The present invention relates to an electromagnetic clutch used in a compressor and the like, and particularly relates to an electromagnetic clutch in which a force attracting an armature to a rotor caused by excitation of an electromagnetic coil is enhanced by use of a stack structure of armature plates as the armature.
A conventional electromagnetic clutch has the following structure to enhance a force causing an armature to be attached to a rotor due to excitation of an electromagnetic coil: a plurality of slits are formed in the armature so that a magnetic circuit formed when the armature is attached to the rotor runs to and from the rotor and the armature a plurality of times (for example, see Patent Document 1).
Patent Document 1: Japanese Patent Application Laid-open Publication No. H08-284976
In the conventional electromagnetic clutch, however, a magnetic circuit formed when the armature is attracted by excitation of the electromagnetic coil (i.e. when the rotor and the armature are still separated before the armature is attached to the rotor) needs to pass between the slits formed in the armature. Since a magnetic circuit with slits has a higher magnetic resistance than a magnetic circuit with no slits, the force attracting the armature to the rotor caused by excitation of the electromagnetic coil decreases.
To solve such a problem, the present invention has an object of providing an electromagnetic clutch in which the force attracting an armature to a rotor caused by excitation of an electromagnetic coil is enhanced.
To achieve the stated object, an electromagnetic clutch according to the present invention is an electromagnetic clutch including: a rotor that includes an electromagnetic coil; and an armature that faces the rotor, and is caused to be attached to the rotor by a magnetic force of the electromagnetic coil, in which the rotor has a plurality of concentric slits on a contact surface with the armature, in which the armature includes: a first armature plate that has one or more concentric slits each facing a contact surface between adjacent slits of the rotor; a second armature plate that is placed on a back side of the first armature plate; and an intermediate layer that is placed between the first armature plate and the second armature plate, and is lower in magnetic permeability than each of the first armature plate and the second armature plate, in which, by excitation of the electromagnetic coil, a magnetic circuit from the rotor back to the rotor through the first armature plate, the intermediate layer, the second armature plate, the intermediate layer, and the first armature plate is formed when the rotor and the armature are not in contact with each other, and a magnetic circuit from the rotor back to the rotor through the first armature plate, a part between the adjacent slits of the rotor, and the first armature plate is formed when the rotor and the armature are in contact with each other.
In the electromagnetic clutch according to the present invention, the magnetic circuit from the rotor back to the rotor through the first armature plate, the intermediate layer, the second armature plate, the intermediate layer, and the first armature plate is formed. This magnetic circuit does not pass through the slit of the first armature plate higher in magnetic resistance, but passes through the second armature plate lower in magnetic resistance. The whole magnetic path M1 therefore has a lower magnetic resistance. The electromagnetic clutch according to the present invention thus achieves an enhanced force attracting the armature to the rotor caused by excitation of the electromagnetic coil.
Hereinbelow, a first embodiment of the present invention will be described with reference to FIGS. to 5.
The electromagnetic clutch is a double-flux type electromagnetic clutch used in, for example, a compressor for an automobile or indoor air conditioner, and is provided in a housing of the compressor or the like. As illustrated in
In double-flux type, the contact surface of each of the rotor 1 and the armature 2 is divided by slits in the radial direction so that the magnetic circuit (hereafter referred to as “magnetic path”) formed when the rotor 1 and the armature 2 are in contact with each other runs to and from the rotor 1 and the armature 2 twice. In triple-flux type, the magnetic path formed when the rotor 1 and the armature 2 are in contact with each other runs to and from the rotor 1 and the armature 2 three times.
The rotor 1 is shaped like a ring with an opening at the center thereof, and is integrally formed with a pulley 12 for transmitting power from a power source (not illustrated) such as an engine. Into the opening 11 formed at the center, a drive shaft (not illustrated) connected to the armature 2 is inserted. The drive shaft is supported by a radial bearing or the like between the drive shaft and a wall surface of the opening 11. The pulley 12 constitutes an outer peripheral portion of the rotor 1. The pulley 12 is connected to the power source by a belt, and rotates the rotor 1.
Slits 14 are formed on a surface (hereafter referred to as “contact surface”) 13 of the rotor 1 that comes into contact with the armature 2. Two slits 14 are concentrically formed on the contact surface 13, thereby dividing the contact surface 13 into three in the radial direction. The three parts of the contact surface 13 divided by the slits 14 are connected by connecting portions 15 formed concentrically with the slits 14.
