DE102018207578A1 - Method for producing a cylindrical permanent magnet and method for producing radial couplings - Google Patents

Abstract

The invention relates to a method (500) for producing a radial coupling, in particular for ventricular cardiac assist pumps. The invention further relates to a method (300) for producing a cylindrical permanent magnet (102, 104).

Description

The present invention relates to a method for producing a cylindrical permanent magnet and to two methods for producing a respective radial coupling.

State of the art

In the prior art, magnetic couplings are known in which concentrically arranged inside one another magnets or magnet pairs are used to transmit torques without contact. These so-called radial rotary joints or central rotary joints have one or more pairs of poles, preferably have a magnetic yoke and preferably have a radial, parallel, diametral magnetization or Halbach arrangement. Here, the field lines are usually oriented substantially radially. The function of this clutch is the transmission of torque through a coaxial arrangement of the outer and inner magnet systems. These couplings are radially unstable, but have a bearing function in the axial direction. By axial offset from a concentric layer creates an axial force that can be used to storage functionality. In arrangements with a higher number of pole pairs, with the same dimensions of the coupling, the transmittable torque increases, while the axial force decreases, especially with very small dimensions of the coupling.

In order to produce such couplings, especially in small dimensions with a high number of pole pairs, very small magnet segments must be made with very high manufacturing tolerance. In this case, the joining of the segments to one another can be very complicated in order to produce the desired magnetic field.

Disclosure of the invention

The method for producing a cylindrical permanent magnet of a permanent magnetic radial coupling has, as a first step, the provision of a cylindrical body to be magnetized.

The word production can also be understood as production or preparation in this case. Here, preparation refers to the body to be magnetized, which is provided according to the method.

Permanent magnetic radial rotary joints are used in a variety of miniature pumps, e.g. Blood pumps, ventricular cardiac assist pumps, in miniature axial pumps in general and especially in the medical field, also in drives or tools of all kinds, especially in metering or micropumps for driving impeller-shaped wheels.

The body comprises or consists of a hard magnetic material. This may be, for example, a ferrimagnetic or ferromagnetic material.

In the second step of the method, a cylindrical magnetization device is provided, wherein the cylindrical body and the cylindrical magnetization device are arranged coaxially.

The magnetization device serves to permanently magnetize the hard magnetic body. The magnetization device is set up and designed to generate such a magnetic field which can permanently magnetize the cylindrical body with at least one pole pair.

According to a preferred embodiment, the cylindrical body is located in the axial direction between the two axial ends of the cylindrical magnetization device. As a result, it is advantageously achieved that the magnetic field generated by the magnetization device is comparatively homogeneous along the axial extent of the cylindrical body.

The larger of the two objects seen in the radial direction, i. of the cylindrical body and the magnetizing device is hollow cylindrical, wherein the smaller of the two bodies is arranged during the magnetization in the interior of the hollow cylindrical article.

The third step of the method is to generate a magnetic field by means of the magnetization device so that the cylindrical body to be magnetized is magnetized so that it is a permanent magnet with at least one pair of poles.

The generation of the magnetic field takes place for a predetermined period of time. According to a preferred embodiment of the method, the magnetization device is removed after the third step, so as to obtain the cylindrical permanent magnet.

In the embodiment with only one pair of poles, the magnetization can also be performed diametrically on magnetic hollow cylinders or, in the case of the radially smaller, inner part, also on a solid cylinder.

The first and the second step of the method can be carried out in any time sequence.

The method advantageously achieves that a cylindrical permanent magnet of a permanent magnetic radial coupling can be produced robustly and inexpensively.

According to a preferred embodiment, an outer diameter of the second permanent magnet is less than 10 mm, more preferably less than 8 mm and most preferably less than 6 mm. As a result, heart pumps or heart support systems (English: VAD, Ventricular Assist Device) can be advantageously made with extremely small dimensions.

This feature advantageously achieves that in the production of the radial coupling of a permanent magnetic radial coupling whose dimensions are very small, to dispense with a segmentation of the permanent magnet and still a high magnetic flux density can be achieved. This is achieved primarily by the use of cylindrical bodies of hard magnetic material and the magnetizing device.

