DE102006008288A1 - Assembly to apply magnetic treatment to a liquid e.g. water has a helical water pipe around a rotating magnetic core - Google Patents

Abstract

An assembly applies magnetic treatment to a flowing liquid e.g. water supply flowing through a pipe. The assembly has an inlet to a non-electrical conductor helical pipe section (2C) around a magnetic core at the center of the helix. The magnetic core consists of a series of permanent magnets extending the full length of the helix and held as a group within a retaining cage. The magnetic assembly consists of an inner core (13A) surrounded by secondary permanent magnets (12). The magnetic assembly rests on bearings and rotates in the opposite direction to that taken by the water through the helix. The assembly has a water flow rate sensor coupled via a magnetic core rotational speed control unit. The assembly has a second sensor monitoring the degree of magnetic effect on the water and linked to the speed control unit.

Description

The The present invention relates to a magnetic device Treatment of a liquid such as. Water or oil and in particular a magnetic treatment device comprising a magnetic treatment of a fluid to be treated, e.g. water powerful can make.

So far Devices have been proposed to prevent sticking of waterstone in water pipes, the corrosion of water pipes and the associated formation of red-colored water or the formation of algae in rivers and stagnant waters Lead water through a magnetic field generated by permanent magnets and modify this water by the action of this magnetic field.

It already such a device is known in which a line for the Water passage inserted into an outer housing is and several opposite arranged permanent magnets are formed (JP-04-122543-A).

It Also, removable water treatment devices are known in the art which yokes inside a housing pair, which surrounds a water supply line, are attached, permanent magnets attached to the inside of the yokes, and the permanent magnets are arranged so that opposite magnetic poles each other over the Face water supply line (JP-11-169861-A).

Besides, they are Devices are known in which several permanent magnets on the outer circumference a line strung together and by a steel body strap are fixed (JP-3074925-U).

at these known devices (JP-04-122543-A, JP-11-169861-A, JP-3074925-U), the permanent magnets are mounted on the outer circumference of a pipe, which has a round cross-section, and these permanent magnets are each other over across the tube, why the time, for the one flowing in the pipe Water is exposed to the magnetic field of the permanent magnets, is extremely short. Therefore, there is a problem that the Magnetic field can not effectively affect the fluid in the pipe and no good modification of the water by the action of the magnetic field he follows.

If over the whole length The permanent magnets of the pipe could be attached, the time in which the water could the magnetic field is prolonged, but persists Here is the problem that this requires many permanent magnets and so that the costs are high.

in the Generally, water pipes are u.a. from a magnetic body like Metal and mainly Iron is formed, but since the tube in this case as a magnetic shield acts, the magnetic field of the permanent magnets can not have a good effect exercise the water in the pipe.

From that Based on the invention, the object is based, a device to provide a good magnetic effect on water or a other fluid that flows in a pipe exerts.

to solution This object is inventively a device provided for magnetic treatment, which is a conduit in whose Inside the fluid to be treated flows and a magnetic field generating means which generates a magnetic field having an effect on the exerts fluid to be treated in the conduit, and characterized in that the conduit has a tubular serpentine section, in which they are helical is wound, and that the magnetic field generating means on the inside of the snake section from end to end is trained.

According to the invention the magnetic field generating means in this magnetic device Treatment of several permanent magnets and a magnetic holding element, which fixes the individual permanent magnets, wherein the magnetic holding element a core part arranged in the middle of the coil section and the individual permanent magnets on the circumference of the core part are formed.

Further it is provided that the device has a magnetic field rotating means, that the magnetic field generating means rotates that the direction of rotation of the magnetic field generating means by the magnetic field rotating means Direction of rotation of the fluid to be treated in the snake section opposite is, and that the snake section is made of a non-conductor.

In addition is provided that a flow rate sensor for determining the Flow rate of the fluid to be treated flowing in the conduit, and a control means for controlling the rotation operation the magnetic field generating means based on the output signal of Flow rate sensor are provided.

