Patent Description:
Magnetic transmission device refers to a transmission technology in which a driving end drives a driven end to realize power transmission by using a coupling force generated by a magnetic material installed on the driving end and the driven end in a transmission component. The coupling forces include attractive and repulsive forces between the magnetic materials. For its non-contact power transmission, magnetic transmission is widely used. The magnetic transmission include main advantages that there is no rigid connection between transmission parts, overload protection can be provided, the structure is simple and easy to maintain, and dynamic seal can be converted into static seal, etc. The main applications include vacuum, spaceflight, medicine, food, scientific experiments, special chemical or high-risk fields.

Due to the limitations of magnetic material technology, transmission torque stabilization should be a major limitation in various applications. At the same time, as the large-scale industrial environment, high torque, high stability, high life and maintenance are the main direction of improvement of magnetic transmission technology in recent years, there are a lot of structural improvements and inventions, especially for the distribution of magnetic material layout of the driving end and driven end.

For example, the invention patent document "a coaxial permanent magnet transmission device" (<CIT>) proposes a new magnet coupling layout structure. Compared with the conventional coaxial magnetic transmission structure, this patent increases the magnetic torque that the magnetic transmission can provide by using the communication tube structure and increasing the magnet coupling pair.

For example, the utility model patent document "a magnetic transmission mechanism" (<CIT>) proposes an application of a magnetic transmission structure in the field of fuel gas sealing. By replacing the traditional seal structure with magnetic transmission, the static seal is transformed into the dynamic seal, which can reduce the transmission resistance and improve the structural stability.

In addition, the invention patent document "electromechanical magnetic transmission device" (<CIT>) proposes a new layout structure of driving end and driven end. Compared with the traditional magnetic transmission structure, this patent achieves the purpose of improving the overall transmission efficiency of the system by adding a parallel mechanism so that one driving end can simultaneously drive multiple driven ends.

Compared with the traditional magnetic transmission structure, according to the key technical for the magnetic transmission of interventional devices, if in the clinical application, it requires more high rotation speed rather than high torque; and at the same time, the requirements for specification are higher relative to the transmission application. Accordingly, there remains a need for several aspects of improvements in torque transfer structures, such as a manually assisted blood pumping device, for use in an interventional blood pumping catheter device in which the power source is located outside the body.

<NUM>) It provides a smaller magnetic transmission structure specification, and can still maintain an effective magnetic transmission torque that can meet clinical applications while using miniature magnets; <NUM>) fast connection structure and higher speed of magnetic transmission can meet the needs of high-speed rotation in the clinical application; and <NUM>) effective magnet sealing ensures biocompatibility requirements for clinical use.

Further prior art is disclosed in documents <CIT> and <CIT>.

The technical problem to be solved by the present invention is to provide a quick-connect type magnetic transmission device for a medical interventional instrument, which can meet the application requirements of a small-sized miniature magnetic transmission structure on the medical interventional instrument, and can achieve a high transmission rotation speed and a quick-connection operation.

The technical solution adopted in the present invention to solve the above-mentioned technical problem is to provide a quick-connect type magnetic transmission device for a medical interventional instrument, comprising a driving-side housing and a driven-side housing, wherein the driving-side housing and the driven-side housing are coaxially arranged and nested and connected, and the quick-connection type magnetic transmission device comprises a magnetic coupling structure, a magnetic coupling coaxial guide mechanism and an integral coaxial guide mechanism successively from inside to outside; the magnetic coupling structure is composed of a magnetic transmission driving end, a magnetic transmission driven end and a quick-connect spacing sleeve; the magnetic coupling coaxial guide mechanism is composed of a magnetic coupling guide sleeve and a magnetic coupling guide groove; and the integral coaxial guide mechanism is composed of a coaxial guide sleeve, a coaxial guide groove and a coaxial locking structure; the magnetic transmission driven end comprises a driven rotor spacing sleeve; the coaxial guide groove is composed of an annular space between the inner wall of the driven-side outer shell and the outer wall of the driven-side inner shell; the magnetic coupling guide groove is composed of a space between the inner wall of the driven-side inner shell and the outer wall of the driven rotor spacing sleeve; the inner wall surface of the driven-side inner shell is tightly fitted with the outer wall surface of the magnetic coupling guide sleeve; the magnetic transmission driving end is provided between the outer wall surface of the driven rotor spacing sleeve and the inner wall surface of the magnetic coupling guide sleeve; and the coaxial locking structure is a key and groove provided on the driving-side housing and the driven-side housing and cooperating with each other.

