BRPI0806052A2 - connector and high frequency vibration device having the same - Google Patents

Abstract

<B> HIGH FREQUENCY VIBRATION CONNECTOR AND DEVICE HAVING THE SAME. <D> A connector is provided, which is applicable to a high frequency vibration generator of a frequency disintegrator. The high frequency vibration generator has an operational portion installed axially to release high frequency vibration energy. The connector includes a connecting portion axially connected to a high frequency vibration generator, an action portion extending axially from one end of the connecting portion, and an inlet and outlet, which communicate with the action portion and are located on different planes in relation to each other. A high frequency vibration device having the connector is also provided.

Description

Report of the Invention Patent for: "HIGH FREQUENCY VIBRATION DEVICE CONNECTING THERE".

Background of the Invention

1. Field of the Invention:

The present invention relates to material disintegration techniques and more particularly to a connector applicable to a high frequency vibration generator and a high frequency vibration device having the connector.

2. Description of Related Art:

Ultrasonic technology is well known in the art for the following applications: medical ultrasound, ultrasonic motion disc, ultrasonic probe, ultrasonic signal detection, and ultrasound 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, cavitation is created in the fluid by highly intense ultrasonic waves. . These cavities generate small vacuum bubbles with a diameter of about one thousand centimeters, and these small vacuum bubbles, when broken, are locally capable of generating a pressure of 1000 atm, which in turn creates a strong impact to wash away dirt or dust. striking the cell wall of material cells, thereby releasing cell content (or lysate) when the cell walls are broken. Material for use in disintegration, ultrasound must be transmitted by a means of communication. Referring to FIG. 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 device containing 13, and a stirring device 14. The ultrasound device 11 is installed in the center of the device containing 13. Vibration12 The head has a piezoelectric material (eg, piezoelectric blade) in it through which a piezoelectric effect is generated, thus creating a high frequency of vibration. In addition, the device containing 13 contains a medium and a material (such as a solid) in it. Media can be a high frequency liquid transfer medium energy vibration, for example, a fluid based on a liquid (such as water). The stirring device 14 is installed inside the device containing 13, continuously stirring for the midrange and the materials. Through the use of the ultrasonic disintegrator 1, during the disintegration material, in practice the vibrations of the vibration head 12 high frequency transfers energy vibrations containing device 13, allowing a plurality of small vacuum bubbles to be generated by cavitation at medium around the vibration head 12. And, an impact created when the small vacuum bubbles are broken is used to disintegrate the material, thereby realizing the result of the However, cited by conventional technique, such as ultrasound equipment and 11 to 12 vibration heads are located in the center of the device containing 13, high frequency transfer vibration 22 downward energy vibration, and therefore the vibration of high energy generated frequency tends to be easy In the center and gradually decreased towards the periphery of the device containing 13. As such, the materials situated on the periphery of the device containing 13 cannot be effectively disintegrated as expected due to insufficient energy vibration, thus leading to uneven integration.

Also, due to this inequality, the medium and osmaterials must be repeatedly agitated. Even so, it is difficult to confirm whether the desired leveling is achieved or not, although the amount of disintegrated material obtained is limited even after a long period of operation. Thus, the above conventional technique is applicable only for laboratory scale use, but not for large scale use.

In addition, the device containing 13 of the conventional ultrasonic desintegrator 1 is almost closed. When the high energy vibration frequency continues to integrate material into the device containing 13, a large amount of heat is generated, thereby increasing the temperature of the medium. When this happens, the disintegration process should be terminated and an additional step of cooling temperature should 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 disintegrating a material such as Chinese herbal natural medicine, organic products, etc., a high temperature usually destroys the cell structure or lysed content of the material to be extracted.

In other words, even if said conventional technique may disintegrate the powdered particulate material, it is not capable of performing an extraction process. And, the amount of material that can be disintegrated for a while is limited, such that the conventional technique is not suitable for large scale use.