According to a preferred embodiment, the inner diameter of the magnetization device is greater than the outer diameter of the cylindrical body. In this case, the magnetizing device is hollow cylindrical and the cylindrical body is inside the magnetizing device.

According to a further preferred embodiment, the outer diameter of the magnetization device is smaller than the inner diameter of the cylindrical body. In this case, the cylindrical body is hollow cylindrical and the magnetizing device is located inside the cylindrical body.

According to a first method for producing a radial coupling, both a first cylindrical permanent magnet and a second hollow cylindrical permanent magnet are produced according to the method described above. Here, the inner diameter of the second permanent magnet is larger than the outer diameter of the first permanent magnet.

According to a third step of the method of manufacturing the radial coupling, the first cylindrical permanent magnet and the second hollow cylindrical permanent magnet are arranged so that the first permanent magnet and the second permanent magnet are coaxially arranged, the first permanent magnet and the second permanent magnet at least partially axially overlap each other the first permanent magnet and the second permanent magnet are rotatably mounted about the common axis, both the first permanent magnet and the second permanent magnet having at least one pole pair, and the first permanent magnet having the same number of pole pairs as the second permanent magnet. Preferably, the term arranging means assembly or assembly.

It follows in general that there is an axial offset between an axial center of the first permanent magnet and an axial center of the second permanent magnet. For generating axial bearing functionality, the axial offset between the first and the second permanent magnet can be set or the axial length of the first and the second permanent magnet can be designed differently.

The method advantageously achieves that a cylindrical permanent magnet of a permanent magnetic radial coupling can be produced robustly and inexpensively.

The method is advantageously particularly suitable for radial couplings which have very small dimensions in the gap, since in this case it may be necessary to fix the first and the second body, i. the two coupling parts to be magnetized separately from each other.

If the first and second bodies are magnetized separately from each other, the same magnetization apparatus can be used for both operations. According to another embodiment, combinations of the coupling parts, optionally the inner or outer part, with otherwise magnetized coupling parts, e.g. in execution as Halbach array, possible.

According to a second method of manufacturing a radial coupling, in a first step, a first cylindrical body to be magnetized and a second hollow cylindrical body to be magnetized are arranged so that the first body and the second body are coaxially arranged, the inner diameter of the second body being larger than the outer diameter of the first body, the first body and the second body at least partially axially overlap, both the first body and the second body are rotatably mounted about the common axis.

Furthermore, the first cylindrical body to be magnetized and the second hollow cylindrical body to be magnetized are arranged such that between the outer diameter of the first Body and the inner diameter of the second body, a hollow cylindrical magnetization device can be arranged.

According to a second step of the second method for producing a radial coupling, the magnetization device is arranged so that the magnetization device is located radially between the outer diameter of the first body and the inner diameter of the second body and both the first body and the second body in the axial direction between located at the two axial ends of the magnetizing device.

According to a second step of the second method of manufacturing a radial coupling, a magnetic field is generated by means of the magnetizing device so that both the first body to be magnetized and the second body to be magnetized are magnetized to be permanent magnets.

Here, both the first permanent magnet and the second permanent magnet on at least one pole pair, wherein the first permanent magnet has the same number of pole pairs as the second permanent magnet.

The generation of the magnetic field takes place for a predetermined period of time. According to a preferred embodiment of the method, the magnetization device is removed after the third step, so as to obtain the permanent magnetic radial coupling.

The method advantageously achieves that a cylindrical permanent magnet of a permanent magnetic radial coupling can be produced robustly and inexpensively.

According to a preferred embodiment, the magnetization device is an electromagnet, which is designed and arranged such that it can generate a magnetic field, which is such that the first body to be magnetized and / or the second body to be magnetized are magnetized according to the Magnetization of the first permanent magnet and / or the second permanent magnet has at least one pair of poles.