Further, it is provided that a magnetization degree sensor for detecting the degree of magnetization of the flowing through the snake section flow and a control means for controlling the rotation operation of the magnetic field generating means are provided on the basis of the output signal of the magnetization degree sensor.

There the line of the device for magnetic treatment, in whose Inside the fluid to be treated flows, according to the present invention a helical one wrapped, tubular snake section forms, on the inside of which the magnetic field generating means is formed is the time is long, in which the fluid to be treated the magnetic field of Magnetic field generating means is exposed, whereby a good modification of the fluid to be treated possible becomes.

There the magnetic field generating means of a plurality of permanent magnets and a Magnetic holding element is made, which fixes the individual permanent magnets, the magnetic holding member one in the middle of the snake portion arranged core part and the permanent magnets on the circumference of the Core part are formed, a core part can be formed with the small permanent magnets close to the inner peripheral surface of the Snake section can be brought, creating a strong magnetic field can be exerted on the fluid inside the pipe.

There a structure is used in which the magnetic field generating means rotated by a magnetic field rotating means, on the inside, on the inner circumference, the snake section a rotating magnetic field, a rotary magnetic field, generated effectively on the helical through the snake section flowing, act in a helical flow, to be treated fluid act can. There about it In addition, the direction of rotation of the magnetic field by the magnetic field rotating means to the direction of rotation of the fluid to be treated in the snake section Opposite, becomes even stronger, better and more effective Effect of the magnetic field on the fluid to be treated possible.

By the formation of the snake section from a non-conductor acts the magnetic field of the magnetic field generating means without shut-off the fluid to be treated, and there by the rotation of the magnetic field generating means in the snake section no eddy current is formed, a warming of Snake section prevented by the rotating magnetic field.

There a flow rate sensor for determining the flow rate of the flowing in the line Fluids and a control means for controlling the rotation activity the magnetic field generating means based on the output signal of the flow rate sensor are provided, the rotation of the magnetic field generating means stopped when the flow of the fluid to be treated stopped is, thereby achieving a reduction in operating costs can. By an increase the number of revolutions of the magnetic field generating means in relation to Flow rate of the fluid to be treated can be a uniform magnetic treatment the fluid to be treated flowing through the serpentine section be achieved.

There a magnetization degree sensor for detecting the degree of magnetization the fluid to be treated flowing through the serpentine section and a control means for performing the control of the rotation operation the magnetic field generating means based on the output signal of the flow rate sensor can be provided, a feedback control or regulation are made, in which the number of revolutions of the magnetic field generating means in relation to to the size of the magnetization degree of the fluid flowing through the serpentine section to be treated will, so that a uniform magnetic treatment of the fluid to be treated can be performed.

below The present invention is based on the figures, for example in detail explained. Show it:

1 a side view of a device for magnetic treatment according to the present invention;

2 a schematic front view showing the internal structure of this device;

3 a side view showing the inside of the snake section;

4 a section substantially along the line XX in 3 ;

5 a view accordingly 3 the magnetic field generating means for explaining the generation state of the magnetic field generated by the magnetic field generating means;

6 a block diagram showing a structural example of the control means;

7 a flowchart showing an example of the control by the control means;

8th a view accordingly 3 showing another example of a magnetic field generating means; and

9 a representation accordingly 5 for the magnetic field generating means of 8th ;

In 1 and 2 denotes the reference numeral 1 a portable frame or a housing, on the underside of castors are formed. Inside this frame or housing 1 is eg a pipe as a pipe 2 arranged in the interior of which a fluid to be treated flows.

The administration 2 is a synthetic resin pipe made of non-conductive vinyl chloride, for example. Both ends are as an opening 2A or as an outflow opening 2 B at the frame 1 fixed. At the influence opening 2A at one end of the line, a supply line (not shown) for supplying the fluid to be treated is connected, and to the outflow port 2 B at the other end of the line, a discharge line, not shown, is connected, through which the fluid is passed to a desired location after completion of the treatment.

