FORM 2
THE PATENTS ACT, 1970
(39 of 1970)
&
THE PATENTS RULES, 2003
COMPLETE SPECIFICATION
[See section 10, Rule 13]
MANUFACTURING METHOD OF STATOR, STATOR OF ELECTRIC MOTOR,
ELECTRIC MOTOR, HERMETICALLY SEALED COMPRESSOR, AND
REFRIGERATION CYCLE APPARATUS;
MITSUBISHI ELECTRIC CORPORATION, A CORPORATION ORGANISED AND
EXISTING UNDER THE LAWS OF JAPAN, WHOSE ADDRESS IS 7-3,
MARUNOUCHI 2-CHOME, CHIYODA-KU, TOKYO 1008310, JAPAN
THE FOLLOWING SPECIFICATION PARTICULARLY DESCRIBES THE INVENTION
AND THE MANNER IN WHICH IT IS TO BE PERFORMED.
2
DESCRIPTION
Title of Invention
MANUFACTURING METHOD OF STATOR, STATOR OF ELECTRIC MOTOR,
ELECTRIC MOTOR, HERMETICALLY SEALED COMPRESSOR, AND
REFRIGERATION CYCLE APPARATUS5
Technical Field
[0001]
The present disclosure relates to a manufacturing method of a stator, a stator of
an electric motor, an electric motor, a hermetically sealed compressor, and a10
refrigeration cycle apparatus.
Background Art
[0002]
In general, a winding method for a stator of a rotating electric machine has been
known. The stator includes an annular yoke including a plurality of laminated yoke15
pieces that are rotatable to each other, and at the yoke pieces, respective teeth are
formed. In the winding method, a winding is wound around these yoke pieces (see, for
example, Patent Literature 1). In this winding method for the stator of the rotating
electric machine, the annular yoke is deformed into a non-circular shape, for example
an elliptical shape, to widen some of gaps between adjacent ones of a plurality of teeth,20
as compared with the other gaps, to cause a winding to pass through each of the
widened gaps and wind the winding around each of the teeth.
Citation List
Patent Literature
[0003]25
Patent Literature 1: Japanese Unexamined Patent Application Publication No.
2010-98938
Summary of Invention
Technical Problem
[0004]30
3
However, in the winding method for the stator of the rotating electric machine
disclosed in Patent Literature 1, the annular yoke is deformed into a non-circular shape
to wind a winding around each of the teeth. Therefore, it is not possible to wind a
winding around a plurality of adjacent teeth simultaneously using a plurality of winding
nozzles.5
[0005]
The present disclosure is applied to solve the above problem, and relates to a
manufacturing method of a stator, in which windings are wound around a plurality of
adjacent teeth simultaneously using a plurality of winding nozzles, thereby to reduce
time required for the winding and reduce the likelihood that a connecting wire will loose10
and also to a stator of an electric motor, an electric motor, a hermetically sealed
compressor, and a refrigeration cycle apparatus.
