BRPI0809113A2 - high frequency disintegrator - Google Patents

Abstract

HIGH FREQUENCY DISINTEGRATOR. A high frequency disintegrator includes a plurality of high frequency vibration generators, a plurality of connectors and at least one heat exchanger. High frequency vibration generators have an operational portion that axially releases high frequency vibration energy. The connectors are connected respectively to the high frequency vibration generators, and each includes an action portion that allows the operational portion to axially release the high frequency vibration energy, an input and an output, where the input and output are connected to the action portion. The connectors are connected in series. The heat exchanger device dissipates heat from the connectors. The high frequency disintegrator eliminates the drawbacks of conventional techniques.

Description

Patent Descriptive Report for: "HIGH FREQUENCY DISINTEGRATOR".

Background of the invention

1. Field of the Invention: The present invention relates to material disintegration techniques and more particularly to a high frequency disintegrator for extracting materials.

2. Description of Related Art: Ultrasound technology is well known in the art for the following applications: medical ultrasound, ultrasonic motion triggering, ultrasound probe, ultrasonic signal detection, and ultrasound. -Sound for industrial processing. Technically, ultrasounds are sounds that cannot be heard by the human ear, and they generate a physical vibration that is transmitted through a medium. For ultrasound in a fluid, the cavity is created in the fluid by highly intense ultrasonic waves. These cavities generate small vacuum bubbles with a diameter of about 0.0001 cm, and these small vacuum bubbles, when broken, are capable of locally generating a pressure of 1000 atm, which in turn creates a strong impact. to remove dirt or hit cell cell walls in materials, thereby releasing the contents (or lysate) of cells when cell walls are broken.

Referring to Figure 1, a conventional ultrasonic disintegrator 1 is illustrated. The ultrasonic disintegrator 1 includes an ultrasound device 11, a vibration head 12 connected to the ultrasound device 11, a content device 13, and an excitation device 14. The ultrasound device 11 is installed in the center of the content device 13. The vibrating head 12 has a piezoelectric material (e.g. a piezoelectric blade) in it through which a piezoelectric effect is generated, thereby creating a high frequency. of vibration. In addition, the content device 13 contains a medium and a material (such as a solid) in the same. The medium may be a liquid medium for transferring high frequency vibration energy, for example, a liquid based fluid (such as water). The excitation device 14 is installed within the content device 13 to continuously excite the media and materials.

By using the ultrasonic disintegrator 1, during disintegration of the material, in practice the vibrations of the vibration head 12 high frequency transfers of energetic vibrations containing the device 13, allowing a plurality of small vacuum bubbles to be generated. By cavitation, the medium around the vibration head 12. And, an impact created when the small bubbles are broken vacuum is used to disintegrate the material, thereby realizing the result of the disintegrating material.

However, cited by conventional technique, such as ultrasound apparatus and 11 to 12 vibration heads are located in the center of the content device 13, the vibration head 22 transfers to high frequency downward energy vibration, and therefore the vibration of the high frequency generated energy tends to be easily concentrated in the center and gradually decreased towards the periphery of the content device 13. As such, the material situated on the periphery of the content device 13 cannot be effectively disintegrated as expected due to insufficient vibration thus leading to uneven disintegration. Also, due to this inequality, the medium and the materials must be repeatedly agitated. Even so, it is difficult to confirm whether or not the desired leveling is achieved, although the amount of disintegrated material obtained is limited even after a long period of operation. Thus, the above conventional technique is applicable only at laboratory scale for use, but not for large scale use. In addition, the conventional ultrasonic disintegrator content device 13 is almost closed. As the high frequency energy vibration continues to disintegrate material in the content device 13, a large amount of heat is generated, thereby increasing the temperature of the medium. When this happens, the disintegration process must be terminated and an additional cooling temperature step must be performed to prevent the average from being overheated, so as not to affect the stability and integrity of the properties of the disintegrated material. In particular, when crumbling a material such as Chinese herbal natural medicine, organic products, etc., a high temperature typically destroys the cell structure or lysed content of the material to be extracted.

