JP3622041B2 - Superconducting bearing device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a superconducting bearing device applied to, for example, a fluid machine or machine tool that requires high-speed rotation, or a power storage device that converts surplus power into kinetic energy of a flywheel for storage.
[0002]
[Prior art]
The present applicant, as a superconducting bearing device capable of stably supporting rotation with a simple configuration, comprises a permanent magnet attached to a rotating body, and a type 2 superconductor disposed so as to face the permanent magnet, The permanent magnet is attached to the rotating body so that the magnetic flux distribution around the rotating shaft of the rotating body is not changed by rotation, and the superconductor allows the permanent magnet to enter the magnetic flux. There has been proposed a disposition at a position where the intrusion magnetic flux does not change due to the rotation of the rotating body (see JP-A-4-78316).
[0003]
Before starting the operation of this superconducting bearing device, there is no mechanism for determining the relative position between the superconductor and the magnetic bearing. There was a problem of poor operating efficiency.
[0004]
Therefore, the applicant further supports the rotating body in a non-contact state with respect to the fixed portion by the superconducting bearing as described above, and the relative position so that the former is located between the fixed portion and the rotating body. A touch-down bearing composed of a thrust ball bearing is arranged on the opposite part, and the bearing ring on the fixed part side of the touch-down bearing is lifted and fixed between the fixed part and the rotating body. There has been proposed a superconducting bearing device provided with an initial positioning mechanism for setting a relative position between a portion and a rotating body (see Japanese Patent Publication No. 6-100225).
[0005]
According to this superconducting bearing device, an efficient operation can be performed by appropriately setting the relative position of the fixed portion and the rotating body by the initial positioning mechanism before operation as follows.
[0006]
First, the rotating body is lifted to a position slightly above the operating position by the initial positioning mechanism, and the permanent magnet and the superconductor of the superconducting bearing are opposed to each other. At this time, the superconductor is kept in a normal conducting state at room temperature. Even when the permanent magnet of the superconducting bearing and the superconductor face each other, the superconductor is in a normal conducting state, so the superconducting bearing is in a non-operating state where no supporting force is generated, and the magnetic flux generated from the permanent magnet is in the normal conducting state. Intrudes into the superconductor. Next, the superconductor is cooled to a predetermined temperature and held in a superconducting state in which the type 2 superconducting state appears. As a result, the superconducting bearing enters an operating state in which a supporting force is generated, and the rotating body is supported by the superconducting bearing in the axial and radial directions. That is, if the superconductor is cooled (magnetic field cooling) in a superconducting state while the magnetic flux generated from the permanent magnet has entered the superconductor, much of the magnetic flux that has entered the superconductor remains as it is. It is restrained inside the superconductor and pinned (pinning phenomenon). Here, since the type 2 superconductor is a mixture of normal conducting particles uniformly in the inside thereof, the distribution of the magnetic flux penetrating into the superconductor becomes constant, so that it is as if the pin is erected on the superconductor. The permanent magnet is penetrated, and the rotating body is restrained together with the permanent magnet with respect to the superconductor. Therefore, even if the support by the initial positioning mechanism is lost, the rotating body is supported in the axial direction and the radial direction in a state where it floats very stably. If the superconducting bearing is brought into an operating state in this way, the support of the rotating body by the initial positioning mechanism is eliminated. Then, the rotating body descends to the operating position by its own weight, but thereafter, it is supported in a non-contact manner in the axial and radial directions by the superconducting bearing as described above. When the rotating body is supported by the superconducting bearing in this way, the rotating body is rotated by the electric motor and the operation is started.
[0007]
However, in the superconducting bearing device described above, it is necessary to move the rotating body above the operating position before the operation is started, and it is necessary to lengthen the rotating body by the moving stroke. And when a rotary body becomes long, the natural frequency of a rotary body will fall and the maximum rotational speed of a rotary body will become low.
[0008]
In addition, during operation, the magnetic levitation force due to the superconducting bearing decreases due to the magnetic flux creep of the superconductor with time, and the position of the rotating body gradually falls down and finally touches down. When touchdown occurs in this way, it is necessary to stop the rotating body and restart the operation by performing initial positioning of the rotating body as described above, and the work for restarting the operation is very troublesome. . Moreover, if the touchdown is performed many times, the touchdown bearing is damaged.
[0009]
[Problems to be solved by the invention]
An object of the present invention is to provide a superconducting bearing device that can solve the above problems, shorten the rotating body to increase the maximum rotational speed, and can be continuously operated for a long time without touchdown. It is to provide.