The administration 2 forms between the influence opening 2A and the outflow opening 2 B a tubular snake section 2C in which it is wound helically. The administration 2 can only in that area, the snake section 2C forms, be executed as non-conductor, and the line 2 can also be wholly helical as a snake section 2C be wrapped. Inside the snake section 2C a later-described magnetic field generating means is formed so that a magnetic field on the fluid to be treated in the interior of the snake portion 2C forming line acts. In the present example, the magnetic field generating means is on the inside of the coil section 2C in particular rotatably arranged from one axial end of this section to its other end. Its rotation becomes on the inside of the snake section 2C a rotary magnetic field is formed.

In 2 denotes the reference numeral 3 a rotation shaft that constitutes the rotation axis of the magnetic field generating means. This rotary shaft 3 is at both ends by bearing units 4 held on the frame 1 are attached. According to the present example, one end of the rotary shaft 4 with the drive shaft of a motor attached to the frame 5 coupled with variable speed, whereby a magnetic field rotating means for rotating the magnetic field generating means is formed.

The reference number 6 indicates a flow rate sensor that is near the influent opening 2A on the line 2 is attached and the flow rate in the pipe 2 determine fluid to be treated fluids, and the reference numeral 7 denotes a magnetization degree sensor located near the outflow port 2 B on the line 2 is attached and the degree of magnetization of the by the snake section 2C observed run to be treated fluid. For the flow rate sensor 6 For example, a magnetic flow meter or a Kármán vortex flowmeter is used, and for the magnetization degree sensor 7 For example, a Hall element or a Hall integrated circuit generating a voltage corresponding to the magnitude of the magnetism or an oxidation-reduction potentiometer, an ORP sensor is used.

If As the degree of magnetization of the treatment fluid changes, it changes also the oxidation-reduction potential Accordingly, why the degree of magnetization quantitatively from the size of the oxidation-reduction potential of the treatment fluid expressed can be.

In 1 denotes the reference numeral 8th the main power source switch of the device, and the reference numeral 9 a display part made of a liquid crystal panel or the like; consists. On this display part 9 which is determined by the flow rate sensor 6 detected flow rate of the treatment fluid, the degree of magnetization of the treatment fluid detected by the magnetization degree sensor, and the operating state of the device in terms of the number of revolutions of the motor 5 displayed with variable number of revolutions.

In 2 denotes the reference numeral 10 a control means or a controller that performs the control of the rotational behavior of the magnetic field generating means based on the outputs of the flow rate sensor and the magnetization degree sensor. In particular, in the present example, an on / off control is performed in which a stop signal from the control means 11 to the engine 5 is sent at a variable speed to stop the magnetic field generating means when the output signal of the flow rate sensor 6 Is "0" or at most a set value, or a drive signal from the control means 11 to the engine 5 is sent at a variable speed to rotate the magnetic field generating means within a certain speed range when the output signal of the flow rate sensor 6 greater than "0" or the set value.

The control means 10 Also performs a control at which the speed of the motor 5 variable speed according to the magnitude of the output of the magnetization degree sensor 7 is increased or decreased, thereby changing the number of revolutions of the magnetic field generating means. It is also possible on the magnetization degree sensor 7 to give up and the engine 5 With variable speed according to the size of the output signal of the flow rate sensor 6 , So according to the flow rate of the fluid to be treated to accelerate or retard.

Now, the structure of the magnetic field generating means will be explained. In 3 and 4 denotes the reference numeral 11 This magnetic field generating means, which consists of several permanent magnets 12A . 12B and a magnet holding member 13 that the individual permanent magnets 12A . 12B fixed, constructed. The magnet holding element 13 consists of one in the middle of the snake section 2C arranged core part 13A and between the individual permanent magnets 12A . 12B arranged magnetic plates 13B , where the permanent magnets 12A . 12B on the circumference of the core part 13A are arranged.