In other words, even though said conventional technique may disintegrate the particulate powder material, it is not capable of performing an extraction process. And, the amount of material that can be disintegrated at a time is limited, such that the conventional technique is not suitable for large scale use. As shown in Figure 2, Taiwan Patent Application η. No. 093119250 discloses another conventional ultrasonic disintegrator 2. The ultrasonic disintegrator 2 includes an ultrasound device 21, a vibration head 22 connected to the ultrasound device 21, and a vibrating carrier device connected to the vibration 23 head 22. The vibration head has a piezo-electric material 22. The carrier suspension 23 device includes a transmission tube 231 connected to the vibration head 22, a transmission pump 232 connected to the transmission tube 231, and a cooler 233 connected to the transmission. tube 231 thus using the transmission pump 232 to control the flow velocity, and allowing material and flow averages in the transmission tube 231 to disintegrate.

However, the conveyor suspension device 23 of the conventional ultrasonic disintegrator 2 is almost closed. Even if the cooler 233 is installed in the carrier suspension device 23, because the 233 is cooler inside the suspension device 23, when the device 21 ultrasound and continues to operate the internal temperature of the suspension device 23 continues to rise, The temperature-cooling effect of cooler 233 cannot compensate for the increase in average temperature in the device carrier suspension 23, ie, cooler 233 is unable to prevent the rise in average temperatures, causing the material to block transmission tube 231. Thus As with the above conventional using disintegrator ultrasound technique 1, the average temperature is increased during the operation of 2 disintegrator ultrasound and the disintegration process should be terminated thereafter in order to allow an additional step cooling temperature to be done to prevent the way of being too much and to avoid affecting the materials s and the crumbled powder particles. This insufficiency, however, increases the processing time.

In addition, to be connected to the vibration head, the transmission of this ultrasonic disintegrator tube 231 must be larger than the vibration head 22, and accordingly, the vibration head has relatively less 22 functional unit and more Short functional time. In order to achieve leveling, materials must be continually disclosed. However, as head vibrations 22 transfers to high frequency low energy vibration, if the material distributed by such an ultrasonic disintegrator 2 is located on the side wall of the transmission tube 231, it may not receive sufficient energy vibration and then the effect can not wait for disintegration to be achieved. Even if the material is situated right in the center of the transmission tube 231, effective disintegration can not be achieved, but also due to the short running time of the continuously disclosed material to be applied. As a result, even when material is continuously distributed, it cannot guarantee that effective disintegration of all material is accomplished.

Although the above ultrasound disintegrator can disintegrate nanoscale powder particle material, it cannot effectively control the temperature in it and has limited operational / functional location and time, and this can destroy the structure of the content (or lysate ) of the material and is not applicable for actual disintegration and extraction. Accordingly, the above disintegrating ultrasound is not suitable for large scale use. Furthermore, said two conventional ultrasonic disintegrators are independent and each single device. When huge amount of disintegrating material is required, a considerable number of associated devices / equipment must be used simultaneously. Thus, if conventional techniques are applied to large scale use, the cost of manufacturing is certainly increased.

Therefore, the problem to be solved here is to develop a technical disintegration material, which even provides for constant disintegration and control temperature and is applicable for large scale use in order to overcome the disadvantages of the above conventional techniques. Summary of the Invention

In view of the exposed drawbacks of conventional techniques, it is an object of the present invention to provide a high frequency disintegrator to achieve even disintegrating material. Another object of the present invention is to provide a high frequency disintegrator effective for controlling the temperature therein.

Another object of the present invention is to provide a high frequency disintegrator applicable for large scale use.

To achieve the above and other objectives, the present invention provides for a high frequency disintegrating invention comprising: a plurality of high frequency vibration generators each having axially operationally installed high frequency energy vibration output portion; a plurality of connectors respectively connected to the plurality of high frequency vibration generators, each of the connectors comprising an operational action portion allowing the high frequency axially energetic vibration output portion, an inlet, and an output, where the inlet and output communicate with the portion action and are located in different axial planes from each other, and the connectors are connected in series, and at least one heat exchange device connected to the connectors, for heat dissipation from connectors .

In the high frequency disintegrator, the action portion is an axially extended channel action. In one embodiment, there is an extended extension of a final portion of the action opposite the operational portion, so as to increase the duration of the channel action and further to increase the time at which the high frequency energetic vibration acts on a material introduced into the disintegrator. high frequency, such that the material can be more evenly disintegrated. In other embodiments, the axial length of the portion action may be directly increased to increase the path length and height at which the high frequency energetic vibration acts on the material.