In the rotor 1, electromagnetic coils 16 are provided, as illustrated in
The armature 2 faces the rotor 1, and includes a first armature plate 21, an intermediate layer 22, and a second armature plate 23. The armature 2 is formed by stacking the first armature plate 21, the intermediate layer 22, and the second armature plate 23 in this order from the rotor 1 side. Each of the armature plates 21 and 23 is made of a magnetic material such as iron or an iron oxide. When the electromagnetic coils 16 provided in the rotor 1 are excited, the magnetic force caused thereby causes the attraction and attachment of the armature plates 21 and 23 to the rotor 1.
The first armature plate 21 faces the rotor 1. The first armature plate 21 is shaped like a disk having a circular opening 24 at its center, as illustrated in
The second armature plate 23 is placed on the side opposite from rotor 1 across the first armature plate 21 (hereafter referred to as “back side”). The second armature plate 23 is shaped like a disk having a circular opening 27 at its center and a plurality of rivet holes 28, as illustrated in
The intermediate layer 22 is placed between the first armature plate 21 and the second armature plate 23. The intermediate layer 22 is a coating film of an anticorrosive or the like applied to a surface of each of the armature plates 21 and 23. A material lower in magnetic permeability than each of the armature plates 21 and 23 is selected as the coating film. The magnetic resistance of the intermediate layer 22 is therefore higher than the magnetic resistance of each of the armature plates 21 and 23. Meanwhile, the magnetic resistance of the intermediate layer 22 is lower than the magnetic resistance of the slit 25 (i.e. the space in the slit 25) of the first armature plate 21. The magnetic resistance of the intermediate layer 22 is set by changing the material or thickness of the coating film.
A damping plate 29 is placed on the back side of the second armature plate 23, as illustrated in
Between the second armature plate 23 and the damping plate 29, leaf springs 31 are placed. The leaf springs 31 are biasing means for biasing the armature 2 toward the damping plate 29 (that is, biasing the armature 2 away from the rotor 1). In a case in which the electromagnetic coils 16 of the rotor 1 are not excited, the armature 2 is separated from the rotor 1 by the biasing force of the leaf springs 31. This means the attraction and attachment of the armature 2 by the electromagnetic coils 16 are carried out against the biasing force of the leaf springs 31. Between the second armature plate 23 and the damping plate 29, spacers 32 are placed to keep the space for accommodating the leaf springs 31.
The outer ends of the leaf springs 31 are connected to the first armature plate 21, the intermediate layer 22, and the second armature plate 23, by rivets 30 (see
On the back side of the damping plate 29, a coupler 33 is placed, as illustrated in
The following describes the magnetic path formed by the electromagnetic clutch having the above-mentioned structure, with reference to
When the electromagnetic clutch of this embodiment is in a state in which the electromagnetic coils 16 are not excited, the rotor 1 and the armature 2 are separated by the biasing force of the leaf springs 31, and the rotor 1 and the armature 2 are not in contact with each other. If each of the electromagnetic coils 16 is excited by energization when the rotor 1 and the armature 2 are not in contact with each other (hereafter simply referred to as “during non-contact”), a magnetic path M1 is formed.
The magnetic path M1 is a closed circuit from the rotor 1 back to the rotor 1 through the first armature plate 21, the intermediate layer 22, the second armature plate 23, the intermediate layer 22, and the first armature plate 21, as illustrated in
When the magnetic path M1 is formed, the armature 2 is attracted to the rotor 1 by the magnetic force. As a result, the rotor 1 and the armature 2 come into contact with each other, and the armature 2 is attached to the rotor 1. When the rotor 1 and the armature 2 are in contact with each other (hereafter simply referred to as “during contact”), a magnetic path M2 is formed.
The magnetic path M2 is a closed circuit from the rotor 1 back to the rotor 1 through the first armature plate 21, the contact surface 13a between the two slits 14 of the rotor 1, and the first armature plate 21, as illustrated in
The electromagnetic clutch according to this embodiment includes: the rotor 1 that includes therein the electromagnetic coil 16; and the armature 2 that faces the rotor 1, and is attracted and attached to the rotor 1 by the magnetic force of the electromagnetic coil 16. The rotor 1 has the two concentric slits 14 on the contact surface 13 with the armature 2. The armature 2 includes: the first armature plate 21 that has the one concentric slit 25 facing the contact surface 13a between the adjacent slits 14 of the rotor 1; the second armature plate 23 that is placed on the back side of the first armature plate 21; and the intermediate layer 22 that is placed between the first armature plate 21 and the second armature plate 23, and is lower in magnetic permeability than each of the armature plates 21 and 23. In the electromagnetic clutch, by excitation of the electromagnetic coil 16, the magnetic path M1 from the rotor 1 back to the rotor 1 through the first armature plate 21, the intermediate layer 22, the second armature plate 23, the intermediate layer 22, and the first armature plate 21 is formed when the rotor 1 and the armature 2 are not in contact with each other, and the magnetic path M2 from the rotor 1 back to the rotor 1 through the first armature plate 21, the contact surface 13a between the adjacent slits 14 of the rotor 1, and the first armature plate 21 is formed when the rotor 1 and the armature 2 are in contact with each other.