[0010]
[Means for Solving the Problems and Effects of the Invention]
A superconducting bearing device according to the present invention detects a displacement of a rotating body arranged vertically in a fixed part, a superconducting bearing that supports the rotating body in at least an axial direction and floats in a non-contact manner, and a radial direction of the rotating body. A radial displacement sensor for detecting the displacement of the rotating body at a predetermined position in the radial direction in a non-contact manner, an axial displacement sensor for detecting an axial displacement of the rotating body, and the rotating body as necessary Is controlled in a non-contact manner at a predetermined position in the axial direction, and the radial magnetic bearing, the axial magnetic bearing, and the superconducting bearing are controlled based on output signals of the radial displacement sensor and the axial displacement sensor. A control device, and an electric motor that rotationally drives the rotating body. A permanent magnet attached to the lower end of the rotating body, and a superconductor attached to a lifting member provided on the fixed portion below the rotating body so as to be movable up and down so as to face the permanent magnet. The control device determines the vertical position of the elevating member based on the output of the axial displacement sensor in a state where the rotating body is rotating while being supported in a non-contact manner by the radial magnetic bearing and the superconducting bearing. By controlling, the rotating body is supported at a predetermined stable rotating position, and when the control of the position of the rotating body by the control of the position of the elevating member reaches a limit, the axial magnetic bearing is operated to move the rotating body to the It is designed to be supported at a stable rotational position.
[0011]
For example, the superconductor is a type 2 superconductor which has a property of appearing in a second type superconducting state by cooling and restraining intrusion magnetic flux and pinning in the second type superconducting state, and the superconducting bearing. However, the rotating body is supported in a non-contact manner in the axial direction and the radial direction by the pinning force of the superconductor. In this case, the permanent magnet of the superconducting bearing is attached to the rotating body so that the magnetic flux distribution around the rotating shaft of the rotating body does not change by rotation, and the second type superconductor has a predetermined amount of magnetic flux of the permanent magnet invading. It is arranged at a position where the distribution of the intrusion magnetic flux does not change due to the rotation of the rotating body.
[0012]
When the superconducting bearing uses a type 2 superconductor, for example, the operation of the superconducting magnetic bearing device is started as follows.
[0013]
First, with the electric motor stopped, the rotating body is supported non-contactingly in the radial direction (horizontal direction) by the radial magnetic bearing and non-contactingly supported in the axial direction (vertical direction) by the axial magnetic bearing. On the other hand, it floats to a predetermined operation position (stable rotation position). An axial magnetic bearing is usually provided with a pair of upper and lower electromagnets that attract and hold the rotor flange from both sides in the axial direction, and each electromagnet is excited to attract the flange from the magnetic bearing controller. Current is supplied. When the rotating body is lifted to the operating position as described above, since the weight of the rotating body is supported only by the axial magnetic bearing, the upward attracting force by the upper electromagnet becomes the downward attracting force by the lower electromagnet. Compared with the weight of the rotating body, the axial magnetic bearing as a whole generates an upward attractive force. Also, at this time, the superconductor on the fixed portion side of the superconducting bearing is kept in a normal conducting state at room temperature, the elevating member is lowered, and the superconductor is sufficiently separated downward from the permanent magnet on the rotating body side of the superconducting bearing ( It is lowered to a position where it is hardly affected by the magnetic flux of the permanent magnet. At this position, the superconductor is cooled to a predetermined temperature and held in a superconducting state in which the type 2 superconducting state appears. Next, in a state where the rotating body is held at the operating position by the axial magnetic bearing and the radial magnetic bearing, the elevating member is raised, and the superconductor is raised to a position facing the permanent magnet with a predetermined gap. Then, a part of the magnetic flux generated from the permanent magnet partially penetrates into the superconductor, and this entered magnetic flux is pinned to the pinning point inside the superconductor. Next, the elevating member is raised to raise the superconductor. When the superconductor of the superconducting bearing in the operating state is lifted while the rotating body is held at the operating position by the axial magnetic bearing, the axially upward supporting force by the superconducting bearing gradually increases, and accordingly, the axial magnetic The bearing force by the bearing gradually decreases. That is, the upward attracting force by the upper electromagnet of the axial magnetic bearing gradually decreases, and the downward attracting force by the lower electromagnet gradually increases, and the upward attracting force of the entire axial magnetic bearing gradually increases. Becomes smaller. Then, the upward attracting force by the upper electromagnet of the axial magnetic bearing and the downward attracting force by the lower electromagnet are equal to each other, and the upward attracting force of the entire axial magnetic bearing, that is, the supporting force in the axial direction becomes zero. At that time, the elevating member is stopped and the superconductor is stopped. And the supply of the excitation current with respect to the electromagnet of an axial magnetic bearing is stopped, and this is made into a non-operation state. Accordingly, the weight of the rotating body is supported only by the superconducting bearing, and the rotating body is supported in a non-contact manner at the operating position by the superconducting bearing and the radial magnetic bearing. When the rotating body is thus supported by the superconducting bearing and the radial magnetic bearing, the electric motor is driven. As a result, the superconducting bearing device starts operation, and the rotating body is rotated while being held at the operating position by the superconducting bearing and the radial magnetic bearing.