The core part 13A is a columnar, octagonal columnar yoke of one length of the serpentine section 2C approximately the same length. At its center is the rotary shaft 14 fixed in a stretched position. According to the present example, as in 3 shown an even number of, for example, eight permanent magnets 12A having a rectangular cross section from the outer peripheral surface of the core part 13A attracted while permanent magnets 12B with triangular cross-section over the magnetic plates 13B between these permanent magnets 12A are used.

For the permanent magnets 12A . 12B For example, ferrite magnets or metal magnets may be used, but magnetic magnets are used, and ideally, neodymium magnets. For the rectangular permanent magnets 12A becomes a magnetic pole from the outer peripheral surface of the core part 13A attracted while the other magnetic pole of the inner peripheral surface of the snake portion 2C opposite. The magnetic poles of magnets adjacent in the circumferential direction are oppositely directed. That is, the rectangular permanent magnets 12A are arranged in such a state that the direction of the north and south poles of magnets, which have an interposed triangular permanent magnet 12B are opposite, so that the north poles and south poles appear alternately in the circumferential direction.

The permanent magnets 12A may also be rod-shaped magnets extending in the longitudinal direction of the core part 13A extend, but preferably as in 4 permanent magnets 12A used with a small length along the longitudinal direction of the core part 13A are arranged in rows, wherein the magnetic poles of adjacent magnets are also directed in the arrangement direction opposite.

The triangular permanent magnets 13B in which the two are between the magnetic plates 13B used surfaces represent the magnetic poles, serve as wedges to increase the fixing force of the permanent magnets 12A in relation to the core part 13A , The triangular permanent magnets 12B are not essential. When using rectangular permanent magnets 12A strong on the core part 13A can be pulled on the triangular permanent magnets 12B be waived.

By the magnetic field generating means as stated above 11 a magnetic field is generated which, as in 5 shown by projection-like magnetic lines of force extending from the inside of the coil section 2C spread radially outwards. This magnetic field can respond well to the fluid being treated in the conduit 2 , which forms the snake section, act. By rotations of the magnetic field generating means 11 a rotary magnetic field is generated, which oscillates on the fluid to be treated in the line 2 , which forms the snake section, acts, whereby the fluid to be treated is bathed even more powerfully and effectively in the magnetic lines of force than in the magnetic field.

In particular, the direction of rotation of the magnetic field rectifier 11 and the direction of rotation of the fluid to be treated, which is the spiral conduit 2 of the snake section 2C flows along, opposite. When the direction of rotation of the treatment fluid in 3 the direction of rotation of the magnetic field generating means runs in the right-hand direction, that is in the clockwise direction 11 viewed from the same direction looking to the left, ie counterclockwise. This increases the frequency with which the fluid to be treated crosses the magnetic field and makes the magnetic treatment of the fluid to be treated more effective.

Even if on the inside of the snake section 2C When a rotating magnetic field is generated, heating by an eddy current can be prevented since the serpentine portion 2C is a non-conductor. In 3 and 4 denotes the reference numeral 15 a cylindrical winding drum on which the line 2 that the snake section 2C should form, is wound. At both ends is a flange 15A educated. The snake section 2C is by connecting these flanges 15A on side plates 1A (please refer 2 ) of the frame fixed in a certain position. Also the winding drum 15 is formed of a non-conductor such as synthetic resin, which is intended to prevent eddy current heating. If a hard tube is used that is in the shape of the snake section 2C Can be fixed on the winding drum 15 be waived.

How out 3 becomes clear, are the snake section 2C and the winding drum 15 Cylindrical, but also a design in the form of a square pipe is possible. In short, it is enough if the snake section 2C such an inner diameter that the magnetic field generating means 11 can be picked up on the inside. To the length of the line 2 that the snake section 2C makes to resize is this lead 2 preferably as in 4 shown tightly wound without spacing.