Compared to conventional techniques, the high frequency disintegrator according to the present invention encompass the plurality of mutually connected connectors in series, each connector having a relatively long portion action, and the heat exchange device that can control the temperature in the high frequency disintegrator. Thus, the high frequency disintegrator can disintegrate the material to a desirable degree of disintegration, and eliminates the drawbacks of conventional techniques such as inapplicable for large-scale use, uneven and ineffective temperature control disintegration. Brief Description of the Drawings

Figure 1 is a structural schematic diagram of a conventional ultrasonic disintegrator.

Figure 2 is a structural schematic diagram of an ultrasonic disintegrator disclosed by Twain patent application No. 093119250;

Figure 3 is a structural schematic diagram of a high frequency disintegrator according to the embodiment of the present invention.

Figure 4 is a schematic diagram showing a state operation of the high frequency disintegrator illustrated in Figure 3.

Figure 5 is a schematic diagram showing an application of a high frequency disintegrator according to another embodiment of the present invention. Figure 6 is a schematic diagram showing an application of a high frequency disintegrator in accordance with a new embodiment of the present invention. Detailed Description of Preferred Embodiments

Preferred embodiments of a high frequency disintegrator proposed by the present invention are described in detail as follows with reference to Figures 3 to 6. It is to be understood that the drawings are simplified schematic diagrams showing only the components relevant to the present invention, and the Component layout could be more complicated in its practical application.

Figures 3 and 4 illustrate a high frequency disintegration according to the embodiment of the present invention. Referring to Figure 3, a high frequency disintegrator 3 according to the embodiment of the present invention includes: a plurality of high frequency vibration generators 31, a plurality of 32 connectors respectively connected to high frequency vibration generators 31 and at least one heat exchange for the heat dissipating device 33 from the plurality of connectors 32.

In this embodiment, the high frequency vibration generator may be an ultrasonic vibration generator or any other equivalent component that may generate a high frequency of vibrations. High frequency vibration

The generator has an axially installed operating portion 311, and in the operating portion 311 axially outputs a high frequency of energy vibration (such as centered ultrasound). Operative part 311 may comprise a piezoelectric material or any other equivalent material.

The 32 each connectors can be a long member made of a high strength pipe such as stainless steel material, titanium alloys, high nickel alloys, etc. The 32 connectors are mutually connected in series and are sequentially coupled to, high frequency corresponding to vibration generators 31. In this embodiment, the connectors 32 each action includes an axially installed portion 321, an extension portion 322 connected to the portion 321, a flexion portion 323 connected to the extension portion 322, connecting a portion 324 connected to the portion 321 action. , a clamping portion 325 connecting to the 324 portion connecting the high frequency vibration generator 31, an inlet 326, and an outlet 327, where the inlet 326 and the establishments situated on different axial planes and 327 are connected to the portion 321 action. action may be a portion axially enlarged action channel so as to increase the path and time through which a material al introduced in the zone of high frequency disintegrator 3 passes. The extension portion 322 is axially extended from the action portion 321 in a direction opposite to the operating part 311, to further increase the path and time through which the material passes. The extension portion 322 communicates with the flexing portion 323. The alloy portion 324 is coupled to an end portion 321 portion corresponding to the operating portion 311. In this embodiment, the connection portion 324 may be provided around a metal tube and attached to the portion. allowing a front portion of the operating portion 311 to enter the portion 321 action. The attachment may be a ring-shaped portion 325 C, which may be attached to the operating portion 311 peripherally by fasteners such as screws (not shown). . Inlet 326 is formed on one side of portion 321 action and communicates with portion 321 in order to introduce the material and a means for portion 321 action through inlet 326 (to be described later). The outlet is located 327 at the end of a bend portion 323 opposite the extended portion 322. The outlet inlet 327 and 326 are located on different axial planes. Note that for ease of manufacture, connector 32 may be assembled and fabricated at various stages in the present embodiment. For example, the portion 321 action, connecting portion 324 and 326 of the cove are integrally formed, and the portion 323 and 327 are integrally formed. Alternatively, connector components 32 may be manufactured separately from the following three groups: portion 321 action, connecting portion 324 and 326 of the inlet, extension portion 322; and folding portion 323 and outlet 327. It is also understood that all or some of said connector 32 components may be integrally formed. The portion extension 322 may be omitted, and the portion 321 actions are directly extended. The extension portion 322 and 323 the portion flexion may be omitted, as well as portion actions 321 are directly widened and partially folded. In other words, the present invention may also adopt any equivalent structure wherein the connector 32 is connected to a high vibration frequency of generator 31, the operating part 311 may axially output high frequency energetic vibration, the action has a portion 321 axially extended action channel, and intake windows and 326 to 327 runoff communicate with portion action 321 are located in different respectively axial aircraft. In addition, the portion connection is installed around 324 to 311 and the operating portion is fixed to the operating portion by clamping portion 311 to 325 in this embodiment, while in other embodiments, if the connection portion 324 has been strongly bent or fixed towards the operational portion 311 of securing the portion corresponding to 325 and closures may be omitted. The heat exchange device 33 of this embodiment may include a heat exchanger 330, where the heat of 330 may be a plate composed of a heat exchanger and inlet material 331, an outlet material 332, an inlet fluid 333 and a fluid flow 334. Inlet material 331, outlet material 332, inlet fluid and 333 to 334 fluid flow are provided on sides of heat exchanger 330. Inlet material 331 communicates with outlet material 332, and inlet fluid 333 communicates with fluid flow 334. 327 The outlet of one of the connectors 32 is connected to the heat exchange inlet material 331 of this device 33, and the heat exchange outlet material 33 is a device connected to the inlet 326 on one side one of the connectors connected in 32 series. The heat exchange at least one device 33 may include a plurality of heat exchange 33 devices connected in series. The heat output 332 on one side the heat of an exchange of 33 serially connected devices can be connected to the inlet 326 on one side the serially connected connectors 32. This is thus a series of connection setup. Inlet fluid 333 from each of the 33 heat exchange devices may be externally connected to a cooling device (not shown), and the fluid flow 334 from each of the heat exchange devices 33 may be connected to one containing component. (not shown). The component is containing, for example, a water tank.