According to the above-mentioned quick-connect type magnetic transmission device for a medical interventional instrument, the magnetic transmission driving end is composed of a driving rotor, a driving rotor spacing sleeve and a driving magnet; the driving rotor is a cylinder having a circular rotation space therein, and the inner surface of the cylinder is provided with a groove; and the driving rotor spacing sleeve is embedded in the circular rotating space, and forms a closed magnet placing groove together with the groove on the inner surface of the cylinder.

According to the above-mentioned quick-connect type magnetic transmission device for a medical interventional instrument, the magnet placing grooves of the driving end have an even number of pairs, the magnets are placed in pairs in opposite directions, and the adjacent magnets have opposite polarities when unfolded in a circumferential direction.

According to the above-mentioned quick-connect type magnetic transmission device for a medical interventional instrument, the magnetic transmission driven end further comprises a driven rotor, a driven magnet and a magnet holder, the driven rotor being a circular shaft; the magnet holder is an elongated cylinder, has a circular assembly space therein, and is assembled on the driven rotor; the driven rotor spacing sleeve is a cylinder and is assembled on the magnet holder; and the surface of the magnet holder is formed with a groove, and constitutes a magnet placing groove at the driven end together with the driven rotor and the driven rotor spacing sleeve.

According to the above-mentioned quick-connect type magnetic transmission device for a medical interventional instrument, the magnet placing grooves of the driven end are an even number of pairs, the magnets are placed in pairs in an opposite direction, and adjacent magnets have opposite polarities when unfolded in a circumferential direction.

According to the above-mentioned quick-connect type magnetic transmission device for a medical interventional instrument, the coaxial guide sleeve and the coaxial guide groove are fitted at a taper, the inner wall surface of the driven-side outer shell is tightly fitted with the outer wall surface of the coaxial guide sleeve, and a gap is left between the outer wall surface of the driven-side inner shell and the inner wall surface of the coaxial guide sleeve.

According to the above-mentioned quick-connect type magnetic transmission device for a medical interventional instrument, the magnetic coupling coaxial guide mechanism and the integral coaxial guide mechanism are fitted at the same taper, and the length of the integral coaxial guide mechanism on the outside is greater than the length of the magnetic coupling coaxial guide mechanism on the inside.

According to the above-mentioned quick-connect type magnetic transmission device for a medical interventional instrument, the taper between the coaxial guide sleeve and the coaxial guide groove is <NUM> : <NUM>.

According to the above-mentioned quick-connect type magnetic transmission device for a medical interventional instrument, a gap between the magnetic transmission driving end and the magnetic transmission driven end is <NUM>-<NUM>, and an overall outer diameter of the quick-connect type magnetic transmission device is <NUM>-<NUM>. According to the above-mentioned quick-connect type magnetic transmission device for a medical interventional instrument, the quick-connect spacing sleeve is located between the magnetic transmission driving end and the magnetic transmission driven end, the magnetic transmission driven end on the inner side of the quick-connect spacing sleeve is located on a catheter and belongs to a sterile area, and the magnetic transmission driving end on the outer side of the quick-connect spacing sleeve is located on a power structure and belongs to a non-sterile area.

