertz water preparation assembly 250 removes the water inlet function and the liquid level measuring function, and the first terahertz water preparation assembly 150 can be referred to for other functions and working principles.

In an embodiment, the lower end surface of the first cover plate 130 is uniformly divided into four parts, and then the four parts are respectively marked as a first cover plate area, a second cover plate area, a third cover plate area and a fourth cover plate area clockwise; the first terahertz detector is arranged at the center point of any one of the first cover plate region, the second cover plate region, the third cover plate region or the fourth cover plate region.

In this embodiment, in order to facilitate receiving the intensity of the terahertz wave reflected back from the first housing 110, at this time, the first terahertz detector 160 may be disposed at a center point of any one of the first cover plate region, the second cover plate region, the third cover plate region, or the fourth cover plate region, and the terahertz electromagnetic wave can be received more sufficiently by being disposed at a deviation center, so as to avoid a problem that the terahertz electromagnetic wave cannot be received sufficiently due to being disposed at a corner.

In an embodiment, the lower end surface of the second cover plate 230 is uniformly divided into four parts, and then the four parts are respectively marked as a fifth cover plate area, a sixth cover plate area, a seventh cover plate area and an eighth cover plate area clockwise; the second terahertz detector is arranged at the center point of any one of the fifth cover plate region, the sixth cover plate region, the seventh cover plate region or the eighth cover plate region.

In this embodiment, in order to facilitate receiving the intensity of the terahertz wave reflected back from the second housing 210, at this time, the second terahertz detector 260 may be disposed at a center point of any one of the fifth cover plate region, the sixth cover plate region, the seventh cover plate region or the eighth cover plate region, and the terahertz electromagnetic wave can be received more sufficiently by being disposed at a position deviated to the center, so as to avoid a problem that the terahertz electromagnetic wave cannot be received sufficiently due to being disposed at a corner.

In one embodiment, the frequency of the electromagnetic wave emitted by the first terahertz antenna 156 is the same as the frequency of the electromagnetic wave emitted by the second terahertz antenna 256, and the frequency of the electromagnetic wave emitted by the first terahertz antenna is 0.5-20 THz.

In the embodiment, the frequencies of the electromagnetic waves emitted by the first terahertz antenna 156 and the second terahertz antenna 256 are the same and are both 0.5-20THz, and the wavelength of the electromagnetic wave corresponding to the frequency range of the electromagnetic wave is 15-600 μm. In order to enhance the resonance effect of the water molecule groups, the frequency of the electromagnetic waves emitted by the first terahertz antenna 156 and the second terahertz antenna 256 can be further set to be 2.5-12Thz, and the wavelength of the electromagnetic waves corresponding to the frequency range of the electromagnetic waves is 25-120 μm. The terahertz electromagnetic wave can cause the water molecule groups in the first pressurizing cavity 101 to generate resonance, and the resonance effect can activate the water molecule groups, that is, the original configuration of the water molecule groups is destroyed through resonance, so that the water molecule groups containing more water molecules are converted into the water molecule groups containing less water molecules. However, the thz electromagnetic wave passes through the dry clay in the upper chamber 201 and is reflected by the upper end surface of the detachable metal partition plate 240, so that the thz electromagnetic wave is not absorbed in the upper chamber 201. Based on the characteristics of the terahertz electromagnetic wave, the set of control tests can be set to verify that water can absorb the terahertz electromagnetic wave (water can generate water molecular cluster rearrangement due to resonance effect after absorbing the terahertz electromagnetic wave).

In an embodiment, a first stainless steel layer structure is further disposed on the inner wall of the first casing 110, and a second stainless steel layer structure is further disposed on the inner wall of the second casing 210.

In this embodiment, since the metal material (e.g., iron or the like) does not absorb the terahertz electromagnetic wave and can reflect the terahertz electromagnetic wave, in order to prevent the terahertz electromagnetic wave from being projected out of the housing, a first stainless steel layer structure may be further disposed on the inner wall of the first housing 110, and a second stainless steel layer structure may be further disposed on the inner wall of the second housing 210.