[0014]
In this case, the rotating body is supported in the radial direction slightly even by the superconducting bearing using the type 2 superconductor. Therefore, the supporting force by the radial magnetic bearing can be reduced accordingly, and the radial magnetic bearing can be downsized. Can do. Needless to say, this effect is great when the superconductor is cooled in the vicinity of the permanent magnet in its magnetic field.
[0015]
As described above, the rotating body is held at the operating position by the axial magnetic bearing and the radial magnetic bearing from the beginning, and is kept at the operating position by the superconducting bearing, so it is necessary to lift the rotating body once above the operating position as in the past. There is no. Therefore, the length of the rotating body can be shortened accordingly.
[0016]
During operation, the magnetic levitation force due to the superconducting bearing may decrease due to magnetic flux creep of the superconductor with time, and the position of the rotating body may gradually fall from the operating position. In that case, the amount of displacement of the rotating body is detected by an axial displacement sensor, and the lifting member and the superconductor are raised by that amount, and feedback control is performed to keep the rotating body at the operating position. This control is possible until the elevating member reaches a predetermined ascent limit position, and after that, it is inevitable that the rotating body is lowered to a predetermined ascent limit position. However, when the rotating body is lowered from the lower limit position, the axial magnetic bearing is operated, and the rotating body is again held at the operating position by the axial magnetic bearing. At this time, the rotating body continues to rotate. The lower limit position is set above the position where the rotating body touches down. Therefore, before the rotating body touches down, the rotating body is rotated and supported by the axial magnetic bearing at the operating position. can do. Then, in a state where the rotating body is held and rotated by the axial magnetic bearing and the radial magnetic bearing, the superconductor is lowered and again brought into the complete second type superconducting state, and then, at the same time as the start of the operation, The superconductivity is raised, the weight of the rotating body is supported only by the superconducting bearing, and the axial magnetic bearing is deactivated. Thereby, the operation of the superconducting bearing device is resumed, and the rotating body is again supported by the operating position by the superconducting bearing and the radial magnetic bearing, and continues to rotate. In this way, even if the magnetic levitation force due to the superconducting bearing is reduced and the position of the rotating body is lowered, before the touch down, the axial magnetic bearing is used and the operation is resumed while the rotating body is rotated. can do. Therefore, it is possible to drive continuously for a long time without touching down the rotating body.
[0017]
In the above control process in which the elevating member is raised to prevent the rotating body from descending in order to keep the rotating body at a predetermined operating position, if vibration in the axial direction of the rotating body during operation occurs, it is suppressed. Therefore, even during operation, it is possible to operate the axial magnetic bearing and control the electromagnet by passing a control current or a control current and a bias current smaller than a normal steady current.
[0018]
In order to reduce the decrease in the magnetic levitation force of the superconducting bearing during operation, a preload exceeding the load is applied in advance before applying a load (weight of the rotating body) to the superconducting bearing (preload). Is desirable. In that case, when the superconductor is raised by the elevating member and a load is applied to the superconducting bearing, the axial magnetic bearing is immediately deactivated when the upper and lower electromagnet attracting forces of the axial magnetic bearing become equal. Instead, the preload can be applied by leaving the superconductor as it is and raising the superconductor a predetermined distance and then lowering it. When the supporting force of the axial magnetic bearing becomes zero, the axial magnetic bearing is deactivated, the weight of the rotating body is supported only by the superconducting bearing, and the rotation is started.
[0019]
The superconducting bearing uses a type 1 superconductor that appears in the first superconducting state by cooling, and uses the complete diamagnetic phenomenon (Meissner effect) in the first type superconducting state of the first type superconductor to rotate the rotating body. However, the present invention can also be applied to a superconducting bearing device using such a first type superconductor. In that case, the superconducting bearing supports the rotating body only in the axial direction, and the rotating body is supported in the radial direction only by the radial magnetic bearing.
[0020]
In this case, the operation can be started in substantially the same manner as described above, and even if the magnetic levitation force due to the superconducting bearing is reduced and the position of the rotating body is lowered, the rotating body is rotated without touching down. The operation can be resumed.
[0021]
According to the superconducting bearing device of the present invention, as described above, the length of the rotating body can be shortened, and therefore, the natural frequency of the rotating body is not lowered and high-speed rotation is possible. In addition, the rotating body can be continuously rotated for a long time without touching down. Therefore, a troublesome operation resuming operation as in the conventional case is not required, and maintenance is easy.
[0022]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment in which the present invention is applied to a power storage device will be described with reference to the drawings.
[0023]
FIG. 1 schematically shows an example of the overall configuration of the superconducting bearing device of the power storage device, and FIG. 2 shows an example of the electrical configuration.