The magnetizing device is preferably an electromagnet, which is preferably produced by means of the coil winding technique. The electromagnet preferably has coils wound from electrical wires. It is further preferred that the electromagnet has a soft magnetic yoke. The design of the magnetization device determines the pole pair number and the direction of the magnetic field in the magnetic rings.

The magnetization device can generate an arbitrary magnetic field within certain limits.

By this feature is advantageously achieved that the first and / or second body can be magnetized in a simple manner so that the first and / or second permanent magnet having a predetermined number of pole pairs.

According to a preferred embodiment, the first permanent magnet and / or the second permanent magnet on a radial, parallel or diametrical magnetization. These are customary types of magnetization, which the person skilled in the art can adapt to the given circumstances of the individual case.

According to a preferred embodiment, the first permanent magnet and / or the second permanent magnet to a permanent magnet, which has a Halbach arrangement or is. Preferably, the first permanent magnet and / or the second permanent magnet is or is a permanent magnet which has or is a Halbach arrangement. By this feature is advantageously achieved that the magnetic flux can be concentrated on one side of the Halbach arrangement (strong side). This is particularly advantageous in the case of the second permanent magnet, which is arranged on the outside, wherein the strong side of the Halbach arrangement of the second Pannenmagneten is directed to the first permanent magnet.

According to a preferred embodiment, the second permanent magnet has a device for magnetic inference. In this case, this device is preferably arranged on the outside of the second permanent magnet. In addition to manufacturing advantages, this advantageously achieves that the torque of the clutch is increased, since less stray fields are lost.

Particularly preferably, an axial length of the first permanent magnet is the same size as an axial length of the second permanent magnet. Further, it is preferable that the respective ends of the first and second permanent magnets are in the same position when viewed in the axial direction.

list of figures

• 1A und 1B zeigen jeweils eine Anordnung eines ersten zu magnetisierenden Körpers, eines zweiten zu magnetisierenden Körpers sowie einer Magnetisierungsvorrichtung, welche zwischen dem ersten Körper und dem zweiten Körper eingebracht wurde, wobei die Anordnung während der Durchführung eines Verfahrens gemäß einer Ausführungsform der Erfindung erhalten wird. 1A zeigt eine Schnittzeichnung entlang einer Längsachse der Anordnung und 1B zeigt eine Seitenansicht der Anordnung.
• 2 zeigt eine Radialkupplung, welche gemäß einem Verfahren zur Herstellung einer Radialkupplung gemäß einer Ausführungsform der Erfindung hergestellt wurde.
• 3 zeigt ein schematisches Ablaufdiagramm eines Verfahrens zur Herstellung eines zylinderförmigen Permanentmagneten einer permanentmagnetischen Radialkupplung gemäß einer Ausführungsform.
• 4 zeigt ein schematisches Ablaufdiagramm eines Verfahrens zur Herstellung einer Radialkupplung gemäß einer Ausführungsform.
• 5 zeigt ein schematisches Ablaufdiagramm eines Verfahrens zur Herstellung einer Radialkupplung gemäß einer weiteren Ausführungsform.

Embodiments of the invention are illustrated in the drawings and are explained in more detail in the following description.

• 1A and 1B each show an arrangement of a first body to be magnetized, a second body to be magnetized and a magnetization device which has been introduced between the first body and the second body, wherein the arrangement is obtained during the implementation of a method according to an embodiment of the invention. 1A shows a sectional view along a longitudinal axis of the arrangement and 1B shows a side view of the arrangement.
• 2 shows a radial coupling, which was prepared according to a method for producing a radial coupling according to an embodiment of the invention.
• 3 shows a schematic flow diagram of a method for producing a cylindrical permanent magnet of a permanent magnetic radial coupling according to an embodiment.
• 4 shows a schematic flow diagram of a method for producing a radial coupling according to an embodiment.
• 5 shows a schematic flow diagram of a method for producing a radial coupling according to another embodiment.

Embodiments of the invention

1A shows an arrangement 100 a first cylindrical body to be magnetized 112 , a second hollow cylindrical body to be magnetized 114 and a magnetizing device 170 , which according to the method for producing a radial coupling between the first body 112 and the second body 114 was introduced.