Thus, a liquid (such as cold water) may be introduced into the heat exchange through the cooling device 33, and after performing the heat exchange in the heat exchange device 33, a liquid (such as hot water) generated after the heat exchange. Heat is then drained out by flowing fluids into 334, for example those containing components, to control the temperature. Alternatively, in other embodiments, fluid flow 334 may be connected to the above mentioned cooling device, thereby omitting containing the component. This allows the cold and hot fluid heat exchange within the device 33 to circulate and thus achieves good control of the effect temperature, Figure 4 shows a high frequency disintegrator operating state of this embodiment. As shown in Figure 4, when in operation, the high frequency disintegrator 3 of the present invention is connected to a machine externally 4, allowing machine 4 to be connected to inlet 326. Machine 4 contains a medium and a material to be disintegrated (both not shown) in it. In this embodiment, the average is, but is not limited to, a liquid such as pure water. In other embodiments, the media may be a gas or any other fluid. The material may be any material to be disintegrated, such as teas, ganoderma, mushrooms, fruits, pearls or any material that requires disintegration in order to extract the lysate content from the material. The media is used to send or deliver the material and allow the material to enter the action path 321 portion cove 326. The operating part 311 outputs axially high frequency energetic vibration to generate a strong impact to the disintegration of the material. As the action offers a relatively long path 321 portion to the high frequency of energy vibrations to disintegrate the material, and the portion 321 actions in this embodiment axially is further bound to the 322 portion extension, the material can then be continuously subjected to the high frequency energy vibration in the single connector 32. Thus, the path and time that the operating part impacts 311 on the material are high enough to disintegrate the material, thereby increasing the evenness of dust particles after disintegration of the material, and allowing the content ( or lysed) of the material to be fully released.

After the long run and time to impact the material, the disintegrated material is transmitted through the media and goes through the 323 and the double portion is then drained out from the first connector 32 (left one shown in Fig. 4), through outlet 327, and thereafter the material enters the heat exchange device 33. The heat exchanger 330 has a heat dissipating portion (not shown) there for the medium and the material to pass therethrough. The fluid passes through the inlet fluid flows around 333 the heat dissipation at the very lowest temperature portion of the disintegrated material in the medium, thereby maintaining the material at a constant temperature. It is understood that the heat exchange device 33 of the present embodiment may include any existing heat exchanger, and the specific structure is not further detailed here. After being subjected to temperature control, the material exits through the output material 332 and enters the portion 321 ° action of the next connector 32 (one half shown in Fig. 4). Said process is then repeated disintegration. As such, various material disintegrations are realized to desirably achieve even material disintegration. Compared to conventional technique, the high frequency disintegrator of this embodiment can disintegrate more material and maintain the material at a successful constant disintegrating temperature, thus suitable for large scale use.