[0024]
The superconducting bearing device includes a vertical shaft-like rotating body (1), a superconducting bearing (2), two sets of upper and lower radial displacement detection units (3) and (4), and two sets of upper and lower sets of control type radial magnetic bearings (5) and (6). ), An axial displacement sensor (7), a control-type axial magnetic bearing (8), and a built-in type electric motor (9), which comprise an upper housing (10) and an intermediate housing (11) constituting a fixed part (A) And the lower housing (12). The upper housing (10) has a stepped vertical cylindrical shape that is relatively short in the vertical direction and has a large diameter in the lower half. The intermediate housing (11) is substantially the same diameter as the small diameter portion on the upper side of the upper housing (10), and forms a vertically long vertical cylinder. The lower housing (12) is substantially the same diameter as the lower large-diameter portion of the upper housing (10) and has a relatively short vertical cylindrical shape in the vertical direction. The three housings (10), (11), and (12) are formed integrally and concentrically by joining a plurality of parts.
[0025]
In the following description, the axial axis (vertical axis) is the Z axis, one radial axis (horizontal axis) orthogonal to the Z axis is the X axis, and the radial axis is orthogonal to the Z axis and the X axis. Let (horizontal axis) be the Y-axis.
[0026]
The rotating body (1) is disposed concentrically at the center in the housing (10) (11) (12). An upper flywheel (13) located in a large-diameter portion on the lower side of the upper housing (10) is fixed to the upper part of the rotating body (1), and the lower flywheel (1) A lower flywheel (14) located at the upper part is fixed. These flywheels (13) and (14) are for storing surplus power as kinetic energy.
[0027]
The superconducting bearing (2) is for supporting the rotating body (1) in the axial direction and the radial direction to float in a non-contact manner, and is an annular permanent magnet fixed concentrically to the lower end of the rotating body (1). It consists of an annular superconductor portion (16) provided on the fixed portion (A) side so as to face the portion (15) and the permanent magnet portion (15).
[0028]
The permanent magnet portion (15) includes a support disc (17) concentrically fixed to the lower end portion of the rotating body (1), and a plurality of annular permanent magnets ( 18) is fixed via an annular ferromagnet (19). For example, each permanent magnet (18) has magnetic poles at both ends in the radial direction, and the permanent magnets (18) are arranged so that the magnetic poles on the opposite side in the radial direction have the same polarity. The permanent magnets (18) are arranged in a radial direction so as to be concentric with the rotating body (1), and the magnetic flux distribution of the permanent magnet (18) around the rotating shaft of the rotating body (1) is the rotating body ( It is made not to change by the rotation of 1).
[0029]
Although not shown in detail, a vertical shaft elevating member (20) concentric with the rotating body (1) is provided at an appropriate position below the fixed portion (A). The upper portion of the elevating member (20) passes through the bottom wall of the lower housing (12) and enters the inside thereof, and the superconductor portion (16) is fixed to the upper end of the elevating member (20). At the same time, the superconductor portion (16) is also raised and lowered. The superconductor portion (16) includes an annular cooling tank (21) fixed to the upper end of the elevating member (20) so as to be concentric with the rotating body (1). The tank (21) is a vertical, low-profile flat double cylinder, and its upper end face is opposed to the lower end face of the permanent magnet (18) of the permanent magnet section (15). A portion of the upper end wall of the tank (21) facing the permanent magnet (18) is thin, and a vertical flat annular second type superconductor (22) in the tank (21) inside this portion. Is fixed. The superconductor (22) is arranged so as to be concentric with the rotating body (1), and is opposed to the permanent magnet (18) in the axial direction through a thin upper end wall of the tank (21) and a gap. The superconductor (22) is, for example, an yttrium-based superconductor such as Y ₁ Ba ₂ Cu ₃ O _7-x Normal conducting particles (Y ₂ Ba ₁ Cu ₁ ) Uniformly mixed, and has the property of restraining and pinning the magnetic flux generated from the permanent magnet (18) in an environment where the second type superconducting state appears. The superconductor (22) is arranged as described above so that the magnetic flux of the permanent magnet (18) enters a predetermined amount in a state where the elevating member (20) is raised to the predetermined position. And it is located in the position where distribution of an intrusion magnetic flux does not change with rotation of a rotary body (1). The tank (21) is connected to an appropriate cooling device (not shown) via the cooling fluid supply pipe (23) and the discharge pipe (24), and the tank (21) is filled with, for example, liquid nitrogen by the cooling device. The cooling fluid consisting of the above is circulated, and the superconductor (22) is cooled by the cooling fluid filled in the tank (21). The elevating member (20) is raised and lowered by a suitable elevating device (29). Although not shown in the figure, when the rotating body (1) is lowered to a lower limit position, which will be described later, at a suitable location of the superconducting bearing device, contact between the permanent magnet portion (15) and the superconductor portion (16) is made. In order to prevent this, a suitable stopper is provided to prevent the elevating member (20) from rising from a predetermined ascent limit position.