The inner diameter of the magnetizing device 170 is larger than the outer diameter of the first cylindrical body 112 , The outer diameter of the magnetization device 170 is smaller than the inner diameter of the second cylindrical body 114 , Both the first cylindrical body 112 as well as the second cylindrical body 114 are each in the axial direction between the two axial ends 171 . 172 the cylindrical magnetization device 170 , Here is the first cylindrical body 112 along the axial direction exactly the same length as the second cylindrical body 114 and the respective ends of the first body 112 as well as the second body 114 are located axially in the same place.

The first cylindrical body 112 is on a wave 106 arranged, which is about an axis 105 is rotatably mounted.

Both the first cylindrical body 112 as well as the second cylindrical body 114 are each with the cylindrical magnetization device 170 arranged coaxially.

Both the first cylindrical body 112 as well as the second cylindrical body 114 are about the common axis 105 rotatably mounted.

The wave 106 serves to drive the first body 112 , which after successful magnetization to the first permanent magnet 102 becomes. One with the second body 114 connected shaft, which serves the output, is not shown here.

1 shows the state in which the magnetizing device 170 the first body 112 and the second body 114 magnetized. After successful magnetization are the first body 112 and the second body 114 each to the first permanent magnet 102 and the second permanent magnet 104 magnetized. This latter state is without the magnetization device 170 in 2 shown.

In 1 is also that of the magnetization device 170 generated magnetic field by field lines 173 , which have arrows, drawn. At the field lines 173 in the 3 o'clock and the 9 o'clock position flows in the magnetizing device 170 the current out of the plane of the drawing, which is indicated by dots, and in the 6 o'clock and 12 o'clock positions, flows in the magnetizing device 170 the current into the drawing plane, which is indicated by crosses. Here, the technical current direction is used.

The resulting magnetic field is through the field lines 173 specified. The resulting magnetic field is such that both in the first body 112 as well as in the second body 114 two pole pairs are magnetized.

2 shows a radial coupling 101 , which was produced according to a method for producing a radial coupling. 2 shows a sectional view of the radial coupling 101 , The radial coupling 101 has a first permanent magnet 102 and a second permanent magnet 104 on. Both the first permanent magnet 102 as well as the second permanent magnet 104 each have two pole pairs, ie four poles, which are each radially magnetized. Based on the marked field lines 173 can be seen that the four poles in the first permanent magnet 102 as well as in the second permanent magnet 104 each in the middle between the 12 o'clock and the 3 o'clock position, between the 3 o'clock and the 6 o'clock position, between the 6 o'clock and the 9 o'clock position and between the 9 o'clock and the 9 o'clock position 12 o'clock position.

3 shows a schematic flow diagram of a method 300 for producing a cylindrical permanent magnet 102 . 104 a permanent magnetic radial coupling 101 ,

The procedure 300 starts in step 310 in that a cylindrical body to be magnetized 112 . 114 provided.

In the following step 315 it is queried whether the inner diameter of a magnetization device 170 , which the cylindrical body to be magnetized 112 . 114 will magnetize larger than the outer diameter of the cylindrical body 112 . 114 or otherwise, the outer diameter of the magnetizing device 170 smaller than the inner diameter of the cylindrical body 112 . 114 is.

This decision depends on whether the body to be magnetized 112 . 114 an internal permanent magnet 102 the radial coupling 101 or an outboard permanent magnet 104 the radial coupling 101 is.

If the inner diameter of a magnetization device 170 larger than the outer diameter of the cylindrical body 112 . 114 is, then the method goes to step 321 in which the cylindrical magnetization device 170 provided. Here, the hook in 3 an affirmation of the query and the cross a denial. Here is the cylindrical body 112 . 114 the first body 112 , Further, the first body 112 and the cylindrical magnetization device 170 arranged coaxially.