Next, an example of the structure of the control means will be explained. As in 6 is shown, the control means 10 including a central processing unit 16 , a storage medium 17 , an input device 18 and an interface unit 19 on. To the interface unit 19 are the display part 9 , the flow rate sensor 6 , the magnetization degree sensor 7 and the motor driver 20 connected. The motor 5 variable speed, which represents the magnetic field means of rotation, is to the driver 20 connected.

The central processing unit 16 runs control programs and controls the entire device. The necessary programs and data are in storage 17 contain.

The storage means 17 has a read only memory (ROM) containing the control programs, etc., and a random access memory (RAM) containing data such as the flow rate and the degree of magnetization of the treatment fluid detected by the flow rate sensor and the magnetization degree sensor. Through the input device 18 For example, an adjustment of the target value for the magnetization degree of the machining liquid, that is, the target magnetization degree, may be input to the random access memory.

The central processing unit 16 leads from the flow rate data, ie the actual flow rate and the magnetization degree data, ie the actual degree of magnetization and the degree of target magnetization in the storage means 17 Calculations and judgments, and sends control signals via the interface unit based on the results 19 to the motor driver 20 , whereby the operation, ie stopping, starting and changing the speed of the engine 5 is made with variable speed.

7 shows a flow chart of the magnetic treatment of the fluid to be treated. How out 7 becomes clear, in the use of the present device, first the main power source switch is turned on and an input of the target degree of magnetization J0 is made in the control means. This input is made as necessary and may be omitted if no change in the target degree of magnetization J0 occurs.

The Receives control means the output signal of the flow rate sensor as the actual flow rate Q of the treatment fluid and the output of the magnetization degree sensor as actual Magnetization degree J1.

If in the line the fluid to be treated flows and thus a state of Q> 0, operating current flows from the control means to the variable speed motor, thereby the magnetic field generating means with a certain number of revolutions is turned. If the present device in an already existing Water pipe was recorded, that reaches as to be treated Fluid flowing in the pipe Tap water by turning the tap a state Q> 0, and if storage water a water reservoir flows through a pump in a line comes It passes through the operation of the pump to the condition Q> 0. There is a risk that even then a weak signal is output from the flow rate sensor and the engine with variable Speed is operated when no flow of the fluid to be treated is in the line, the above conditional formula "Q> 0" in practice, for example, as "Q> 1" are designed by or can Flow sensor output signals below a certain Level are locked.

Then takes the control means in the state of flowing fluid to be treated in the line a comparison of the Zielmagnetisierungsgrads J0 and of the actual Degree of magnetization J1 ago. The variable speed motor will be included J0> J1 accelerates and at J0 <J1 delayed whereby the magnetic field generating means with one of the size of the actual Magnetization degree J1 corresponding speed is rotated. The comparison of the target magnetization degree J0 and the actual Degree of magnetization J1 is made at certain intervals, and the acceleration or deceleration The speed of the variable speed motor will ever according to the size of the difference made gradually between J0 and J1. If the engine with variable Speed has reached its rated speed, this state is maintained, until it comes to J0 <J1.

Subsequently, based on 8th an example of a modification of the magnetic field generating means explained. Parts that do not differ from the above example have been given the same reference numbers. An explanation of these parts will be omitted. How out 8th becomes clear, is the core part 23A in the present example, a columnar member having a quadrangular cross section. Also with this core part 23A it is one in the middle of the snake section 2C arranged yoke, in the center of the rotary shaft 14 is fixed in a stretched way. On the outer peripheral surface of this core part 23A are four tab strips 23B formed, whereby the magnetic holding element 23 is formed. The tab strips 23B are wing-shaped magnetic plates which are integral with the core part 23A are executed and each radially from the core part 23A protrude.