[0030]
The radial magnetic bearings (5) and (6) support the rotating body (1) in a non-contact manner and control the positions of the rotating body (1) in two radial directions (X-axis and Y-axis directions) orthogonal to each other. It is provided at two locations, upper and lower, in the intermediate housing (11). Each of the radial magnetic bearings (5) and (6) is fixed in the housing (11) so as to sandwich the rotating body (1) from both sides in the X-axis direction, and the rotating body (1) is placed on both sides in the X-axis direction. A pair of X-axis direction electromagnets (5x) (6x) to be attracted and the rotating body (1) are fixed in the housing (11) so as to sandwich the rotating body (1) from both sides in the Y-axis direction. A pair of Y-axis direction electromagnets (5y) (6y) for attracting both sides. In this embodiment, the same magnet is used for the electromagnets (5x), (5y), (6x), and (6y) of the radial magnetic bearings (5) and (6).
[0031]
The radial displacement detection units (3) and (4) constitute radial displacement detection means for detecting the radial displacement of the rotating body (1). The upper detection unit (3) is provided in the vicinity of the upper radial magnetic bearing (5), and the lower detection unit (4) is provided in the vicinity of the lower radial magnetic bearing (6). Each detection unit (3) (4) is fixed in the housing (11) so as to sandwich the rotating body (1) from both sides in the X-axis direction, and detects the displacement of the rotating body (1) in the X-axis direction. A pair of X-axis direction displacement sensors (3x) and (4x) and the rotating body (1) are fixed in the housing (11) so as to sandwich the rotating body (1) from both sides in the Y-axis direction. It is comprised from a pair of Y-axis direction displacement sensor (3y) (4y) which detects this.
[0032]
The axial magnetic bearing (8) controls the position of the rotating body (1) in the axial direction (Z-axis direction) and positions the rotating body (1) at a predetermined position in the axial direction. It is provided in the small diameter part on the upper side of (10). A horizontal outward flange (25) is fixed near the upper end of the rotating body (1). The axial magnetic bearing (8) is fixed in the housing (10) so as to sandwich the portion near the outer periphery of the flange (25) from both sides in the Z-axis direction, and attracts the rotating body (1) to both sides in the Z-axis direction. A pair of upper and lower Z-axis direction electromagnets (8a) and (8b) are provided. In this embodiment, the same electromagnets (8a) and (8b) of the axial magnetic bearing (8) are used.
[0033]
The axial displacement sensor (7) constitutes an axial displacement detecting means for detecting the displacement of the rotating body (1) in the axial direction. The axial displacement sensor (7) is provided at an appropriate position of the fixed portion (A), for example, in the upper end portion of the upper housing (10). Is provided.
[0034]
Each electromagnet (5x) (5y) (6x) (6y) (8a) (8b) of each magnetic bearing (5) (6) (8) is connected to a control device (26), and from this control device (26) Excitation current is supplied to each electromagnet (5x) (5y) (6x) (6y) (8a) (8b). The exciting current is a combination of a constant steady current and a control current that changes due to the displacement of the rotating body (1). Normally, the values of the steady current are equal for all the electromagnets (5x) (5y) (6x) (6y) of the radial magnetic bearings (5) (6). The absolute values of the control currents are equal to each other and the signs are opposite to each other for each pair of electromagnets (5x) (5y) (6x) (6y) corresponding to each radial magnetic bearing (5) (6). . With respect to the pair of upper and lower electromagnets (8a) (8b) of the axial magnetic bearing (8), the values of the steady current are equal to each other, the absolute values of the control current are equal to each other, and the signs are opposite to each other. Then, the control device (26) controls the magnitude of the control current of each electromagnet (8a) (8b) of the axial magnetic bearing (8) based on the output signal of the axial displacement sensor (7). 1) in the axial direction is controlled, and the electromagnets (5x) (5y) of the radial magnetic bearings (5) (6) are controlled based on the output signals of the radial displacement sensors (3x) (3y) (4x) (4y). By controlling the magnitude of the control currents (6x) and (6y), the position of the rotating body (1) in the radial direction is controlled.
[0035]
The lifting device (29) of the lifting member (20) is also connected to the control device (26), thereby controlling the vertical position of the lifting member (20), that is, the superconductor (22).
[0036]
The electric motor (9) is for rotating the rotating body (1) at high speed, and is provided in the intermediate housing (11) between the upper and lower radial magnetic bearings (5) and (6). The electric motor (9) includes a rotor (9a) provided on the outer periphery of the rotating body (1) and a stator (9b) fixed around the rotor (9a) and fixed in the housing (11). Become.
[0037]
When the support by the superconducting bearing (2) and the magnetic bearings (5), (6), and (8) is lost near the upper end and the lower end in the intermediate housing (11), the rotating body (1) is touched down to mechanically Touch-down bearings (27) and (28) are provided for support.