Solution to Problem
[0006]
A manufacturing method of a stator according to one embodiment of the present15
disclosure is a manufacturing method of a stator that includes: a stator core including a
plurality of divided cores that are connected annularly and include respective back
yokes and teeth, the back yokes being fixed to an inner circumferential surface of a
container having a cylindrical shape and extending in a circumferential direction of the
container, the teeth protruding inwardly from inner circumferential surfaces of the back20
yokes in a radial direction; a winding wound around the teeth of the divided cores, and
insulators insulating the divided cores from the winding. Each of the insulators
includes: an end-face insulating portion covering an end face of an associated one of
the divided cores in an axial direction of the container; an inner flange portion projecting
in the circumferential direction from an inner-circumferential-side end portion of the end-25
face insulating portion, and extending in a direction away from the divided core in the
axial direction; and an outer flange portion projecting in the circumferential direction
from an outer-circumferential-side end portion of the end-face insulating portion, and
extending in the axial direction away from the divided core. The outer flange portion
has, on an outer circumferential surface of the outer flange portion, a set portion on30
4
which a connecting wire extending from the winding is set, and has, on an inner
circumferential surface of the outer flange portion, a recessed insulator portion having a
recess. The recessed insulator portion has a width in the circumferential direction that
is greater than a width of the end-face insulating portion in the circumferential direction,
and smaller than a width of the outer flange portion in the circumferential direction. A5
first end portion is further form the divided core than a second end portion, where the
first end portion is one of end portions of the recessed insulator portion that is farther
from the divided core in the axial direction than the other end portion, and the second
end portion is one of end portions of the inner flange portion that is further from the
divided core in the axial direction than the other end portion. A third end portion is10
closer to the divided core than the second end portion, where the third end portion is the
other end portion of the recessed insulator portion that is closer to the divided core in
the axial direction than the one end portion of the recessed insulator portion. A
stepped portion is provided at a boundary between the third end portion and an inner
circumferential surface of the outer flange portion. The manufacturing method15
includes: performing winding simultaneously on adjacent ones of the teeth, using
winding nozzles, after opening one part of a single body into which the divided cores are
connected annularly to combine, such that the single body is C-shaped, thereby
increasing distances between the teeth; and laying the connecting wire, in the laying the
connecting wire, each of the winding nozzles is moved from one of the teeth that is20
subjected to winding to a subsequent one of the teeth, after the opened part of the
single body in which the divided cores are connected is closed such that the single body
is circularly shaped and then the wiring nozzle is moved and the connecting wire is laid
over the set portion. The performing winding and the laying the connecting wire are
alternately repeated. In the performing winding, the winding to be in contact with25
portions of the insulators that are located opposite to the back yokes is wound such that
a distal end of the winding nozzle is caused to pass through an inside of the recessed
insulator portion, while the winding led out from the distal end of the winding nozzle is
being laid over the stepped portion.
[0007]30
5
A stator of an electric motor according to another embodiment of the present
disclosure is manufactured by the above manufacturing method of a stator.
[0008]
An electric motor according to still another embodiment of the present disclosure
includes: the above stator of an electric motor; and a rotor of an electric motor, the rotor5
being provided inward of the stator.
[0009]
A hermetically sealed compressor according to a further embodiment of the
present disclosure includes: the above electric motor; a compression mechanism
configured to be driven by the electric motor and to compress fluid sucked from outside;10
and a hermetically sealed container housing the electric motor and the compression
mechanism.
[0010]
A refrigeration cycle apparatus according to a still further embodiment of the
present disclosure includes: the above hermetically sealed compressor; an outdoor-side15
heat exchanger; a pressure reducing device; and an indoor-side heat exchanger.
Advantageous Effects of Invention
[0011]
In the manufacturing method of a stator according to the above one embodiment
of the present disclosure, in the process of performing winding, windings are wound20
around a plurality of the teeth adjacent to each other simultaneously with the plurality of
winding nozzles in a state in which the single body in which the divided cores are
connected is opened at one part and is C-shaped, thereby reducing the time required
for the winding; and in the process of laying the connecting wire, the connecting wire is
laid after the single body including the connected divided cores and opened at the one25
part are closed to be shaped circularly, thereby reducing the likelihood that the
connecting wire will loose. Furthermore, the winding to be in contact with portions of
the insulators that are located opposite to the back yoke is wound such that the distal
end of the winding nozzle is made to pass through the inside of the recessed insulator
portion, while the winding led out from the distal end of the winding nozzle is being laid30
6
over the stepped portion. Thus, it is possible to bring the winding into tight contact with
the portions of the insulators that are located opposite to the back yoke, and improve
the winding density.
Brief Description of Drawings
[0012]5
[Fig. 1] Fig. 1 is a sectional view of a hermetically sealed compressor according
to Embodiment 1.
[Fig. 2] Fig. 2 is a cross-sectional view of the hermetically sealed compressor
taken along the A-A' line in Fig. 1, as viewed from above.