In an embodiment, a first image sensor is further disposed on a lower end surface of the first cover plate 130, and a second image sensor is further disposed on a lower end surface of the second cover plate 230.

In the present embodiment, the first image sensor is provided in the first preparation apparatus 100, and a terahertz transmission image of water in the first housing 110 can be acquired. The second image sensor is disposed in the second manufacturing apparatus 200, and may acquire a terahertz transmission image of the dried clay in the second housing 210. Like imaging techniques of other wave bands, the terahertz imaging technique also utilizes terahertz rays to irradiate a measured object, obtains information of a sample through transmission or reflection of an article, and then images. The terahertz transmission image of the detected object is collected and can be used as a reference picture for characteristic analysis of the terahertz electromagnetic wave.

The embodiment of the invention provides an intelligent terahertz water rearrangement monitoring system, and also provides an intelligent monitoring method of the intelligent terahertz water rearrangement monitoring system, as shown in fig. 12, the method comprises the following steps:

s101, controlling a first terahertz water preparation assembly and a second terahertz water preparation assembly to be started and to be closed after a preset starting time threshold is started, wherein the working powers of terahertz waves generated by the first terahertz water preparation assembly and the second terahertz water preparation assembly are the same; wherein the electromagnetic wave intensity of the terahertz waves generated by the first terahertz water preparation component is a first initial electromagnetic wave intensity value, the electromagnetic wave intensity of the terahertz waves generated by the second terahertz water preparation component is a second initial electromagnetic wave intensity value, and the second initial electromagnetic wave intensity value is equal to the first initial electromagnetic wave intensity value;

s102, acquiring a first current electromagnetic wave intensity value in the first pressurizing cavity through a first terahertz detector, and acquiring a second current electromagnetic wave intensity value in the upper cavity through a second terahertz detector;

s103, sending the first initial electromagnetic wave intensity value, the second initial electromagnetic wave intensity value, the first current electromagnetic wave intensity value and the second current electromagnetic wave intensity value to a server;

s104, obtaining a first difference intensity value in the server by the first difference intensity value = first current electromagnetic wave intensity value — first current electromagnetic wave intensity value, and obtaining a second difference intensity value in the server by the second difference intensity value = second current electromagnetic wave intensity value — second current electromagnetic wave intensity value;

s105, acquiring a difference value between the first difference intensity value and the second difference intensity value as a comparison difference value;

and S106, if the contrast difference value is larger than 0, the server sends the water molecule rearrangement prompt message to a user side in communication connection with the server.

In this embodiment, by the above-described comparison, when the comparison difference value is greater than 0, it is possible to determine that the terahertz wave is mostly absorbed by water and water molecule rearrangement is transmitted. This is because the first difference intensity value is not close to 0 if the terahertz wave is absorbed by the bulk of water, and the second difference intensity value is equal to 0 or close to 0 if the terahertz wave is not absorbed by the dry puddle, so that when the difference between the first difference intensity value and the second difference intensity value (i.e., the control difference value) is greater than 0, it can be determined that the terahertz wave is absorbed by the bulk of water and water molecule rearrangement is transmitted.

In one embodiment, the threshold value of the turn-on time is 1-10 min.

In this embodiment, the single working time of both the first terahertz antenna and the second terahertz antenna can be set to 1-10 minutes, and at this time, water molecule groups in the first pressurizing cavity 101 can be resonated by the terahertz electromagnetic wave, and the water molecule groups can be activated by the resonance effect.