[0038]
When the above power storage device is stopped, the electric motor (9), the superconducting bearing (2) and the magnetic bearings (5) (6) (8) are in an inoperative state, and the rotating body (1) is rotated. Is supported by touchdown bearings (27) and (28). In addition, the superconductor (22) on the fixed part (A) side of the superconducting bearing (2) is sufficiently away from the permanent magnet (18) on the rotating body (1) side in the normal conducting state at room temperature. It is lowered to the lower end position where it is hardly affected by.
[0039]
Then, from such a state, for example, the operation is started as follows.
[0040]
First, the magnetic bearings (5), (6), and (8) are put into an operating state, and the rotating body (1) in a stopped state is supported in a non-contact manner in the radial direction by the radial magnetic bearings (5) and (6). (8) By non-contact support in the axial direction by (8), it is levitated to a predetermined operation position (stable rotation position) with respect to the fixed portion (A). In the case of this embodiment, the rotor (1) is located at the center of the housing (10) (11) (12) when it floats to the operating position, and the upper and lower electromagnets (8a) (8b) of the axial magnetic bearing (8). ) And the flange (25) of the rotating body (1) have the same size in the axial direction, and a pair of electromagnets (5x) (5y) (6x) of the radial magnetic bearings (5) (6). ) (6y), the radial gaps between the rotating body (1) and the rotating body (1) are equal to each other. At this time, since the superconducting bearing (2) is still in a non-operating state, the weight of the rotating body (1) is supported only by the axial magnetic bearing (8), and therefore the upward attracting force by the upper electromagnet (8a). Is larger by the weight of the rotating body (1) than the downward attractive force by the lower electromagnet (8b), and the axial magnetic bearing (8) as a whole generates an upward attractive force. That is, the control current of the upper electromagnet (8a) is a positive value, the value of the lower electromagnet (8b) is a negative value, and the value of the excitation current of the upper electromagnet (8a) is the value of the excitation current of the lower electromagnet (8b). Compared to the above, the axial magnetic bearing (8) is increased by the upward attractive force (weight of the rotating body (1)) as a whole.
[0041]
When the rotating body (1) is held at the operating position by the magnetic bearings (5), (6), and (8), the cooling fluid is supplied to the cooling tank (21), and the superconductor (22) is moved to the predetermined position at the above position. It cools to temperature and is hold | maintained at the superconducting state which appears a 2nd type superconducting state.
[0042]
Next, with the rotating body (1) held in the operating position by the magnetic bearings (5), (6), and (8), the superconductor (22) is opposed to the permanent magnet (18) with a predetermined gap. Raise to the position where you want to. Then, a part of the magnetic flux generated from the permanent magnet (18) partially enters the superconductor (22), and the entered magnetic flux is pinned to the pinning point inside the superconductor (22). Next, the superconductor (22) is raised. When the superconductor (22) of the superconducting bearing (2) in the operating state is lifted with the rotating body (1) held in the operating position by the axial magnetic bearing (8), the axial direction by the superconducting bearing (2) The upward support force gradually increases, and accordingly, the support force by the axial magnetic bearing (8) gradually decreases. That is, the upward attracting force by the upper electromagnet (8a) of the axial magnetic bearing (8) is gradually reduced, and the downward attracting force by the lower electromagnet (8b) is gradually increased, and the axial magnetic bearing (8 ) The overall upward suction force gradually decreases. Then, the upward attractive force by the upper electromagnet (8a) of the axial magnetic bearing (8) and the downward attractive force by the lower electromagnet (8b) are equal to each other. When the supporting force in the direction becomes zero, the superconductor (22) is stopped. Thereafter, when a preload is applied to the superconducting bearing (2), the superconductor (22) is further raised by a predetermined distance and then lowered again, so that the supporting force of the axial magnetic bearing (8) becomes zero. At this point, the superconductor (22) is stopped. Then, the supply of the excitation current to the electromagnets (8a) and (8b) of the axial magnetic bearing (8) is stopped to make it inoperative. As a result, the weight of the rotating body (1) is supported only by the superconducting bearing (2), and the rotating body (1) is supported in a non-contact manner at the operating position by the superconducting bearing (2) and the radial magnetic bearing (5) (6). Is done.
[0043]
In the case of the above apparatus, the same upper and lower electromagnets (8a) and (8b) of the axial magnetic bearing (8) are used, and the upper and lower electromagnets (8a) and (8b) are in a state where the rotating body (1) is in the operating position. ) And the flange (25) of the rotating body (1) are equal to each other, so that the relationship between the excitation current value and the attractive force is the same for the upper and lower electromagnets (8a) and (8b). . Therefore, by detecting that the excitation currents of the upper and lower electromagnets (8a) and (8b) are equal, it is possible to know that the attractive forces of the upper and lower electromagnets (8a) and (8b) are equal. Depending on the power storage device, the upper and lower electromagnets of the axial magnetic bearing may have different specifications, or the gaps between the rotating body in the operating position and the upper and lower electromagnets may not be equal. However, even in such a case, since the operation position is constant, the relationship between the value of the excitation current and the value of the attractive force is constant for each electromagnet and can be known in advance. Therefore, if the relationship between the excitation current values of the upper and lower electromagnets when the attraction forces of the upper and lower electromagnets are equal is determined in advance, it can be detected that the excitation current values of the upper and lower electromagnets are in the above relationship. Thus, it can be known that the attraction forces of the upper and lower electromagnets are equal.