If the outer diameter of the magnetizing device 170 smaller than the inner diameter of the cylindrical body 112 . 114 is, then the method goes to step 322 in which the cylindrical magnetization device 170 is provided, wherein the cylindrical body 112 . 114 the second body 112 is and the first body 112 and the cylindrical magnetization device 170 are arranged coaxially.

The steps 321 and 322 make the step together 320 ,

After step 321 the procedure goes to step 331 in which a magnetic field using the magnetizing device 170 is generated, so that the cylindrical to be magnetized first body 112 is magnetized so that it becomes the first permanent magnet 102 becomes.

After step 322 the procedure goes to step 332 in which a magnetic field using the magnetizing device 170 is generated, so that the cylindrical second body to be magnetized 114 is magnetized so that it becomes the second permanent magnet 104 becomes.

The steps 331 and 332 make the step together 330 ,

Each after step 331 or step 332 the procedure ends 300 ,

During the procedure, both the first body is located 112 or the first permanent magnet 102 as well as the second body 114 or the second permanent magnet 104 in the axial direction between the two axial ends 171 . 172 the cylindrical magnetization device 170 ,

4 shows a schematic flow diagram of a method 400 for producing a radial coupling 101 ,

The procedure starts in step 410 in that a first cylindrical permanent magnet 102 according to the method 300 will be produced.

In the following step 420 becomes a second cylindrical permanent magnet 104 according to the method 300 produced.

Here, the inner diameter of the second permanent magnet 104 larger than the outer diameter of the first permanent magnet 102 ,

Both the first permanent magnet 102 as well as the second permanent magnet 104 has two pole pairs each.

In the next step 430 becomes the first cylindrical permanent magnet 102 and the second hollow cylindrical permanent magnet 104 arranged so that the first permanent magnet 102 and the second permanent magnet 104 are arranged coaxially.

Here are the respective ends of the first permanent magnet 102 and second permanent magnets 104 seen in the axial direction in the same place. Further, both the first permanent magnet 102 as well as the second permanent magnet 104 around the common axis 105 rotatably mounted.

Thus, the radial clutch became 101 completed.

5 shows a schematic flow diagram of another method 500 for producing a radial coupling 101 ,

The procedure 500 starts with step 510 in which a first cylindrical body to be magnetized 112 and a second hollow cylindrical body to be magnetized 114 be arranged coaxially. Here, the inner diameter of the second body 114 larger than the outer diameter of the first body 112 ,

Both the first body 112 as well as the second body 114 are about the common axis 105 rotatably mounted and are located in the same place seen in the axial direction. Here is an axial length of the first body 112 equal to an axial length of the second body 114 ,

Further, the first body 112 and the second body 114 arranged so that between the outer diameter of the first body 102 and the inner diameter of the second body 104 a hollow cylindrical magnetization device 170 can be arranged.

In the following step 520 becomes the magnetization device 170 arranged so that the magnetization device 170 radially between the outer diameter of the first body 102 and the inner diameter of the second body 104 is located and both the first body 112 as well as the second body 114 in the axial direction between the two axial ends 171 . 172 the magnetization device 170 located.

In the next step 530 is using the magnetization device 170 generates a magnetic field, so that both the first body to be magnetized 112 as well as the second body to be magnetized 114 are magnetized so that they are permanent magnets.

The magnetization device 170 Here is an electromagnet with a soft magnetic yoke, which is designed and arranged so that it can generate a magnetic field, which is such that the first body to be magnetized 112 and the second body to be magnetized 114 be magnetized so that after the magnetization of the first permanent magnet 102 and the second permanent magnet 104 two pairs of poles, ie four poles, as in 2 shown.

In step 530 the magnetic field is generated for a predetermined period of time.

After the magnetization is finished and the magnetic field has disappeared, the first body is 112 to the first permanent magnet 102 become and the second body 114 to the second permanent magnet 104 become.

The first permanent magnet 102 and the second permanent magnet 104 each have a radial magnetization. Further, an axial length of the first permanent magnet 102 the same size as an axial length of the second permanent magnet 104 ,

In the following step 540 becomes the magnetization device 170 removed, causing the radial clutch 101 is obtained.

