Current devices used to generate acoustic shock waves using electro-hydraulic principles typically have a finite life with respect to the electrodes used to generate the shock waves. The primary reason for finite life is the increasing spark gap between the electrodes. As the number of shock waves generated between electrodes increases, the electrode surfaces (tips) facing each other are eroded. As the electrode surfaces erode the distance between the tips grow and the effectiveness of electro-hydraulic shockwave generation is diminished. The finite life of the eroding electrodes can require frequent manual adjustment or replacement of electrodes to maintain an effective spark gap. Thus it is desirable to have an electrode arrangement where the tip design allows a longer functional life and at the same time the electrodes' gap distance is maintained automatically at a substantially constant distance to increase electrode life and reduce the need for manual adjustment or replacement of electrodes.
The acoustic shock wave produced in embodiments of this invention can be produced through the time-controlled plasma bubble formation and collapse across fixed electrodes placed in a special liquid medium. The formation of the plasma bubble can start with a purely thermal release, which may be generated by the high conductance between the electrodes. The relatively high conductance may produce a flow of electrons between cathode and anode electrodes, which heats the special liquid medium and contributes to plasma formation. The release of electrons and recombination of active atoms generated during high voltage discharge may be catalyzed by the substances present within the special liquid medium that may consist primarily of water with additives such as catalysts, buffer solutions and fine metals to increase conductivity.
During the plasma formation, the gap between the electrodes can be shortened by the leading charged particles, since plasma itself is populated by the charged particles. As the gap shortens, less energy may be needed to continue formation of the plasma arc (discharge) and as the voltage (potential energy) continues to be supplied to the electrodes this may generate a purely thermal release between the particles enclosed by the gap. The driven out electrons are freely mobile in the plasma gas, and the free electrons can ionize different particles on their way through impact resulting in a nuclear chain reaction that begins and forms the plasma channel between the electrodes. If an electron of an ion is caught in the plasma channel, its energy may be converted into oscillation energy (heat) and light (UV-RADIATION). The created energy can continue to heat the plasma and the surrounding environment. The environment adjacent to the plasma region between the two electrodes may heat so fast that water in the special liquid medium may evaporate forming a gas bubble that may grow rapidly and collapse rapidly once the bubble's internal pressure is overcome by the pressure of the surrounding liquid medium and the reduced potential between the two electrodes, thus producing the shock wave. The plasma formation and collapse may occur in less than a microsecond, and the liquid mixture surrounding the electrodes may remain sufficiently stable to sustain creating the next plasma bubble.
In various embodiments the combination of materials in the electrodes, the particular geometry of the electrodes and the composition of the special liquid medium can create the energy versus time reaction needed to produce the plasma bubble, which ultimately may produce the shock wave. In at least one embodiment of the present invention the combination of the electrode material, their geometry and special liquid medium in which the discharge occurs is optimized for at least one of:
In general, the electrodes in shock wave generation devices for extracorporeal therapy applications are of cylindrical shape and made of special alloys to increase their life expectancy, since in the electrochemical and thermal reaction that occurs during plasma formation some small amount of electrode materials is consumed. This principle is depicted in
As the number of shock waves increase, the electrode surfaces facing each other experience erosion and results in increasing the gap 12. As the gap 12 increases from its nominal value, the efficiency and quality of plasma bubble formation decreases adversely affecting the intended use. At this point, the electrodes 14 and 15 must be readjusted for the proper gap.