[0044]
When the rotating body (1) is supported by the superconducting bearing (2) and the radial magnetic bearings (5) and (6) as described above, the electric motor (9) is driven. Thus, the superconducting bearing device starts operation, and the rotating body (1) is rotated while being held at the operating position by the superconducting bearing (2) and the radial magnetic bearings (5) (6). At this time, the magnetic flux that has entered the superconductor (22) does not ideally become a resistance that prevents rotation as long as the magnetic flux distribution is uniform and unchanged with respect to the rotational axis of the rotating body (1).
[0045]
In the case of the above-described apparatus, the rotating body (1) is supported in the radial direction slightly by the superconducting bearing (2) using the type 2 superconductor (22), and accordingly, the radial magnetic bearings (5) (6) ) Requires only a small supporting force, and the radial magnetic bearings (5) and (6) can be miniaturized.
[0046]
In addition, from the beginning, the rotating body (1) is held at the operating position by the axial magnetic bearing (8) and the radial magnetic bearings (5) and (6), and is maintained at the operating position by the superconducting bearing (2). In addition, it is not necessary to lift the rotating body upward from the operating position. Accordingly, the length of the rotating body (1) can be shortened accordingly.
[0047]
During the operation of the above device, the magnetic levitation force due to the superconducting bearing (2) decreases due to the magnetic flux creep of the superconductor (22) with time, and the position of the rotating body (1) may gradually fall from the operating position. is there. In that case, the displacement amount of the rotating body (1) is detected by the axial displacement sensor (7), and the superconductor (22) is raised by that amount, and feedback control is performed so as to keep the rotating body (1) at the operating position. . For example, when the rotating body (1) is lowered by a predetermined amount (for example, 0.1 mm) from the operating position, the elevating member (20) is raised by the elevating device (29) until the rotating body (1) returns to the operating position. This control is repeated until the elevating member (20) is stopped at the upper limit position by the stopper. Even after the elevating member (30) stops at the ascent limit position, the rotating body (1) is lowered, but when the elevating member (30) is lowered by a predetermined amount (for example, (0.8 mm) from the operation position and lowered from the predetermined lower limit position, At this point, the axial magnetic bearing (8) is operated, and the rotating body (1) is held in the operating position again by the axial magnetic bearing (8), at which time the rotating body (1) continues to rotate. The lower limit position is set above the position where the rotating body (1) touches down the touch-down bearings (27) and (28). Therefore, before the rotating body (1) touches down, The rotating body (1) can be supported at the operating position by the axial magnetic bearing (8) while being rotated, and the rotating body (1) is supported by the axial magnetic bearing (8) and the radial magnetic bearing (5) (6). ) In the rolled state, the superconductor (22) is lowered and brought into the complete second superconducting state, and then the superconducting (22) is raised and the superconducting bearing (2) in the same manner as at the start of the operation. Only the weight of the rotating body (1) is supported, and the axial magnetic bearing (8) is deactivated, whereby the operation of the device by the superconducting bearing (2) is resumed, and again the rotating body (1) The superconducting bearing (2) and the radial magnetic bearings (5) and (6) are supported at the operating position and continue to rotate, and thus the magnetic levitation force by the superconducting bearing (2) is reduced and the rotating body (1) Even if the position of the rotating body (1) is lowered, the axial magnetic bearing (8) can be used to resume the operation while the rotating body (1) is rotated before the touchdown of the position of the rotating body (1). ) For a long time without touching down It is possible to operate and continue to.
[0048]
In the above control process in which the elevating member (20) is raised to prevent the rotating body (1) from descending in order to keep the rotating body (1) at a predetermined operating position, the axial direction of the operating rotating body (1) In order to suppress this vibration, the axial magnetic bearing (8) is operated during operation, and the electromagnet (8a) (8b) is controlled by the control current or the control current and the normal steady current. It is also possible to control by supplying a small bias current. The occurrence of vibration in the axial direction of the rotating body (1) can be detected by the axial displacement sensor (7).
[0049]
In the above embodiment, the superconducting bearing (2) using the type 2 superconductor (22) is used. Instead, the type 1 superconductor that appears in the type 1 superconducting state by cooling is used. Superconducting bearings that have been used can also be used. In this case, the overall configuration of the superconducting bearing is the same as that of the superconducting bearing (2), and the first type superconductor is used instead of the second type superconductor (22). The superconducting bearing using the first type superconductor magnetically levitates the rotating body (1) using the complete diamagnetic phenomenon in the first type superconducting state of the first type superconductor. The rotating body (1) Receives only the supporting force upward in the axial direction from the superconductor, and is supported only in the axial direction. The rotating body (1) is supported in the radial direction only by the radial magnetic bearings (5) and (6).