Claims (10)

Method (300) for producing a cylindrical permanent magnet (102, 104) of a permanent magnetic radial coupling (101) with the following steps: Providing (310) a cylindrical body (112, 114) to be magnetized; Providing (320) a cylindrical magnetization device (170), wherein the cylindrical body (112, 114) and the cylindrical magnetization device (170) are arranged coaxially; and Generating (330) a magnetic field using the magnetization device (170) so that the cylindrical magnetizable body (112, 114) is magnetized to be a permanent magnet (102, 104) having at least one pole pair. Method (300) according to Claim 1 , characterized in that the inner diameter of the magnetization device (170) is greater than the outer diameter of the cylindrical body (112, 114). Method (300) according to Claim 1 , characterized in that the outer diameter of the magnetization device (170) is smaller than the inner diameter of the cylindrical body (112, 114). Method (300) according to one of the preceding claims, characterized in that the cylindrical body (112, 114) is located in the axial direction between the two axial ends (171, 172) of the cylindrical magnetization device (170). Method (400) for producing a radial coupling (101) comprising the following steps: producing (410) a first cylindrical permanent magnet (102) according to a method of Claims 1 to 4 ; Producing (420) a second hollow cylindrical permanent magnet (104) according to a method of Claims 1 to 4 . wherein the inner diameter of the second permanent magnet (104) is larger than the outer diameter of the first permanent magnet (102); Arranging (430) the first cylindrical permanent magnet (102) and the second hollow cylindrical permanent magnet (104) such that the first permanent magnet (102) and the second permanent magnet (104) are coaxially disposed, the first permanent magnet (102) and the second permanent magnet (104) overlap at least partially axially, both the first permanent magnet (102) and the second permanent magnet (104) are rotatably mounted about the common axis (105); both the first permanent magnet (102) and the second permanent magnet (104) have at least one pole pair; and the first permanent magnet (102) has the same number of pole pairs as the second permanent magnet (104). Method (500) for producing a radial coupling (101) with the following steps: Arranging (510) a first cylindrical magnetizable body (112) and a second hollow cylindrical magnetizable body (114), wherein the first (112) body and the second body (114) are coaxially arranged, the inner diameter of the second body (114) greater than the outer diameter of the first body (112), the first body (112) and the second body (114) overlap at least partially axially; both the first (112) body and the second body (114) are rotatably mounted about the common axis (105); and between the outer diameter of the first body (102) and the inner diameter of the second body (104) a hollow cylindrical magnetization device (170) can be arranged; Arranging (520) the magnetization device so that the magnetization device (170) is located radially between the outer diameter of the first body (102) and the inner diameter of the second body (104) and both the first body (112) and the second body ( 114) in the axial direction between the two axial ends (171, 172) of the magnetization device (170); Generating (530) a magnetic field using the magnetization device (170) such that both the first body (112) to be magnetized and the second body (114) to be magnetized are magnetized to be permanent magnets; both the first permanent magnet (102) and the second permanent magnet (104) have at least one pole pair; and the first permanent magnet (102) has the same number of pole pairs as the second permanent magnet (104). Method (400, 500) after Claim 5 or 6 , characterized in that the magnetization device (170) is an electromagnet which is designed and arranged such that it can generate a magnetic field which is such that the first body to be magnetized (112) and / or the second body to be magnetized (114) are magnetized so that after the magnetization of the first permanent magnet (102) and / or the second permanent magnet (104) has at least one pair of poles. Method (400, 500) after Claim 5 . 6 or 7 , characterized in that the first permanent magnet (102) and / or the second permanent magnet (104) has a radial, parallel or diametrical magnetization. Method (400, 500) according to one of Claims 5 to 8th , characterized in that the first permanent magnet (102) and / or the second permanent magnet (104) comprises a permanent magnet having a Halbach arrangement. Method (400, 500) according to one of Claims 5 to 9 , characterized in that an axial length of the first permanent magnet (102) is equal to an axial length of the second permanent magnet (104).

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