WATER CONDITIONER WITH VARIABLE FREQUENCY ELECTROMAGNETIC FIELD

Abstract

The present invention relates to an apparatus for removal and prevention of 5 scale deposition comprising SMPS (switched mode power supply) (1) for generating DC signal, retrofittable pipe section (3) being fitted in residence water carrying pipe wherefrom the scale is removed or prevented to be deposited, a signal cable (2) being wound around the pipe section (3) to form overlapped coils of optimum turns being connected by center tap (2c), a 10 transistor (4) of low operating frequency electrically connected with signal cable (2) at center tap (2c) formed between overlapped coils. The conductor lead (2a) and conductor lead (2b) are respectively connected to the terminal Band C of the transistor (4). By said configuration, when the signal is applied to the signal cable (2), an alternative electromagnetic field with variable 15 frequency is induced around pipe that effectively removes and prevents the scale forming through the water passed from said conduit.

Claims

1. An apparatus for removal and prevention of scale deposition comprises: a generator (1) having a first (positive) terminal (1a) and second terminal (negative terminal) (1b) for generating a DC signal between said terminals (1a, 1b); a retrofittable elongated tubular member (3) configured to be interconnected with the water carrying conduit in an axial manner, having at a first end an inlet and at a second end longitudinally opposite the first end an outlet for the flowing fluid; at least one signal wire (2) being wrapped around said elongated member to form a first coil and a second coil; said wire having a conductor lead (2a, 2b) at its both end; at least one transistor (4) having three terminals (B, C, E) associated with the generator (1) for ensuring that the signal is non continuous and a frequency modulated with variable frequency; wherein said coils are overlapped and are electrically connected to each other to form a center tap (2c); wherein said center tap (2c) is electrically connected with the first terminal (1a) of the generator (1) so that the signal is applied to the coils to energize the coils and generate a corresponding variable electromagnetic field in the conduit; wherein one of said conductor lead (2a) of the wire (2) is electrically connected to the terminal B of the transistor (4); wherein one of said conductor lead (2b) of the wire (2) is electrically connected to the terminal C of the transistor (4); wherein negative terminal (1b) of the generator (1) is electrically connected to the terminal E of the transistor (4); wherein said signal energize the first coil and second coil to produce alternating magnetic field in the coils.

2. The apparatus for removal and prevention of scale deposition as claimed in claim 1, wherein the successive turns of each of the first and second coil are in opposite direction.

3. The apparatus for removal and prevention of the scale deposition as claimed in claim 1, wherein said transistor (4) having a characteristic of low operating frequency whereby it vary the frequency of said magnetic field induced in the first and second coil.

4. The method for removal and prevention of scale deposition comprises following steps: a) winding a number of turns of signal wire (2) to form a first coil and winding a number of turns on the first coil with same wire in opposite direction to form a second overlapped coil; b) forming a center tap (2c) at the connecting point of the said coils; c) electrically connecting said center tap (2c) with the first (positive) terminal (1a) of the generator (1); d) electrically connecting one of the conductor lead (2a) of the signal wire (2) to the terminal B of the transistor (4); e) electrically connecting one of the conductor lead (2b) of the signal wire to the terminal C of the transistor (4); f) electrically connecting the negative terminal (1b) of the generator (1) to the terminal E of the transistor (4); g) applying said signal through said electrical connection so as to pass through said first coil and second coil; h) producing alternating magnetic field in said coils by applying signal to said overlapped coils; i) varying the frequency of the magnetic field produced in said coils by said transistor (4) by interrupting said signal for effectively removing the scale.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0013] Objects and advantages of the invention will be apparent from the following detailed description taken in conjunction with the accompanying figures of the drawing wherein:

[0014] FIG. 1 shows the block diagram of first embodiment of an apparatus for removal and prevention of scale deposition according to present invention.

[0015] FIG. 2 shows the block diagram of second embodiment of an apparatus for removal and prevention of scale deposition according to present invention.

DETAILED DESCRIPTION OF THE INVENTION

[0016] Before explaining the present invention in detail, it is to be understood that the invention is not limited in its application to the details of the construction and arrangement of parts illustrated in the accompany drawings. The invention is capable of other embodiments, as depicted in different figures as described above and of being practiced or carried out in a variety of ways. It is to be understood that the phraseology and terminology employed herein is for the purpose of description and not of limitation.