The embodiment of the invention provides a terahertz water rearrangement intelligent monitoring system and an intelligent monitoring method, wherein the terahertz water rearrangement intelligent monitoring system comprises 2 preparation devices which are sequentially marked as a first preparation device and a second preparation device; the system also comprises a server; the method comprises the steps that terahertz water is prepared from water in a first pressurizing cavity and a first water storage cavity through a first terahertz water preparation assembly in a first preparation device, so that terahertz water is obtained, the electromagnetic wave intensity of terahertz waves generated by the first terahertz water preparation assembly is a first initial electromagnetic wave intensity value, and a first current electromagnetic wave intensity value in the first pressurizing cavity is obtained through a first terahertz detector; taking second preparation equipment as comparison group equipment in the preparation process, transmitting terahertz electromagnetic waves into the upper cavity through a second terahertz water preparation assembly in a second preparation device, wherein the electromagnetic wave intensity of the terahertz waves generated by the second terahertz water preparation assembly is a second initial electromagnetic wave intensity value, and acquiring a second current electromagnetic wave intensity value in the upper cavity through a second terahertz detector; and obtaining a first difference intensity value by the first difference intensity value = first current electromagnetic wave intensity value-first current electromagnetic wave intensity value, obtaining a second difference intensity value by the second difference intensity value = second current electromagnetic wave intensity value-second current electromagnetic wave intensity value, and sending the water molecule rearrangement prompt message to a user side in communication connection with the server if the difference value between the first difference intensity value and the second difference intensity value is larger than 0. Due to the fact that a control group experiment is arranged, the fact that water can absorb terahertz electromagnetic waves and molecular rearrangement occurs can be effectively proved.

While the invention has been described with reference to specific embodiments, the invention is not limited thereto, and various equivalent modifications and substitutions can be easily made by those skilled in the art within the technical scope of the invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims (8)

1. A terahertz water rearrangement intelligent monitoring system is characterized by comprising 2 preparation devices which are sequentially marked as a first preparation device and a second preparation device; the first preparation device and the second preparation device are in communication connection with the server;

the first preparation device comprises a first shell, a first hollow bracket arranged in the first shell and a first cover plate covering the first shell; the first cover plate is provided with a first water inlet pipe and a first control switch for controlling the opening and closing of the first water inlet pipe; a first microporous filter plate is arranged in the first shell and divides a first closed space formed by tightly covering the first cover plate on the first shell into a first pressurizing cavity and a first water storage cavity; a first terahertz water preparation assembly is arranged in the first hollow support and is used for preparing terahertz water in the first pressurizing cavity and the first water storage cavity to obtain terahertz water; the first preparation device further comprises a first terahertz detector arranged on the lower end face of the first cover plate and used for detecting the electromagnetic wave intensity in the current environment;

the second preparation device comprises a second shell, a second hollow bracket arranged in the second shell and a second cover plate covering the second shell; a detachable metal separation plate is arranged in the second shell, a second closed space formed by tightly covering the second cover plate on the second shell is divided into an upper chamber and a lower chamber by the detachable metal separation plate, dry pottery clay is contained in the upper chamber, and the laying height of the dry pottery clay contained in the upper chamber is the same as the height of water contained in the first pressurizing chamber; a second terahertz water preparation assembly is arranged in the second hollow support; the second preparation device also comprises a second terahertz detector arranged on the lower end face of the second cover plate and used for detecting the electromagnetic wave intensity under the current environment;

the first terahertz water preparation assembly comprises a first control plate, a first motor, a first electromagnet and a first inflator pump, wherein the first control plate, the first motor, the first electromagnet and the first inflator pump are arranged in the first hollow support, the first motor is connected with the first electromagnet through a first connecting shaft and drives the first electromagnet to rotate, and the first inflator pump inputs gas to pressurize the first pressurizing cavity; a first terahertz antenna is fixedly arranged on the outer wall of the first hollow support; a first air pressure sensor communicated with the first pressurizing cavity is further arranged on the side wall of the first hollow support; a first water level detector and a second water level detector are respectively arranged on the side wall of the first hollow bracket, the first water level detector is used for detecting the water level of the first pressurization cavity, and the second water level detector is used for detecting the water level of the first water storage cavity;

the first control panel is electrically connected with the first motor, the first electromagnet, the first inflator pump, the first air pressure sensor, the first water level detector, the second water level detector, the first terahertz antenna, the first terahertz detector and the first control switch respectively;