Electrodes in Special Liquid Medium
The special liquid medium in which electrodes are placed must be optimized for the intended application. The special liquid mixture is not only important to the formation of the plasma bubble, but it is also a primary factor to electrode tip erosion. The material of electrode tips (for example, DURATHERM ALLOY) and the composition of the liquid medium surrounding the tips must be considered together, because increased conductivity of the fluid will translate to a higher plasma arcing temperature and will increase erosion of the tip. The other equally important optimization is to reduce the formation of the hydrogen and oxygen gas bubbles (from electrolysis of water). Otherwise the medium will become overwhelmed with gas and cause misfiring of the electrodes or reduce the effectiveness of the shockwave due to large gas bubbles acting as an acoustic insulator for transmitting the shock wave to the body. The water used in the liquid mixture is degassed to an oxygen concentration of 2 mg/liter to minimize oxygen bubble formation. The addition of a hydrogenation catalyst will assist in recombining the hydrogen and/or oxygen back into water. An example of a catalyst for this purpose is palladium which has the ability to absorb hydrogen (1200 ml H2/ml Pd). Metals like magnesium or aluminum will act as oxygen absorbers. A common hydrogenation catalyst in industry is Pd/C consisting of an activated charcoal with palladium, the charcoal acts as a carrier for the palladium and is a good electrical conductor. The large porous structure of the charcoal provides a large surface (>500 m2/g) for supplying the palladium (at the surface of the charcoal) for hydrogenation. The activated charcoal also acts to suspend and distribute the palladium throughout the liquid and increases the conductivity of the water. The other special liquid optimization is to reduce misfires that occur due to poor distribution of ions in the water. If the liquid were comprised solely of the water and catalyst, over time the catalyst settles or clumps and is distributed less uniformly (however it is not a homogenous mixture) throughout the liquid and the initial attempts of plasma formation between the electrodes would not occur. To improve the initial misfiring performance, a buffer is also needed in the liquid to set its pH (increase conductivity) and the affect of a buffer in water will remain stable. The amount of buffer and its pH will affect the erosion of the electrodes, with the more conductive medium allowing more electrode erosion. Also, the conductivity of the liquid affects the plasma formation (i.e., increasing the conductivity reduces the size of the plasma region).
Examples of catalysts that can be utilized:
Examples of conductive agents that can be utilized:
An exemplary conductive agents for an embodiment of the invention may be 4 to 4.5 μl pH6/ml water
Examples of colloidal or solubility agents for the catalyst that can be utilized:
An exemplary colloidal or solubility agents for a catalyst used in an embodiment of the invention may be 15 to 30 μl liquid soap/ml water
Test results for different combinations of catalysts and buffers are presented in Table 1 below:
The following are optimal liquid mixtures for exemplary embodiments of the special liquid mixture of the invention:
Spring-Loaded Electrodes
A device generating acoustic shock waves using electro-hydraulic principle shown in
In one embodiment of the invention the electrodes may be arranged where each electrode is supported by a spring-loaded mechanism on one end and a fine mesh structure on the other end as shown in
As the number of shock waves generated by the device increases, the surfaces at the tips of electrodes 214 and 215 experience erosion. As the erosion increases, each compression spring 18 moves the corresponding electrode 214 and 215 towards the supporting structure 16 thus maintaining a constant distance 212 between the tips of electrodes 214 and 215. Since the distance 212 stays constant, the finite life of the electrodes can be greatly increased providing for less frequent adjustment or replacement of electrodes. This type of electrode arrangement can increase the finite electrode life.