As shown in FIG. 2, Taiwan Patent Application η. 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 suspension device carrier connected to the vibration 23 head 22. The vibration head has a electro-electric material 22. The conveyor suspension device 23 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 speed. , And allowing the material and flow averages in the transmission tube 231 to disintegrate.

However, the transmission tube 231 of the conveyor suspension device 23 of the conventional ultrasonic disintegrator 2 is radially installed under the ultrasound apparatus 21 and the vibration head 22.Dai, the vibration 22 heads only acts on the material located within a radial height of the transmission pipe 231, and at radial height is only about an inner diameter of the transmission pipe 231, such that the action is extremely short distance. As the time at which vibration head 22 acts on the material is relatively short, uneven disintegration occurs easily. And, when the crumbled material particles are different in size due to different degrees of disintegration, a subsequent extraction process would be impaired, thus degrading the extraction and extraction progress. In addition, to be connected to the vibration head, the transmission of this 231 ultrasonic tube 2 disintegrator must have a larger size than the 22 head vibration, in that sense, the head vibration has relatively less 22 unit area and shorter action time. In order to achieve leveling, materials should be continually disclosed. However, as the vibrations head 22 transfers at 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 cannot wait for disintegration. be achieved. Even if the material is situated right in the center of the transmission tube 231, effective disintegration cannot 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 be guaranteed that effective disintegration of all material will be fulfilled.

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 should 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 can overcome the drawbacks of conventional techniques.

Summary of the invention

In view of the exposed disadvantages of the conventional technique, one object of the present invention is to provide a high frequency vibration connector having the same device to achieve even disintegrating material.

Another object of the present invention is to provide a high frequency vibration connector of the same device in order to increase its effectiveness.

Still another object of the present invention is to provide a connector and a high frequency vibration of the same device suitable for large scale use.

Another object of the present invention is to provide a same frequency device and high vibration connector that are cost effective. To achieve the above and other objectives, the present invention provides a high frequency connector and vibration having the same device. where the connector is applicable to a high frequency vibration generator, allowing the high frequency vibration generator to generate high frequency energy vibration output. The connector includes a connecting portion, an action portion, an inlet and an output. The bonding portion is connected to a high frequency of vibration of the generator. The action is technicallyaxially extended from a final connection portion, allowing the high frequency vibration generator to generate high frequency energy vibrationaxially. The inlet and outlet communicate with the action portion and are located in different axial planes of each other.

The high frequency vibration generator has an operational portion that is output at a high frequency axially energetic vibration, where the operating technique is axially connected to the connecting portion. The action is technical, for example, an axially widened channel action. The operating results ultrasonic vibration portion axially in the action technique. In one embodiment, the connector further comprises an extension fully extended from a final portion of the oppositional portion of the operating technique, thereby increasing the duration of action and the time channel action through which the high energy vibration frequency affects a deforming material more evenly to disintegrate the material. . In other embodiments, the axial length of the portion action may be directly increased to widen the path (length) and time at which the high energy vibration frequency acts on the material.

In addition, said high frequency vibration device may be formed by a connector and a high frequency vibration generator. Alternatively, the high frequency vibration device may contain a plurality of serially connected connectors with a plurality of high frequency vibration generators, thus allowing the connectors to be serially connected to each other. Compared to conventional techniques, the connector of the present invention has an action portion relatively long, thus extending relative to the time when the high frequency vibration operative technique operates on the material, such that the problem of material inequality in disintegration can be solved while the efficiency can be enhanced in the present invention. In addition, the connectors can be connected in series to each other, making the high frequency vibration device suitable for large scale use, thus effectively solving the problem of conventional techniques not of large scale use. In addition, throughput may be increased over the array arrangement in the present invention such that the present invention provides a cost-effective and cost effective way for the manufacturing industry compared to conventional techniques where a considerable number of associated devices / equipment is required.