At the periphery of the core part 23A is an even number of, for example, eight permanent magnets 12A arranged. The permanent magnets 12A are each as a group of two magnets on both sides of the projection strips 23B dressed. The permanent magnets 12 each group stand over the tab strip 23B with the same pole while the exposed magnetic poles are different from adjacent groups. That is, when the permanent magnets 12 . 12 of a group of opposing north poles attracted by the projection strip become the permanent magnets 12 . 12 the neighboring group with opposite south poles from the promontory strip 23B dressed. Also in the present example, it is convenient permanent magnets 12 short length, along the longitudinal direction of the core part 23A are arranged in rows, wherein the magnetic poles of adjacent magnets are oppositely directed in the arrangement direction.

Also with the magnetic field generating means 21 According to the present example, a magnetic field is generated which, as in FIG 9 shown by projection-like magnetic lines of force extending from the inside of the coil section 2C spread radially outwards. This magnetic field can respond well to the fluid being treated in the conduit 2 , which forms the snake section, act. By rotations of the magnetic field generating means 21 a rotary magnetic field is generated, which oscillates on the fluid to be treated in the line 2 , which forms the snake section, acts, whereby the fluid to be treated is bathed even more intense and intense in the magnetic lines of force.

In the foregoing, the present invention has been explained, but the subject device can not only magnetically treat water and other liquids, but also air and other gases. A structure in which the magnetic field generating means 11 . 21 is rotated, is best, but also a structure is possible, in which this means on the inside of the snake section 2C is received in a solid state. In addition, an electromagnet having a three-phase coil structure which generates a rotating magnetic field can also be used as the magnetic field generating means or a structure in which an electromagnet which does not electrically generate a rotating magnetic field is rotated. Also, when using permanent magnets, there is no limitation to a structure as in the above examples, but, for example, in the circumferential direction magnetized annular permanent magnets can be fixed tubular side by side on the outer circumference of a core part with the shape of a round column.

Claims (8)

Device for magnetic treatment with a line ( 2 ), in the interior of which a fluid to be treated flows, and a magnetic field generating means ( 11 . 21 ) which generates a magnetic field which exerts an effect on the treatment fluid in the conduit, the conduit ( 2 ) a tubular serpentine section ( 2C ) in which it is helically wound, and the magnetic field generating means ( 11 . 21 ) inside the snake section ( 2C ) is formed from its end to its other end. Device for magnetic treatment according to claim 1, characterized in that the magnetic field generating means ( 11 . 21 ) inside the snake section ( 2C ) extends from its end to its other end. Magnetic treatment device according to claim 1 or 2, characterized in that the magnetic field generating means ( 11 . 21 ) of several permanent magnets ( 12 ) and a magnetic holding element ( 13 ), the individual permanent magnets ( 12 ), and the magnetic holding element ( 13 ) one in the middle of the snake section ( 2C ) arranged core part ( 13A ) and the individual permanent magnets ( 12 ) at the periphery of the core part ( 13A ) are formed. Device for magnetic treatment according to claim 1, 2 or 3, characterized in that a magnetic field rotating means ( 5 . 14 ) is provided which the magnetic field generating means ( 11 . 21 ) turns. Magnetic treatment device according to claim 4, characterized in that the direction of rotation of the magnetic field generating means ( 11 . 21 ) through the Mag netfelddrehmittel ( 5 . 14 ) to the direction of rotation of the fluid to be treated in the snake section ( 2C ) is set opposite. Magnetic treatment device according to one of the preceding claims, characterized in that the serpentine section ( 2C ) consists of a non-conductor. Magnetic treatment device according to claim 4 or 5, characterized in that a flow rate sensor ( 6 ) for determining the flow rate of the fluid to be treated in the conduit and a control means ( 10 ) for performing the control of the rotation of the magnetic field generating means ( 11 . 21 ) based on the output signal of the flow rate sensor ( 6 ) are provided. Magnetic treatment device according to claim 4 or 5, characterized in that a magnetisation degree sensor ( 7 ) for determining the degree of magnetization of the fluid to be treated flowing through the coil section and a control means ( 10 ) for performing the control of the rotation of the magnetic field generating means ( 11 . 21 ) based on the output of the magnetization degree sensor ( 7 ) are provided.