An alternative embodiment of electrodes supported by springs is shown in
Another alternative embodiment of spring-loaded electrodes is shown in
A different embodiment for the electrode geometry that utilizes similar in function to
Ring Shaped Electrodes
As shown in
The electrical discharge, when the design shown in
Modified Ring Shaped Electrodes
The electrode geometry shown in
Complementary Profile Electrodes
An alternate embodiment for the shape of the electrodes shown in
Concentric Coplanar Electrodes with Cylindrical Spark Gap
An alternative embodiment to extend the life of the electrodes is shown in
Multiple Electrode Tips
In general, referring back to
Position Adjustable Electrodes
The shock wave device may include a user adjustable electrode positioning device as shown in
Alternatively, in another embodiment shown in
In another arrangement shown in the
In a further embodiment, the spark gap distance 1412 can be adjusted automatically through a mechanical drive train 76 coupled to a stepper motor 74 as shown in
Spark Gap Sensing and Compensating System
An embodiment for a system to sense the gap distance 1512 is shown in
In the case of a shock wave device with manually adjustable electrodes the user is provided an external means to adjust the gap distance of the applicator treatment head as described in
In an embodiment where the adjustment is automated, the control system 1600 may be coupled to a shock wave device with an electromechanical drive 76 as depicted in
In both
The microcontroller 96 may initiate the measurement of the electrode gap 1512 or 1612 by generating a particular impulse voltage or combination of impulse voltages from the HV Generator 80 using the Microcontroller interface Generator Control 102. The voltage generated by the HV Generator 80 would be less than normally used to create a shock wave. The HV Switch 84 is enabled to apply the Generator Output 82 to the treatment head 10 by the control signal HV Switch Enable 104. The impulse voltage and impulse current on the output 86 of the HV Switch 84 is sensed by a Voltage and Current Signal Processor 90. The Voltage and Current Signal Processor 90 converts the impulse voltage and impulse current applied to the treatment head into a digital form 92 and 94 respectively, which is processed by the Microcontroller 96. The Microcontroller software determines the electrode gap distance 1512 or 1612 through the derivation of the Equivalent Capacitance (“EC”) of the treatment head.
The microcontroller 96 may derive the EC by correlating it to the standard electrical capacitance formula for a parallel plate capacitor as shown below:
EC≈∈r(Atip/dgap) Equation 1
The formula of Equation 1 can be replaced by other mathematical models that may be a more complex model of the EC for the treatment head. In the simplest case of Equation 1, “∈r” is the dielectric value of the special liquid medium within the treatment head. The electrode tip surface area (“Atip”) can be considered constant as it is less of a factor compared to the electrode gap distance (“dgap”) in calculating the EC, and the dielectric value can also be assumed to be constant, so the gap distance can be derived by knowing the EC. The microcontroller will measure the voltage (“V”) and current (“I”) applied to the treatment head and from that derive EC using the formula:
In Equation 3, the microcontroller 96 may integrate the measured current (“I”) applied to the treatment head or can measure current decay over a finite period, from that the charge stored in the capacitance of the electrodes is determined which is required to derive the EC. In conclusion, the microcontroller can measure the voltage (“V”) and current (“I”) applied to the treatment head to monitor the distance between the electrodes.
Empirical Electrode Life Span Estimation
Acoustic shock wave pulses produce a distinct audible sound that can be measured using a Sound Pressure Level meter. The measured sound level of continuous pulses falls within a tight range when the ‘spark gap’ is within the design limits. As the ‘spark gap’ distance increases, the measured sound level from continuous pulses starts to diverge from the tight range described earlier. This is an indication of inconsistent plasma bubble formation.
When a combination of optimized catalysts and buffers combined with tip shape and material is used, in accordance with embodiments described in this specification, the data shows an increased longevity of the applicators' lifespan as can be seen in
The foregoing description of the exemplary embodiments of the invention has been presented only for the purposes of illustration and description and is not intended to be exhaustive or to limit the invention to the precise forms disclosed. Many modifications, combinations and variations are possible in light of the above teaching.
The embodiments were chosen and described in order to explain the principles of the invention and their practical application so as to enable others skilled in the art to utilize the invention and various embodiments and with various modifications as are suited to the particular use contemplated. Alternative embodiments will become apparent to those skilled in the art to which the present invention pertains without departing from its spirit and scope.
Accordingly, the scope of the present invention is defined by the appended claims rather than the foregoing description and the exemplary embodiments described therein.
The present application claims the benefit of priority of U.S. Provisional Application No. 61/663,016 filed Jun. 22, 2012, which is incorporated herein by reference.
Number | Date | Country | |
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61663016 | Jun 2012 | US |