In such a structure, the magnetic path M1 formed during non-contact does not pass through the slit 25 of the first armature plate 21 higher in magnetic resistance, but passes through the second armature plate 23 lower in magnetic resistance. The whole magnetic path M1 therefore has a lower magnetic resistance. The force attracting the armature 2 to the rotor 1 caused by excitation of the electromagnetic coil 16 can be enhanced in this way.
Moreover; the magnetic path M2 formed during contact runs to and from the rotor 1 and the first armature plate 21 twice. The force causing the armature 2 to be attached to the rotor 1 due to excitation of the electromagnetic coil 16 can be enhanced in this way.
Furthermore, according to this embodiment, the intermediate layer 22 is a coating film, and so can be formed easily. Since an anticorrosive or the like applied to the surface of the armature can be used as the coating film, there is no need for a new material.
Next, a second embodiment of the present invention will be described with reference to
In this embodiment, the second armature plate 23 is placed on the back side of . the first armature plate 21, and a spacer 35 is disposed between the armature plates 21 and 23 to keep a predetermined air layer (space) between the armature plates 21 and 23, as illustrated in
The magnetic permeability of the intermediate layer 22 in this embodiment is equal to the magnetic permeability of air, and so is lower than the magnetic permeability of each of the armature plates 21 and 23. The magnetic resistance of the intermediate layer 22 is accordingly higher than the magnetic resistance of each of the armature plates 21 and 23. Meanwhile, the magnetic resistance of the intermediate layer 22 is set to be lower than the magnetic resistance of the slit 25 (i.e. the space in the slit 25) of the first armature plate 21. The magnetic resistance of the intermediate layer 22 is set by changing the width of the intermediate layer (air layer) 22. In particular, it is preferable that the width of the intermediate layer 22 is less than the width of the slit 25.
In the electromagnetic clutch in this embodiment, the magnetic circuit M1 during non-contact is a closed circuit from the rotor 1 back to the rotor 1 through the first armature plate 21, the intermediate layer 22, the second armature plate 23, the intermediate layer 22, and the first armature plate 21, as illustrated in
According to this embodiment, the intermediate layer 22 is an air layer formed between the armature plates 21 and 23, and so can be formed easily. In addition, the magnetic resistance of the intermediate layer 22 can be easily adjusted by changing the height of the spacer 35.
Next, a third embodiment of the present invention will be described with reference to
The electromagnetic clutch in this embodiment is triple-flux type electromagnetic clutch, as illustrated in
In the electromagnetic clutch in this embodiment, the magnetic circuit M1 during non-contact is a closed circuit from the rotor 1 back to the rotor 1 through the first armature plate 21, the intermediate layer 22, the second armature plate 23, the intermediate layer 22, and the first armature plate 21, as illustrated in
Although the embodiments of the present invention have been described above, the present invention is not limited thereto. Each of the first armature plate 21, the intermediate layer 22, and the second armature plate 23 may be a stack structure of a plurality of plate-like members. For example, the second armature plate 23 may be formed by stacking two or more second armature plates 23 described in the embodiments.
Although the rotor 1 is formed integrally with the pulley 12, but it is not limited thereto. For example, the rotor 1 and the pulley 12 prepared separately may be joined by welding or the like.
The electromagnetic clutch is not limited to double-flux type or triple-flux type electromagnetic clutch, and the magnetic path M2 during contact may runs to and from the rotor 1 and the armature 2 four or more times. For example, in a case in which the magnetic path M2 during contact runs to and from the rotor 1 and the armature 2 N times, the rotor 1 has N concentric slits 14 on the contact surface 13 with the armature 2, and the armature 2 has (N−1) concentric slits 25 facing respective (N−1) contact surfaces 13a each of which is between adjacent slits 14 of the rotor 1. This structure enhances the force causing the armature 2 to be attached to the rotor 1 due to excitation of the electromagnetic coil 16.
The intermediate layer 22 may be made of a material, such as soft iron or nickel, lower in magnetic permeability than each of the armature plates 21 and 23. In such a case, the magnetic resistance of the intermediate layer 22 is set to be lower than the magnetic resistance of the slit 25 (i.e. the space in the slit 25) of the first armature plate 21. The magnetic resistance of the intermediate layer 22 can be adjusted by changing the thickness or material of the intermediate layer.
Number | Date | Country | Kind |
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2012-038052 | Feb 2012 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2013/054025 | 2/19/2013 | WO | 00 |