In this embodiment, the high frequency disintegrator 3 comprises three high frequency vibration generators 31, three connectors 32 and heat exchange three devices 33 which are connected in series. This allows more material to be disintegrated simultaneously and also facilitates a subsequent extraction process. Alternatively, in other embodiments, higher vibration frequency generators 31, connectors 32 and heat exchange device 33 may be connected in series in response to different operating situations. Even though only a high frequency vibration generator 31, a connector 32, and a heat exchange device 33 are used, the high frequency of the present disintegrating invention still provides for increased time and action path may and effective temperature control compared with the conventional technique. Hence, the design series allows for more effective bonding and even disintegration of all material and ensures the integrity of the material (or lysed) content by temperature control.

Note that in this embodiment the material is transmitted through the media (such as water), and therefore the material after disintegration is mixed with water. Therefore, prior to extraction, a technical separation is adopted to separate the disintegrated material from water and then the content (or lysate) of the material can be extracted. For example, a branch system (not shown) is provided to allow the disintegrated and medium material to pass through a filtering portion (such as a membrane or a centrifugal separation) to branch the system and to be separated into liquid and powder particles. (such as water). As said separation technique is a general conventional separation technique, its theory and action are known in the art and are no longer described herein.

In addition, during the disintegration process performed by the high frequency disintegrator of this embodiment, the power of the high frequency vibration generator 31 may be adjusted in response to different operating situations. For example, in order to obtain nanometer scale of dust particles, the power of high frequency vibration 31 generator can be increased to allow the material to be disintegrated into nanometer scale, powder in a short time, thus obtaining nanometer scale , dust particles at a faster rate. In order to extract a liquid extract from the material, the power of the high frequency vibration generator 31 may be reduced in order to disintegrate the material until the desired material contents are released; then, said technical separation is used to separate the disintegrated material from the liquid powder particles, thereby obtaining the liquid from the material.

When the high frequency vibration generator 31 operates, ultrasonic energy thus generated allows the temperature of the medium and the material to rise dramatically. And throughout portion 311 operates operating, the faster the temperature rises. Thus, it is desirable for the use of a heat exchange device 33 to have a good control of the effect temperature, such that the optimum effect temperature control can be achieved in a short period of time, making the entire extraction process in a steady state. performed at constant temperature and avoiding any change in the content (or lysate) of the material. In this embodiment, the heat exchange device 33 may be connected to an external cooling and water device. Hot has a drain design, thus providing good cooling and temperature control effect. Further information on this embodiment, each connector 32 is connected to a heat exchange device 33, thereby providing excellent temperature lowering temperature control and effects. In addition, the heat exchange device 33 of the present invention is not limited to the shapes shown in figures 3 and 4. Any configuration having inlet material 331 being connected to outlet 327, output material 332 for transmission of material to the next connector. 32, the fluid inlet 333 externally by being connected to the refrigeration apparatus, and 334 for the flow of hot water out drainage fluids, can serve as the heat exchange device 33 of the present invention, Figure 5 shows the application of a disintegrator of high frequency according to another embodiment of the present invention, wherein the same or similar components to said embodiments are labeled with the same or similar reference numerals and detailed descriptions thereof are omitted.

As shown in FIG. 5, the heat exchange device 33 of the high frequency disintegrator 3 in this embodiment differs from that in said embodiment in that the heat exchange device 33 of the present embodiment includes a plurality of heat exchangers. 330, containing one component for receiving 338 the plurality of heat exchangers of 330, and for transmitting components 339. In this embodiment, the component containing 338, for example, is a large water tank drained within the plurality of the heat exchangers. 330, and contains a 3381 cooling fluid, like water in it. The size of the 338 containing component is sufficient to accommodate all 330 heat exchangers that are connected in series. The 339 transmission components are provided on both sides of the disintegrator. high frequency 3, and are movably connected to high frequency vibration generators 31 to heat exchangers 330 to be immersed in coolant 3381. During the disintegration process, the motion of 339 transmission components can be controlled such that direct transmission components 339 drive heat exchangers 330 connected to connectors 32 to advance to the component containing 338 for cooling and temperature control.