The present invention has the following advantageous effects compared to the prior art. A quick-connect type magnetic transmission device for a medical interventional instrument provided by the present invention uses a double guide of a magnetic coupling coaxial guide mechanism and an integral coaxial guide mechanism, which can ensure a high degree of coaxiality in a quick-connection operation, and meet the high-speed rotation requirements in clinical applications. The double-guide lock-fit structure can achieve fast connection while ensuring minimal transmission gap. The dynamic seal of the original transmission shaft is transformed into the static seal between the driving end and the driven end by the magnetic transmission. On the one hand, the seal wear is completely avoided and the transmission resistance is reduced. On the other hand, the driven end can be completely sealed, so as to ensure the sterility in the catheter in the clinical application.

The present invention are further described below in combination with the attached drawings and embodiments.

Referring to <FIG>, <FIG>, the present invention provides a quick-connect type magnetic transmission device for a medical interventional instrument, comprising a driving-side housing and a driven-side housing, wherein the driving-side housing and the driven-side housing are coaxially arranged and nested and connected, and are divided into three layers of a magnetic coupling structure, a magnetic coupling coaxial guide mechanism and an integral coaxial guide mechanism according to functions from inside to outside. Hererin, the magnetic coupling structure is composed of a magnetic transmission driving end <NUM>, a magnetic transmission driven end <NUM> and a quick-connect spacing sleeve <NUM>; the magnetic coupling coaxial guide mechanism is composed of a magnetic coupling guide sleeve <NUM> and a magnetic coupling guide groove <NUM>; and the integral coaxial guide mechanism is composed of a coaxial guide sleeve <NUM>, a coaxial guide groove <NUM> and a coaxial locking structure. The magnetic transmission driven end <NUM> comprises a driven rotor spacing sleeve <NUM>; the coaxial guide groove <NUM> is composed of an annular space between the inner wall of the driven-side outer shell <NUM> and the outer wall of the driven-side inner shell <NUM>; the magnetic coupling guide groove <NUM> is composed of a space between the inner wall of the driven-side inner shell <NUM> and the outer wall of the driven rotor spacing sleeve <NUM>; the inner wall surface of the driven-side inner shell <NUM> is tightly fitted with the outer wall surface of the magnetic coupling guide sleeve <NUM>; and the magnetic transmission driving end <NUM> is provided between the outer wall surface of the driven rotor spacing sleeve <NUM> and the inner wall surface of the magnetic coupling guide sleeve <NUM>.

The core difficulty of quick connection and achieving high-speed rotational stability lies in ensuring the coaxiality of the abutment. In addition, the outer diameter of the quick-connect type magnetic transmission structure of the present invention is significantly reduced relative to the transmission structure, and the reduction of the outer diameter correspondingly results in the decrease of the connection strength, requiring a longer axial mating distance to compensate, thus further increasing the coaxiality difficulty. For this reason, the present invention provides a quick-connect type magnetic transmission device using a double-guide locking fitting structure to provide sufficient connection strength to ensure the coaxiality. After the quick connect is inserted into place, a tight fit is formed between the guide sleeve and the guide groove. The coaxial locking structure is a key and groove provided on the driving-side housing and the driven-side housing and cooperating with each other. For example, a coaxial locking key <NUM> is formed at one end of the driven-side housing, and a coaxial locking groove <NUM> is provided at one end of the driving-side housing <NUM> Before insertion, the coaxial locking groove <NUM> is in the "on" position. After the coaxial locking key <NUM> is inserted into place, the coaxial locking groove <NUM> is adjusted to the "off" position to complete locking. In addition, a locking ring <NUM> may be further provided on the driven-side housing <NUM>.