the second terahertz water preparation assembly comprises a second control plate, a second motor, a second electromagnet and a second inflator pump, the second control plate, the second motor, the second electromagnet and the second inflator pump are arranged in the second hollow support, the second motor is connected with the second electromagnet through a second connecting shaft and drives the second electromagnet to rotate, and the second inflator pump inputs gas to pressurize the upper chamber; a second terahertz antenna is fixedly arranged on the outer wall of the second hollow support; a second air pressure sensor communicated with the upper cavity is further arranged on the side wall of the second hollow support;

the second control panel is electrically connected with the second motor, the second electromagnet, the second inflator pump, the second air pressure sensor, the second terahertz antenna and the second terahertz detector respectively;

wherein the first hollow bracket may pass through the first cover through-hole and protrude from a lower side of the first cover through-hole;

the first control board also controls the current flowing through the wire in the first electromagnet.

2. The terahertz water rearrangement intelligent monitoring system of claim 1, wherein the lower end surface of the first cover plate is uniformly quartered and then respectively marked as a first cover plate region, a second cover plate region, a third cover plate region and a fourth cover plate region clockwise; the first terahertz detector is arranged at the center point of any one of the first cover plate region, the second cover plate region, the third cover plate region or the fourth cover plate region.

3. The terahertz water rearrangement intelligent monitoring system of claim 1, wherein the lower end surface of the second cover plate is uniformly quartered and then respectively marked as a fifth cover plate region, a sixth cover plate region, a seventh cover plate region and an eighth cover plate region clockwise; the second terahertz detector is arranged at the center point of any one of the fifth cover plate region, the sixth cover plate region, the seventh cover plate region or the eighth cover plate region.

4. The terahertz water rearrangement intelligent monitoring system of claim 1, wherein the frequency of the electromagnetic wave emitted by the first terahertz antenna is the same as the frequency of the electromagnetic wave emitted by the second terahertz antenna, and the frequency of the electromagnetic wave emitted by the first terahertz antenna is 0.5-20 THz.

5. The terahertz water rearrangement intelligent monitoring system of claim 1, wherein a first stainless steel layer structure is further disposed on the inner wall of the first housing, and a second stainless steel layer structure is further disposed on the inner wall of the second housing.

6. The terahertz water rearrangement intelligent monitoring system as claimed in claim 1, wherein a first image sensor is further disposed on a lower end surface of the first cover plate, and a second image sensor is further disposed on a lower end surface of the second cover plate.

7. The intelligent monitoring method of the terahertz water rearrangement intelligent monitoring system as claimed in any one of claims 1 to 6, comprising:

controlling the first terahertz water preparation assembly and the second terahertz water preparation assembly to be started and to be closed after a preset starting time threshold is started, wherein the working powers of terahertz waves generated by the first terahertz water preparation assembly and the second terahertz water preparation assembly are the same; wherein the electromagnetic wave intensity of the terahertz waves generated by the first terahertz water preparation component is a first initial electromagnetic wave intensity value, the electromagnetic wave intensity of the terahertz waves generated by the second terahertz water preparation component is a second initial electromagnetic wave intensity value, and the second initial electromagnetic wave intensity value is equal to the first initial electromagnetic wave intensity value;

acquiring a first current electromagnetic wave intensity value in the first pressurizing cavity through a first terahertz detector, and acquiring a second current electromagnetic wave intensity value in the upper cavity through a second terahertz detector;

sending the first initial electromagnetic wave intensity value, the second initial electromagnetic wave intensity value, the first current electromagnetic wave intensity value and the second current electromagnetic wave intensity value to a server;

obtaining a first difference intensity value in the server by the first difference intensity value = first current electromagnetic wave intensity value-first current electromagnetic wave intensity value, and obtaining a second difference intensity value in the server by the second difference intensity value = second current electromagnetic wave intensity value-second current electromagnetic wave intensity value;

obtaining a difference value between the first difference intensity value and the second difference intensity value as a comparison difference value;

and if the contrast difference value is larger than 0, the server sends the water molecule rearrangement prompt information to a user side in communication connection with the server.

8. The intelligent monitoring method of the terahertz water rearrangement intelligent monitoring system according to claim 7, wherein the turn-on time threshold is 1-10 min.

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