[Fig. 3] Fig. 3 is a schematic configuration diagram of a refrigeration cycle10
apparatus, such as an air-conditioning apparatus, to which the hermetically sealed
compressor according to Embodiment 1 is connected.
[Fig. 4] Fig. 4 is a cross-sectional view of the hermetically sealed compressor
taken along the B-B' line in Fig. 1, as viewed from above.
[Fig. 5] Fig. 5 is an annular plan view of a stator according to Embodiment 1.15
[Fig. 6] Fig. 6 is a plan view of stator iron cores of the stator according to
Embodiment 1.
[Fig. 7] Fig. 7 is a plan view of a stator iron core piece (first core part) of the stator
according to Embodiment 1.
[Fig. 8] Fig. 8 is a plan view of a stator iron core piece (second core part) of the20
stator according to Embodiment 1.
[Fig. 9] Fig. 9 is a sectional view of a laminated structure of the stator iron cores
of the stator according to Embodiment 1.
[Fig. 10] Fig. 10 is a plan view of C-shaped stator cores of the stator according to
Embodiment 1.25
[Fig. 11] Fig. 11 is a plan view of the C-shaped stator according to Embodiment 1
before winding.
[Fig. 12] Fig. 12 is a perspective view of the C-shaped stator according to
Embodiment 1 before winding.
7
[Fig. 13] Fig. 13 is a perspective view of the C-shaped stator according to
Embodiment 1 after winding.
[Fig. 14] Fig. 14 is a plan view of the C-shaped stator according to Embodiment 1
after winding.
[Fig. 15] Fig. 15 is a perspective view of the stator formed annularly according to5
Embodiment 1 after winding.
[Fig. 16] Fig. 16 is a flowchart illustrating a manufacturing method of the stator
according to Embodiment 1.
[Fig. 17] Fig. 17 is a plan view of insulators of the stator according to Embodiment
1.10
[Fig. 18] Fig. 18 is a perspective view illustrating a method of laying connecting
wires of the stator according to Embodiment 1.
[Fig. 19] Fig. 19 is a perspective view illustrating a process of performing winding
on the stator according to Embodiment 1.
[Fig. 20] Fig. 20 is a schematic explanatory view illustrating a process of15
performing winding on a stator of a comparative example.
[Fig. 21] Fig. 21 is a sectional view of an insulator of the stator according to
Embodiment 1.
[Fig. 22] Fig. 22 is a partially-enlarged perspective view of the stator according to
Embodiment 1.20
[Fig. 23] Fig. 23 is a sectional view of an upper portion of the stator that is taken
along an up-down direction at a portion of the stator that is indicated by an arrow B in
Fig. 22.
[Fig. 24] Fig. 24 is a sectional view of the upper portion of the stator that is taken
along the up-down direction at a portion of the stator that is indicated by an arrow C in25
Fig. 22.
[Fig. 25] Fig. 25 is a plan view illustrating the process of performing winding at the
stator according to Embodiment 1.
[Fig. 26] Fig. 26 is a sectional view of another configuration of insulators in the
stator according to Embodiment 1.30
8
Description of Embodiments
[0013]
Embodiments of the present disclosure will be described with reference to the
drawings. It should be noted that the present disclosure is not limited by the
embodiment described below. In addition, in the drawings, the relationship in size5
between components may differ from an actual one.
[0014]
Embodiment 1
Fig. 1 is a sectional view of a hermetically sealed compressor 100 according to
Embodiment 1. Fig. 2 is a cross-sectional view of the hermetically sealed compressor10
100 that is taken along line A-A' in Fig. 1, as viewed from above. Regarding
Embodiment 1, a single-cylinder rotary compressor will be described below as an
example of the hermetically sealed compressor 100.