[0050]
When a superconducting bearing using the first type superconductor is used, the operation can be started in substantially the same manner as described above, and the magnetic levitation force due to the superconducting bearing is reduced and the position of the rotating body (1) is changed. Even if it falls, the operation can be resumed while rotating the rotating body (1) without touching it down.
[0051]
In the case of starting operation, the superconductor is cooled at the lower end position with the rotating body (1) held in the operating position by the magnetic bearings (5), (6), and (8), and the first type superconducting state appears. Thereafter, the superconductor is gradually raised. When the superconductor approaches the permanent magnet (18) to some extent, the rotating body (1) receives an upward support force due to the complete diamagnetism phenomenon of the superconductor, and this support force increases as the superconductor rises. In addition, the supporting force by the axial magnetic bearing gradually decreases. When the supporting force by the axial magnetic bearing (8) becomes zero and the entire weight of the rotating body (1) is supported by the superconducting bearing, the axial magnetic bearing (8) is brought into a non-operating state, and the rotating body (1) is supported at the operating position by the superconducting bearing (2) and the radial magnetic bearings (5) and (6), and the motor (9) is driven to start the operation.
[0052]
During operation, when the magnetic levitation force due to the superconducting bearing decreases with time and the position of the rotating body (1) gradually falls from the operating position, the elevating member (20) and the superconductor are raised and rotated. When feedback control is performed to keep the body (1) in the operating position and the elevating member (20) can no longer rise from the ascent limit position, the axial magnetic bearing ( 8) is operated, and the rotating body (1) is held in the operating position again by the axial magnetic bearing (8). Then, in a state where the rotating body (1) is held and rotated by the axial magnetic bearing (8) and the radial magnetic bearing (5) (6), the superconductor is lowered to be in the complete first superconducting state again. Thereafter, as in the case of starting the operation, the superconductivity is raised, the weight of the rotating body (1) is supported only by the superconducting bearing, the axial magnetic bearing (8) is deactivated, and the operation is resumed.
[0053]
The configuration of the superconducting bearing, the axial magnetic bearing, the radial magnetic bearing, the electric motor, and the like, the overall configuration of the power storage device, and the like are not limited to those of the above embodiment, and can be changed as appropriate.
[0054]
Further, the present invention can be applied to devices other than the power storage device.
[Brief description of the drawings]
FIG. 1 is a schematic configuration diagram of a power storage device showing an embodiment of the present invention.
FIG. 2 is a block diagram showing an example of an electrical configuration of a superconducting bearing device portion of the power storage device.
[Explanation of symbols]
(1) Rotating body
(2) Superconducting bearing
(3x) (3y) (4x) (4y) Radial displacement sensor
(5) (6) Radial magnetic bearing
(7) Axial displacement sensor
(8) Axial magnetic bearing
(9) Electric motor
(18) Permanent magnet
(20) Lifting member
(22) Superconductor
(26) Control device

Claims (2)

A rotating body arranged vertically in a fixed portion, a superconducting bearing that supports the rotating body in at least the axial direction and floats in a non-contact manner, a radial displacement sensor for detecting a radial displacement of the rotating body, and the rotation A control-type radial magnetic bearing that supports the body in a non-contact manner at a predetermined position in the radial direction, an axial displacement sensor for detecting an axial displacement of the rotating body, and if necessary, the rotating body is not positioned at a predetermined position in the axial direction. A control type axial magnetic bearing for contact support, a control device for controlling the radial magnetic bearing, the axial magnetic bearing and the superconducting bearing based on output signals of the radial displacement sensor and the axial displacement sensor, and the rotating body; An electric motor that rotates is provided, and the superconducting bearing is attached to the lower end of the rotating body. A permanent magnet, and a superconductor attached to an elevating member provided to be able to ascend and descend to the fixed portion below the rotating body so as to face the permanent magnet, and the control device includes the rotating body Is rotated in a non-contact manner supported by the radial magnetic bearing and the superconducting bearing, by controlling the vertical position of the elevating member based on the output of the axial displacement sensor It is supported at a stable rotational position, and when the control of the position of the rotating body by controlling the position of the elevating member reaches a limit, an axial magnetic bearing is operated to support the rotating body at the stable rotational position. A superconducting bearing device characterized by comprising: The superconductor is a type 2 superconductor that exhibits a type 2 superconducting state by cooling, and in the type 2 superconducting state, has the property of constraining and pinning the magnetic flux that enters, and the superconducting bearing is 2. The superconducting bearing device according to claim 1, wherein the rotating body is supported in a non-contact manner in an axial direction and a radial direction by a pinning force of the superconductor.

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