Although the transmission components 339 in this embodiment are installed on two faces of High Frequency Disintegrator 3 and are movably connected to high frequency vibration generators 31, the position and structure of the transmission network in other embodiments 339 for example 339 the transmission components may be connected to connectors 32, provided that the drive heat exchanger 330 to be immersed in coolant 3381. Prevention of the invention is not limited to this embodiment. can be submerged in 3381 coolant within the 338 containing component. This is advantageous for a material that requires a lower temperature disintegration due to the constant low temperature control can be provided, figure 6 shows an application of a high frequency disintegrator according to a new embodiment of the present invention wherein the same or similar components to said embodiments are labeled with the same or similar reference numerals and detailed descriptions thereof are omitted.

As shown in Figure 6, the high frequency disintegrator 3 'of the present embodiment is distinct from those included in the above-mentioned non-heat 330 embodiments. The heat exchange device 33 'includes a component containing 338, a fluid cooling 3381 contained in the transmission containing component 338 and 339 components in order to directly perform thermal dissipation on the plurality of connectors 32. For the plurality of connectors 32, respectively connected to high frequency vibration generators 31, the output of each of the 327 connectors 32 is connected to the inlet 32 32 another connector 32 via a transmission tube 34, and thus the high frequency vibration 31 generators are connected to another one in series. The component containing 338 is a large water tank, and is installed under the plurality of connectors 32 and transmission tubes 34. The transmission 339 components are provided on two sides of the high frequency disintegrator 3, and are movably connected to power generators. high frequency vibration 31. When routing the transmission components 339, the plurality of the 32 pipe 34 and transmission connectors may be immersed in coolant 3381, as the cold water temperature drops where it is held, to allow the 32 connectors and 34 transmission tubes that must be kept at a suitable temperature and achieve temperature control effect.

It is understood that any configuration that may drive connectors 32 to be immersed in coolant 3381 may serve as the transmission of the Elements of the present invention. A cooling device (not shown) installed or externally connected to the circular containing component 338 and cooling fluid in 3381 to the 338 containing component so as to maintain fluid cooling at 3381 at a specific temperature. As such, the temperature of the material at 32 and the connectors to 34 transmission pipes can be controlled, thus saving the equipment relatively cost. In comparison to the conventional technique, the high frequency disintegrator of the present invention is formed by a plurality of high frequency vibration generators, a plurality of connectors and a plurality of heat exchange devices, which are connected in series, allowing the connectors to provide more time and the path to action simultaneously and evenly disintegrate more material so that the high frequency disintegrator is ready for large scale use. In addition, temperatures during and after material disintegration are effectively controlled to ensure the integrity of material properties and large-scale use. Based on the foregoing, the high frequency disintegrator of the present invention has solved the various drawbacks in the state of the art and is highly susceptible to industrial application. The invention has been described using exemplary preferred embodiments. However, it is to be understood that the scope of the invention is not limited to the disclosed embodiments. Rather, it is intended to cover several similar modifications and agreements. The scope of the claims should therefore be given to the broader interpretation to cover all such modifications and similar agreements.

Claims (8)

1. High frequency disintegrator characterized by the fact that it comprises: a plurality of high frequency vibration generators each having an axially installed operating portion for releasing high frequency vibration energy; a plurality of connectors respectively connected to the plurality of high frequency vibration generators, each of the connectors comprising an action portion to allow the operating portion to release high frequency vibration energy axially, an input, and an output, where the input is the outlet communicate with the action portion and are located in different axial planes relative to each other, and the connectors are connected in series, and at least one heat exchanger device connected to the connectors, for heat dissipation from connectors. High frequency disintegrator according to claim 1, characterized in that the high frequency vibration generators are ultrasonic vibration generators. High frequency disintegrator according to claim 1, characterized in that each of the connectors comprises an extended portion of one end of the action portion opposite the operating portion. High frequency disintegrator according to claim 1, characterized in that each of the connectors further comprises a connecting portion connected to the action portion and a fixing portion connecting the connecting portion to a corresponding generator. high frequency vibration High frequency disintegrator according to claim 1, characterized in that the exchanger comprises at least one heat exchanger. High frequency disintegrator according to claim 5, characterized in that the heat exchanger comprises a material inlet, a material outlet, a fluid inlet and a fluid outlet, wherein the outlet of one of the connectors are connected to the material inlet and the input of an adjacent one of the series connected connectors is connected to the material outlet. High frequency disintegrator according to claim 1, characterized in that the heat exchanger device includes a content component and a cooling fluid contained in the content component. High frequency disintegrator according to claim 1, characterized in that the heat exchanger device further includes at least one transmission component for driving the connectors to be submerged in the coolant.