[0015]
As illustrated in Fig. 1, in the hermetically sealed compressor 100 according to15
Embodiment 1, a compression mechanism 20 and an electric motor 30 are housed in a
cylindrical hermetically sealed container 10. The compression mechanism 20 is
configured to compress refrigerant gas. The electric motor 30 is configured to drive the
compression mechanism 20. The hermetically sealed container 10 is made up of an
upper container 11 and a lower container 12. The compression mechanism 20 is20
provided in a lower portion of the hermetically sealed container 10, and the electric
motor 30 is provided in an upper portion of the hermetically sealed container 10. The
compression mechanism 20 and the electric motor 30 are connected by a rotation shaft
21. The rotation shaft 21 transmits rotational motion of the electric motor 30 to the
compression mechanism 20. In the compression mechanism 20, refrigerant gas is25
compressed by a transmitted rotational force, and then discharged to the interior of the
hermetically sealed container 10. The interior of the hermetically sealed container 10
is filled with high-temperature and high-pressure refrigerant gas obtained through
compression. In the lower portion of the hermetically sealed container 10, that is, at
the bottom portion thereof, refrigerating machine oil is stored for lubrication of the30
9
compression mechanism 20. At a lower portion of the rotation shaft 21, an oil pump
(not illustrated) is provided. As the rotation shaft 21 rotates, the oil pump pumps up the
refrigerating machine oil stored in the bottom portion of the hermetically sealed
container 10, and supplies the refrigerating machine oil to sliding parts of the
compression mechanism 20, thereby ensuring a mechanical lubricating action of the5
compression mechanism 20. At an upper portion of the hermetically sealed container
10, a glass terminal 48 is provided as a terminal to which an external power supply (not
illustrated) is connected. The glass terminal 48 is electrically connected to the electric
motor 30 through a power line 47.
[0016]10
The rotation shaft 21 includes a main shaft portion 21a, an eccentric shaft portion
21b, and a sub-shaft portion 21c. The main shaft portion 21a, the eccentric shaft
portion 21b, and the sub-shaft portion 21c are arranged in this order from the upper side
its axial direction. The axial direction corresponds to the longitudinal direction of each
of the hermetically sealed container 10 and the rotation shaft 21. The electric motor 3015
is fixed to the main shaft portion 21a by shrink fit or press fit. A cylindrical rolling piston
22 is slidably fitted to the eccentric shaft portion 21b.
[0017]
As illustrated in Figs. 1 and 2, the compression mechanism 20 includes the rolling
piston 22, a cylinder 23, an upper bearing 24, a lower bearing 25, and a vane 26. In20
the cylinder 23, a cylindrical space is provided such that both ends thereof in the axial
direction are opened, that is, a cylinder chamber 23a is provided. The cylinder
chamber 23a houses the eccentric shaft portion 21b of the rotation shaft 21, the rolling
piston 22, and the vane 26. The eccentric shaft portion 21b performs eccentric motion
in the cylinder chamber 23a. The rolling piston 22 is fitted to the eccentric shaft portion25
21b. The vane 26 partitions a space defined by an inner circumference of the cylinder
23 and an outer circumference of the rolling piston 22.
[0018]
In the cylinder 23, a vane groove 23c is formed such that one of ends thereof is
opened in the cylinder chamber 23a and the other is an end at which a back pressure30
10
chamber 23b is provided. In the vane groove 23c, the vane 26 is accommodated.