Brief Description of Drawings

FIG. 1 is a schematic diagram of a conventional ultrasonic disintegrator;

FIG. 2 is a structural schematic diagram of an ultrasonic disintegrator disclosed by the Taiwanese Patent Application η. 093119250;

FIG. 3D structural is a schematic diagram of a connector according to the embodiment of an invention;

FIG. 3B is a cross-sectional side view of the connector shown in FIG. 3A; FIGS. 4A and 4B are structural schematic diagrams a high frequency vibration device having a connector according to the present invention; eFIG. 5 is a schematic diagram of an effective application of a high frequency vibration device according to one embodiment of the present. Detailed Description of Preferred Embodiments Preferred embodiments of a connector and a high vibration frequency having the same device as proposed by the present invention. are described in detail as follows with reference to FIGS. 3A, 3B, 4 and 5. It should be understood that the drawings are simplified by schematic diagrams showing only the components relevant to the present invention, and the layout of the components may be more complicated and the number of components may be adjusted for practical application. The present invention is applicable. at a high frequency disintegrator. The high output frequency can generate high frequency vibration from the vibrating energy of the connector, thus allowing a material to be disintegrated by utilizing the energy generated by a high frequency generator vibration as well as to extract the content (lysate) of the material.

FIGS. 3A and 3B are schematic diagrams of a connector according to the embodiment of a present invention. As shown in FIGS. 3A and 3B, connector 3 of the present embodiment may be designed as a long tube made of a high strength material, such as stainless steel, titanium alloys, high nickel alloys, etc. In that embodiment, connector 3 includes a connecting portion 31 for being connected. at a high frequency of vibration of the generator (to be described later), an axially widened portion 32 action of an end portion of the alloy 31, an extension portion 33 connected to the action portion 32, a fold portion 34 connected to the widening portion 33, and an inlet 35 and an exit 36, which communicate with the action portion 32 and are located on different axial planes.

The action may have an axially widened channel portion 32 so as to increase the travel and time through which material introduced in the 32 pass portion action. The axially extending portion is extended from 33 to 32 in a portion opposite to that of the portion 31 connection, to further increase the path and time through which the material passes. As a technique of this action the embodiment is connected to the widening portion 33, inlet 35 and 36 outputs communicating with the portion 32 action through extension portion 33. Alternatively, in one embodiment without extending portion 33, the action portion 32 may be directly connected to inlet 35 and exit at 36.

The flexing portion 34 is connected to one end of the extended portion 33, and connecting the 31 is located in the upper technique a final portion of the action 32. The inlet 35 is provided on one side of the action portion 32 and the action portion 32 to allow osmaterials and a medium to be introduced into the portion action32 (to be described later). The outlet may be located at a final portion of the flexion 34 such that inlet 35 and outlet 36 are located on different axial planes. In addition, an inner diameter of 35 the inlet is smaller than the portion 32 action, and therefore excessive material can be prevented from entering the portion 32 at a time, thereby preventing excess material accumulation within the portion 32 action. Note that for easy manufacturing reasons, the connector 3 may be assembled and manufactured in various stages in the present embodiment. For example, by connecting portion 31, portion 32 and inlet 35 are integrally formed, portion 34 and outlet 36 are integrally formed, while extension portion 33 is manufactured separately. It is also understood that all or some of said connector 3 components may be integrally constituted. The extension may be omitted portion 33 and 32 is the extended direct action portion. Alternatively, extension portion 33 and flexion portion 34 may be omitted and 32 is the widened and partially folded direct acting portion. These are just a few examples of the present invention, while the present invention is not limited to such examples. As these examples can be well understood and implemented by qualified technical persons, they are not shown in the drawings.

In other words, the present invention may also rotate any structure equivalent to an action in which an axially extended portion 32 portion of the channel, inlet e35 and outlet 36, which communicate with the portion 32 portion, respectively are located in different axial planes.