With continued reference to <FIG>, the magnetic transmission driving end <NUM> is comprised of a driving rotor <NUM>, a driving rotor spacing sleeve <NUM>, and a driving magnet <NUM>. Herein, the driving rotor <NUM> is a cylinder having a circular rotation space therein, and the inner surface of the cylinder is provided with a groove; the driving rotor spacing sleeve <NUM> is embedded in the circular rotating space, and forms a closed magnet placement groove together with the groove on the inner surface. The magnet placement grooves at the driving end shall be an even number of pairs. When the magnets are placed, they shall be placed in pairs in opposite directions. When the magnets are unfolded in the circumferential direction, the adjacent magnets have opposite polarities. The driving rotor spacing sleeve <NUM> and the driving rotor <NUM> are performed with integral injection moulding during processing to achieve assembly, so as to constitute a magnet accommodating cavity. After the driving magnet <NUM> is placed in the magnet receiving cavity, the adhesive port is closed with the medical grade glue. The other end of the magnetic transmission driving end <NUM> is tightly connected to a driving motor, and the driving motor is fixed in the driving-side housing via a buffering structure. The above-mentioned assembly relationship is a conventional assembly structure, and will not be described in detail herein.

With continued reference to <FIG>, the magnetic transmission driven end <NUM> is comprised of a driven rotor <NUM>, a driven rotor spacing sleeve <NUM>, a driven magnet <NUM>, and a magnet holder <NUM>. Herein, the driven rotor <NUM> is a circular shaft, and the magnet holder <NUM> is an elongated cylinder, has a circular assembly space therein, and is assembled on the driven rotor <NUM>; the driven rotor spacing sleeve <NUM> is a cylinder and is assembled on the magnet holder <NUM>; the magnet holder <NUM> has a groove on its surface, and constitutes a magnet placing groove at the driven end together with the driven rotor <NUM> and the driven rotor spacing sleeve <NUM>. The magnet placing grooves on the driven end shall be an even number of pairs. When the magnets are placed, they shall be placed in pairs in opposite directions. When the magnets are unfolded in the circumferential direction, the adjacent magnets have opposite polarities. The other side of the magnetic transmission driven end <NUM> is fitted with a support bearing (not shown), the support bearing is tightly fitted inside the driven-side inner shell <NUM>, and the driven-side inner shell <NUM> is fixed inside the driven-side outer shell <NUM> via the buffering structure. The above assembly is also a conventional assembly structure and will not be described in detail herein.

In the magnetic coupling structure of the present invention, the magnetic transmission driven end <NUM> and the magnetic transmission driving end <NUM> are separated by a quick-connect spacing sleeve <NUM>. When the transmission structure is applied to the interventional catheter, the magnetic transmission driven end <NUM> on the left side of the quick-connect spacing sleeve <NUM> is located on a catheter and belongs to a sterile area, and the magnetic transmission driving end <NUM> on the right side is located on a power structure and belongs to a non-sterile area.

The magnetic coupling coaxial guide mechanism of the present invention cooperates with the integral coaxial guide mechanism to restrict a small rotation gap between the driving end and the driven end at the inner and outer sides of the quick-connect spacing sleeve <NUM>, so as to ensure the coaxiality of the both ends after the quick-connect insertion and withdrawal, thereby achieving the requirements of high rotation speed and stability. Since the gap between the magnetic transmission driving end <NUM> and the magnetic transmission driven end <NUM> is only <NUM>-<NUM>, the wall thickness of the quick-connect spacing sleeve <NUM> is about <NUM> in a magnetic transmission mating area. The bottom of the quick-connect spacing sleeve <NUM> is assembled and placed with the bottom of the magnetic coupling coaxial guide mechanism. In order to ensure the strength and coaxiality of the assembly part, the wall thickness of the quick-connect spacing sleeve <NUM> is thickened to <NUM> at the assembly position.