[0017] Referring to FIG. 1, an apparatus for preventing scaling and/or removing scale in a housing (not shown) is shown. Although not shown in the drawings, the housing in this embodiment is a metallic or a non-metallic pipe configured to carry water. The apparatus of the present invention, however, may be applied to other containers including conduits or tanks used to carry water such as hard water that can cause scaling.

[0018] Referring to FIG. 1, there is provided a diagram of a first embodiment of apparatus for scale remover and preventer which comprise a SMPS (switched mode power supply) (1) having a positive terminal (1a) and a negative terminal (1b) and generates DC voltage signal between said terminals (1a, 1b) from the auxiliary power supply, a pipe section (3), particularly made from copper or plastic, a signal cable (2) having a first conductor lead (2a) and a second conductor lead (2b) and is shown coiled around the outer surface of the pipe section (3) and a NPN transistor (4), preferably TTC5200, having terminals (B, C, E). Conductor lead (2a, 2b) of said signal cable (2) are respectively connected to the terminals (B, C) of the transistor (4) and remaining terminal (E) is connected to a negative terminal (1b) of the SMPS (1) as shown in FIG. 1. The pipe section (3) is configured such that it is retrofittable or incorporable into the housing pipe. Once installed, opposing ends of the pipe section (3) adjoin to the respective openings of the housing pipe such that the plastic pipe section (3) and the housing pipe are in fluidly communication with one another.

[0019] It is to be noted that said pipe section (3) is preferably made from the copper or plastic material. Further, the purpose of using the TTC5200 NPN transistor is having its characteristics of low operating frequency which is suitable for varying the frequency of the magnetic field generated in the coil. However, it is within the scope of present invention to utilize the other transistor having the similar configuration of TTC5200. Further, it is within the scope of present invention to adapt battery for producing DC voltage signal for replacing the SMPS.

[0020] Referring continuous to FIG. 1, there is shown a configuration of winding said signal cable (2) on the pipe (3). Said signal cable (2) is wound such that when about half of the length of the signal cable (2) is coiled on the pipe (3) to form a first coil by winding optimum number of turns, a center tap (2c) is formed by extending and banding some portion of the signal cable (2). Another half portion of the signal cable is coiled on the pipe (3) in a reverse linear direction to form a second coil. Thus, two overlapped coils are formed on the pipe (3) that contains about similar number of turns.

[0021] Now, referring FIG. 1 again, said center tap (2c) is electrically connected to the positive terminal (1a) of the SMPS (1). In said embodiment, the first conductor lead (2a) of signal cable (2) is connected to the terminal B via resistor R1 for limiting the base current flow and the second conductor lead (2b) of signal cable (2) is connected to the terminal C of the transistor (4). Said terminal E of the transistor (4) is connected to the negative terminal (1b) of the SMPS (1). Here, said DC signal applied to the signal cable (2) produces the electromagnetic field (shown in dotted line) by completed the circuitry from the positive terminal (1a) to the negative terminal (1b). The aforesaid configuration enables the transistor (4) to come in the path of said DC signal during flowing from the positive terminal (1a) to the negative terminal (1b).

[0022] In operation, the standard AC power supply is given to the input of the SMPS (1) that produces the stable DC voltage signal between said positive terminal (1a) and negative terminal (1b). Now, when said signal is applied to the center tap (2c) of signal cable (2), said coils are energized to produce alternating magnetic field wherein lines of flux of magnetic field produced from one coil is directed along the fluid flow path established by said pipe (3) and the lines of flux of magnetic field produced from another (second) coil is directed to the opposite direction of fluid flow path. Thus, alternating magnetic field is produced in the coils. From centre tap (2c), said current is divided by flowing through the conductor leads (2a, 2b). Here, said current is applied to the terminal B from the first conductor lead (2a) by passing through the resistor R1 that controls the current of said signal. Similarly, said signal is applied to the terminal C by second conductor lead (2b) without using any current limiting component in its path. Due to characteristics of low operating frequency of transistor (4), said signal will alternatively pass from the terminal B to terminal E and terminal C to terminal E. Here in both case, magnetic field of different value is produced in the both coils which is shown below.

[0023] In first embodiment, the magnetic field is calculated in the overlapped coils on the pipe by passing the signal of 0.26 amp in both coils. Each said coil contains N=100 turns wound on the L=0.06 m length of pipe section (3). The magnetic field produced in both coils is calculated below.