FIGS. 4A and 4B schematic diagrams are a high frequency vibration device having a connector according to the present invention. As shown in FIGS. 4A and 4B, the high frequency vibration device includes connector 3 and a high frequency vibration generator 4 installed in connector 3. In this embodiment, the high frequency vibration generator 4 may be an ultrasonic vibration generator or any other equivalent component that may generate a high frequency vibrations. The high frequency vibration generator 4 has an axially installed operating portion that 41 may maxially output high frequency energy vibration (such as centered ultrasound). Operational technique 41 may comprise a piezoelectric material or any equivalent material. In this embodiment, the portion 31 connection may be a metal or sleeve-around tube attached to the operative technique 41, allowing a prior art of the operative technique 41 to enter the portion 32. A gripping portion 42 is used to secure the 31 and connect portion of operating technique 41. The release portion 42, as a ring form C, can be attached to the operating technique 41 peripherally by screw closures (not shown).

It is to be noted that connecting technique 31 is installed around operative technique 41 and is fixed to operative technique by gripping portion 41 into this embodiment, while in other embodiments, the connection portion 31 has been rigidly attached to or occupied with operative technique 41. , the securing portion 42 and the corresponding latches may be omitted. In addition, the portion 31 is not limited to a tube or sleeve, any other equivalent structure connecting the high frequency vibration connector 3 to the generator is suitable to present the invention.

When in real use, inlet 35 connector externally is connected to a machine containing one medium and one material (not shown). In this embodiment, the average is, but not limited to, a liquid, like 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 content (or lysate) of the material. The media is used to send or deliver the material and allow the material to enter the pathway of the inlet portion 32 cue 35. Operational technique 41 axially outputs high frequency energy vibration to generate a strong impact for material integration. The materials are then disintegrated for next work through output 36, and such work may be near the inlet of the connectors or a device in a different heat exchange may be performed. As for the axially portion action 32 is capable of extending yoke from length and operating action portion 41, thus providing a long way for the high frequency of energy vibrations to disintegrate the material. Further information on this embodiment, action 32 is portion axially connected to extension portion 33, such that the material can be continuously subjected to a high frequency of energy vibration in the single connector 3. Accordingly, the present invention increases the path and time that operating technique 41 impacts the material sufficiently to disintegrate the material, thereby increasing the dust particles evenly after material disintegration, and allowing the content (or lysate), of the material to be fully released.

In addition, as portion 33 enlargement is axially extended from the end of portion 31 action, thus allowing portion 32 action to have a longer length, due to the arrangement of portion 33 extension, such that the action once applied to the material in the portion. connector 3 is increased and thus the operating technique 41 may more evenly disintegrate the material. Hence, the material can be sufficiently disintegrated completely to release the content (or lysate), thereby obtaining the same disintegration effect as desired material. 5 is a schematic diagram of an effective application of a high frequency vibration device according to an embodiment of the present invention. Such was shown in FIG. 5, a plurality of 37 transmission pipes may be used to connect a plurality of 3 connectors in series. For example, the one end of one of the 36 connectors 3 (ie, the left on connector 3 FIG. 5) is connected to one end of a transmission tube 37, and another end of 37 is the transmission tube connected to the inlet 35 of the other Connector 3 (or ie connector connector 3 (FIG. 5), and so on. Thus, the high frequency vibration device can be constructed by multiple sets of 3 and the high frequency vibration connectors 4 generators which are connected in series, and is suitable for large-scale use. This embodiment only illustrates an example of the high frequency vibration device consisting of three sets. 3 and the high frequency vibration generators connectors connected in series as shown in FIG. 5; However, persons skilled in the art will certainly understand that the number and shape of components connected to the series do not preclude such an example. For example, two or more sets of 3 and the high frequency vibration generators connectors4 can be connected in series. Alternatively, transmission pipes 37 (such as smooth pipes) may be omitted, while outlet 36 of one connector 3 is permitted to be directly connected to inlet 35 of the other connector 3.The length of outlet 36 and / or inlet 35 may be extended. . Corresponding threaded structures (such as bolts and screw holes) may be provided, respectively, to outlet 36 and 35 inlet to accommodate and surround outlet 36 and 35 to inlet and each other. And, seal rings can be eliminated between exit 36 and the inlet 35 to maintain a closed state. In addition, although adjacent connectors 3 are connected in series in the present embodiment, not all connectors 3 are connected in series, for example, the first 3 connectors. not directly connected to the last connector