The vane 26 moves back and forth in the radial direction in the vane groove 23c. The
vane 26 is set in the vane groove 23c. In this state, the vane 26 is shaped in the form
of a substantially cuboid having a length that is smaller than the length of the cylinder
chamber 23a in the radial direction and that in the axial direction. In the back pressure5
chamber 23b of the vane groove 23c, a vane spring (not illustrated) is provided. In
normal cases, high-pressure refrigerant gas in the hermetically sealed container 10
flows into the back pressure chamber 23b, and a differential pressure between the
pressure of refrigerant gas in the back pressure chamber 23b and the pressure of
refrigerant gas in the cylinder chamber 23a produces a force to move the vane 26 in the10
radial direction toward the center of the cylinder chamber 23a. The vane 26 is moved
in the radial direction toward the center of the cylinder chamber 23a by the force
produced due to the differential pressure between the back pressure chamber 23b and
the cylinder chamber 23a and by a pressing force of the vane spring in the radial
direction. The force to move the vane 26 in the radial direction brings one end of the15
vane 26, that is, an end portion of the vane 26 that adjoins the cylinder chamber 23a,
into contact with the outer circumference of the rolling piston 22. As a result, the space
defined by the inner circumference of the cylinder 23 and the outer circumference of the
rolling piston 22 can be partitioned into sub-spaces. Even when the pressure of
refrigerant gas in the hermetically sealed container 10, that is, a differential pressure20
between the pressure of the refrigerant gas in the back pressure chamber 23b and the
pressure the refrigerant gas in the cylinder chamber 23a, is not sufficient to press the
vane 26 against the outer circumference of the rolling piston 22, it is still possible to
press one end of the vane 26 against the outer circumference of the rolling piston 22 by
using the force of the vane spring. Thus, one end of the vane 26 can necessarily be25
brought into contact with the outer circumference of the rolling piston 22.
[0019]
As illustrated in Fig. 1, the upper bearing 24 is fitted to the main shaft portion 21a
of the rotation shaft 21 to rotatably support the main shaft portion 21a, and close one
opening portion of the cylinder chamber 23a in the axial direction. Similarly, the lower30
11
bearing 25 is fitted to the sub-shaft portion 21c of the rotation shaft 21 to rotatably
support the sub-shaft portion 21c, and close the other opening portion of the cylinder
chamber 23a in the axial direction. The upper bearing 24 has a substantially inverted
T-shape as viewed side-on. The lower bearing 25 has a substantially T-shape as
viewed side-on. The cylinder 23 is provided with a suction port (not illustrated) through5
which the refrigerant gas is sucked into the cylinder chamber 23a from the outside of
the hermetically sealed container 10. The upper bearing 24 is provided with a
discharge port (not illustrated) through which the compressed refrigerant gas is
discharged to the outside of the cylinder chamber 23a.
[0020]10
At the discharge port of the upper bearing 24, a discharge valve (not illustrated) is
provided. The discharge valve controls the timing of discharging high-temperature and
high-pressure refrigerant gas from the cylinder 23 through the discharge port. To be
more specific, the discharge valve is kept closed until the pressure of refrigerant gas
that is compressed in the cylinder chamber 23a of the cylinder 23 reaches a15
predetermined pressure. When the pressure of the refrigerant gas reaches the
predetermined pressure or higher, the discharge valve is opened to allow the high-
temperature and high-pressure refrigerant gas to be discharged to the outside of the
cylinder chamber 23a.
[0021]20
In the cylinder chamber 23a, suction, compression, and discharge are repeated.
Thus, the refrigerant gas is intermittently discharged from the discharge port, thus
causing noise such as pulsation noise. In order to reduce this noise, a discharge
muffler 27 is provided on an outer side of the upper bearing 24, that is, on a side of the
upper bearing 24 that faces the electric motor 30, such that the discharge muffler 2725
covers the upper bearing 24. The discharge muffler 27 has a discharge hole (not
illustrated) through which a space defined by the discharge muffler 27 and the upper
bearing 24 communicates with the interior of the hermetically sealed container 10.
Refrigerant gas to be discharged from the cylinder 23 through the discharge port is once
discharged to the space defined by the discharge muffler 27 and the upper bearing 24,30
12
and is then discharged from the discharge hole into the hermetically sealed container
10.