In order to achieve a shorter axial mating distance and obtain a greater connection strength, the coaxial guide sleeve <NUM> and the coaxial guide groove <NUM> of the present invention are further provided with a <NUM>% mating taper to achieve insertion guidance while improving the mating strength after insertion into place. There is an offset in the axial direction of the two guide mating structures. When it is inserted quickly, the outer integrated coaxial guide mating structure firstly contacts to perform integrated coarse guide control, and the inner magnetic coupling coaxial guide mating structure continues to be inserted to start contacting to perform precise guide control of the magnetic coupling structure. Furthermore, the two guide mating structures have a length difference while adopting the same taper. Compared with the magnetic coupling coaxial guide mechanism, the length of the integrated coaxial guide mechanism located outside is longer. During the insertion operation, the insertion resistance increases nonlinearly due to the axial offset of the inner and outer structures. The insertion resistance is lower before the magnetic coupling coaxial guide contacts. After the magnetic coupling coaxial guide contacts, the insertion resistance increases rapidly, which can ensure the final mating strength and avoid the high difficulty of fast insertion.

Compared with the magnetic transmission structures in the conventional industry, the present invention is applicable to micro-structures, high rotational speed, and low torque type applications in medical interventional devices. With the magnetic transmission architecture of the present invention, a quick-connect operation is achieved while the overall outer diameter of the structure can be controlled to within <NUM> and stable operation of the structure can be ensured at a maximum magnetic transmission speed of <NUM> RPM.

The present invention firstly converts the dynamic seal of the original transmission shaft into a static seal between the driving end and the driven end by a magnetic transmission. On the one hand, the seal wear is completely avoided and the transmission resistance is reduced. On the other hand, the driven end can be completely sealed so as to ensure the sterility in the catheter after sterilization in clinical application.

Further, the present invention employs a double-guide locking fit structure to achieve quick connection while ensuring a minimal transmission gap. On the one hand, under the condition that the medical catheter is used as a consumable for a single time but the high-value power structure is expected to be used for multiple times, one power driving end can be used with different driven ends for multiple times, which saves the cost of use and improves the reliability of the system because the power structure does not need to be sterilized again. On the other hand, the guide structure stably controls the rotational gap between the driving and driven ends within a very small gap of <NUM>, providing sufficient torque in a small size structure by achieving a smaller controlled magnetic drive gap.

Claim 1:
A quick-connect type magnetic transmission device for a medical interventional instrument, comprising a driving-side housing and a driven-side housing, the driven-side housing including a driven-side outer shell (<NUM>) and a driven-side inner shell (<NUM>), wherein
the driving-side housing and the driven-side housing are coaxially arranged and nested and connected, and the quick-connection type magnetic transmission device comprises a magnetic coupling structure, a magnetic coupling coaxial guide mechanism and an integral coaxial guide mechanism successively from inside to outside; the magnetic coupling structure is composed of a magnetic transmission driving end (<NUM>), a magnetic transmission driven end (<NUM>) and a quick-connect spacing sleeve (<NUM>); the magnetic coupling coaxial guide mechanism is composed of a magnetic coupling guide sleeve (<NUM>) and a magnetic coupling guide groove (<NUM>); and the integral coaxial guide mechanism is composed of a coaxial guide sleeve (<NUM>), a coaxial guide groove (<NUM>) and a coaxial locking structure;
the magnetic transmission driven end (<NUM>) comprises a driven rotor spacing sleeve (<NUM>); the coaxial guide groove (<NUM>) is composed of an annular space between the inner wall of the driven-side outer shell (<NUM>) and the outer wall of the driven-side inner shell (<NUM>); the magnetic coupling guide groove (<NUM>) is composed of a space between the inner wall of the driven-side inner shell (<NUM>) and the outer wall of the driven rotor spacing sleeve (<NUM>); the inner wall surface of the driven-side inner shell (<NUM>) is tightly fitted with the outer wall surface of the magnetic coupling guide sleeve (<NUM>); and the magnetic transmission driving end (<NUM>) is provided between the outer wall surface of the driven rotor spacing sleeve (<NUM>) and the inner wall surface of the magnetic coupling guide sleeve (<NUM>);
the coaxial locking structure is a key and groove provided on the driving-side housing and the driven-side housing and cooperating with each other.