3. Alternatively, in other embodiments, the first connector 3 may be directly serially connected to the last connector 3 so as to continuously circulate and disintegrate material.

Therefore, many alternatives, modifications, and variations would be apparent and performed by those skilled in the art such that they are not shown in the drawings and are not further detailed here. Compared to conventional techniques, the connector of the present invention provides a long way to action. At the same time a greater amount of material disintegrate evenly, thus applicable for large scale use. Thus, the problem due to the disintegration of uneven radial and short-range operation - conventional techniques has been solved. In addition, the connector of the present invention is also suitable for the series of connection configuration, and therefore is capable of defecting conventional techniques not suitable for large-scale use due to failure of the configuration serial connection. Therefore, the high frequency and vibration connector having the same device according to the present invention must overcome uneven disintegration deficiencies and not suitable for large-scale use in conventional techniques, such that the present invention has high industrial applicability.

The invention has been described using exemplary preferred embodiments. However, it is to be understood that the scope of the invention does not limit the disclosed embodiments. Rather, it is intended to cover various modifications and in similar arrangements. The scope of the claims, therefore, must be attributed to the broadest interpretation, so as to encompass all such modifications and to the like.

Claims (10)

1. Connector applicable to a high frequency vibration generator of a high frequency disintegrator, allowing the high frequency vibration generator to release high frequency vibration energy, the connector characterized in that it comprises: a connecting portion connected to the generator high frequency vibration, an axially extended action portion of an end of the connecting portion, allowing the high frequency vibration generator to release axially high frequency vibration energy; an inlet and an outlet, which communicate with the action portion and are located on different axial planes respectively. Connector according to claim 1, characterized in that it comprises an extension portion integrally extended from an end of the action portion opposite the connection portion. Connector according to Claim 1, characterized in that an inner diameter of the inlet is smaller than that of the action portion. 4. High frequency vibration device characterized by the fact that it comprises: a high frequency vibration generator having an axially installed operating portion for releasing high frequency vibration energy; a connector comprising a connecting portion axially connected to the operating portion; an axially extended end portion from one end of the connecting portion, allowing the high frequency vibration generator to release high frequency vibration energy axially, and an input and output, which communicate with the action portion and are located on different axial planes, respectively. . High frequency vibration device according to claim 4, characterized in that the connector further includes a fixing portion that connects the connecting portion to the high frequency vibration generator. High frequency vibration device according to claim 4, characterized in that an inner diameter of the inlet is smaller than the action portion. 7. High frequency vibration device characterized by the fact that it comprises: a plurality of high frequency vibration generators each having an operating portion axially installed to release high frequency vibration energy; a plurality of connectors comprising a connecting portion axially connected to the operative portion of a corresponding of the high frequency vibration generators; an axially extending action portion from one end of the connecting portion to allow the corresponding high frequency vibration generators to release axially high frequency vibration energy, and an input and an output, which communicate with the action portion and They are located on different axial planes, respectively, where the connectors are connected in series. High frequency vibration device according to claim 7, characterized in that each of the connectors further comprises an extension portion extending integrally from an end of the action portion opposite the connection portion. High frequency vibration device according to claim 7, characterized in that an inner diameter of the inlet is smaller than the action portion. High frequency vibration device according to claim 7, characterized in that it further includes at least one transmission tube installed between the outlet of one of the connectors and the adjacent one of the connectors.