[0024] In first coil, said signal is passed through the resistor of R1=6.6K whereby the current is reduced up to 0.8*10.sup.3 amp. Thus according to equation,

[00001]$\begin{array}{c}B.Math..Math.1=.Math.4.Math.*{10}^{-7}*100*0.8*{10}^{-3}/\mathrm{0.06`}\\ =.Math.1.67.Math..Math..Math..Math.T\end{array}$

[0025] magnetic field is produced.

[0026] In second coil, according to equation,

[00002]$\begin{array}{c}B.Math..Math.2=.Math.4.Math.*{10}^{-7}*100*0.26/\mathrm{0.06`}\\ =.Math.0.544.Math..Math.\mathrm{mT}.Math..Math.\mathrm{magnetic}.Math..Math.\mathrm{field}.Math..Math.\mathrm{is}.Math..Math.\mathrm{produced}.\end{array}$

[0027] By comparing magnetic field induced in the both coils, it is seen that alternating magnetic field at variable frequency is generated in the coils at different time interval by using said transistor. The frequency of magnetic field is varied in the range of 360 Hz to 3.70 kHz. Here, both said magnetic field B1 and B2 will be in opposite direction. Further, said transistor is equipped with heat sink that keep cool said transistor. Moreover, by increasing the current, the value of magnetic field in each coil is increased without causing any problem of overheating. Thus, desired strength of electro-magnetic field is achieved in the coils. Further, the heat of entire circuit is also dissipated by the cooling fan (not shown) that is operated by said DC signal or any other external power supply means.

[0028] In another embodiment shown in FIG. 2, for enhancing ranges of variable frequency of the electro-magnetic field, plurality of transistors (4a, 4b, 4c, 4d) are utilized. For sake of understanding, the center tap (2c) and conductor leads (2a, 2b) are shown in the different box. In this embodiment, the transistor 4a, 4b and 4d, are BC337, 2N3904 and 2N2222, respectively are NPN transistor and 4c, is BC327, and is PNP transistor. As shown in FIG. 2, the DC signal from the SMPS is supplied to the center tap (2c) by passing through the regulator means (U1). After that, said signal is passed from said coils towards its conductor lead (2a) and conductor lead (2b). Here, the configuration of said transistor (4a, 4b, 4c and 4d) varies the frequency of electro-magnetic field in the manner discussed below.

[0029] As shown in FIG. 2, a timer (U2) receives signal from the SMPS and applied the signal by logic 0 and 1. Logic 0 present low signal and logic 1 present high signal. When, the timer (U2) sends the logic 1, the transistor (4a) will be activated so that the signal from the terminal (2a) is applied to the base terminal of the transistor (4b) by passing through the resistor R2. Thus, transistor (4b) will be activated that allows the signal to pass from conductor lead (2b) to negative terminal (1b) of the SMPS. Likewise, when the timer (U2) sends logic 0, the transistor (4c) (PNP transistor) will be actuated so that signal from the conductor lead (2b) is applied to the base terminal of the transistor (4d). Thus, the transistor (4d) will be activated that enable the signal to pass from the conductor lead (2a) to negative terminal (1b) of the SMPS. Further, said timer chips (U2) sends pulse of logic 0 and logic 1 at irregular time interval. By said configuration, the frequency of electromagnetic field produced in the coil is varied in broad range that is more effective for removing scale from the pipes. Here, the frequency of magnetic field induced in the coils is varied in the range of 10 Hz to 400 Hz. Further, in second embodiment, modulated magnetic field is generated. Thus, every time, the frequency and magnitude of electromagnetic field will be varied. Further, in present invention, said timer (U2) is utilized to provide base current to the transistors which is much lower (i.e. in micro ampere) compared to current drawn from timer in R-L-C circuit. Hence, unlike R-L-C circuit, the timer doesn't get hot according to present invention.

[0030] According to present invention, by variation in frequency of alternating electro-magnetic field, a multiple decrease in the amount of calcium in the deposit is achieved. Thus, formation of scale in the pipe is removed. Thus, the installation of the instant invention on the main water supply line of a residence may prevent the formation of scale within the piping system of the home.

[0031] The invention has been explained in relation to specific embodiment. It is inferred that the foregoing description is only illustrative of the present invention and it is not intended that the invention be limited or restrictive thereto. Many other specific embodiments of the present invention will be apparent to one skilled in the art from the foregoing disclosure. All substitution, alterations and modification of the present invention which come within the scope of the following claims are to which the present invention is readily susceptible without departing from the spirit of the invention. The scope of the invention should therefore be determined not with reference to the above description but should be determined with reference to appended claims along with full scope of equivalents to which such claims are entitled.