[0022]
Beside the hermetically sealed container 10, a suction muffler 101 is provided to
prevent liquid refrigerant from being directly sucked into the cylinder chamber 23a of the5
cylinder 23. In general, the hermetically sealed compressor 100 is supplied with a
mixture of low-pressure refrigerant gas and liquid refrigerant from a refrigerant circuit to
which the hermetically sealed compressor 100 is connected. When the liquid
refrigerant flows into the cylinder 23 and is compressed in the compression mechanism
20, this causes occurrence of a failure in the compression mechanism 20. Therefore,10
in the suction muffler 101, the refrigerant gas is separated from the liquid refrigerant,
and only this refrigerant gas is sent to the cylinder chamber 23a. The suction muffler
101 is connected to the suction port of the cylinder 23 by a suction connection pipe
101a. Low-pressure refrigerant gas that is sent from the suction muffler 101 is sucked
into the cylinder chamber 23a through the suction connection pipe 101a.15
[0023]
The compression mechanism 20 is configured as described above, and the
eccentric shaft portion 21b of the rotation shaft 21 is rotated in the cylinder chamber 23a
of the cylinder 23 by the rotational motion of the rotation shaft 21. An operating
chamber is defined by the inner circumference of the cylinder 23, the outer20
circumference of the rolling piston 22 fitted to the eccentric shaft portion 21b, and the
vane 26. The volume of the operating chamber increases or decreases as the rotation
shaft 21 rotates. First, the operating chamber communicates with the suction port, and
low-pressure refrigerant gas is then sucked into this operating chamber. Next, the
communication between the operating chamber and the suction port is blocked, and as25
the volume of the operating chamber decreases, refrigerant gas in the operating
chamber is compressed. Finally, the operating chamber communicates with the
discharge port, and after the pressure of the refrigerant gas in the operating chamber
reaches a predetermined pressure, the discharge valve provided at the discharge port is
opened, and the refrigerant gas compressed to be in a high-pressure and high-30
13
temperature state is discharged to the outside of the operating chamber, that is, the
outside of the cylinder chamber 23a. The high-pressure high-temperature refrigerant
gas discharged from the cylinder chamber 23a through the discharge muffler 27 to the
interior of the hermetically sealed container 10 passes through the electric motor 30,
then flows up in the hermetically sealed container 10, and is discharged to the outside5
of the hermetically sealed container 10 from a discharge pipe 102 provided on the upper
portion of the hermetically sealed container 10. The refrigeration circuit in which the
refrigerant flows is provided outside the hermetically sealed container 10. The
discharged refrigerant circulates in the refrigeration circuit and flows back to the suction
muffler 101.10
[0024]
Fig. 3 is a schematic configuration diagram of a refrigeration cycle apparatus 200,
such as an air-conditioning apparatus, to which the hermetically sealed compressor 100
is connected. As illustrated in Fig. 3, the refrigeration cycle apparatus 200 includes the
hermetically sealed compressor 100, the suction muffler 101 connected to the suction15
side of the hermetically sealed compressor 100, a four-way switching valve 103
connected to the discharge side of the hermetically sealed compressor 100 to switch
the flow direction of refrigerant that flows from the hermetically sealed compressor 100,
an outdoor-side heat exchanger 104, a pressure reducing device 105 such as an
electric expansion valve, and an indoor-side heat exchanger 106. These components20
are sequentially connected by pipes, whereby the refrigeration circuit is formed. It
should be noted that in general, in an air-conditioning apparatus, the indoor-side heat
exchanger 106 is provided in an indoor apparatus, while the hermetically sealed
compressor 100, the suction muffler 101, the four-way switching valve 103, the outdoor-
side heat exchanger 104, and the pressure reducing device 105 are provided in an25
outdoor apparatus.
[0025]
In heating operation of the refrigeration cycle apparatus 200, the four-way
switching valve 103 is connected to the indoor-side heat exchanger 106 as indicated by
solid lines in Fig. 3. High-temperature and high-pressure refrigerant obtained through30
14
compression by the hermetically sealed compressor 100 flows to the indoor-side heat
exchanger 106, and condenses and liquefies to change into liquid refrigerant.
Thereafter, this liquid refrigerant is reduced in pressure by the pressure reducing device
105 to change into low-temperature and low-pressure two-phase refrigerant.
Thereafter, the low-temperature and low-pressure two-phase refrigerant flows to the5
outdoor-side heat exchanger 104, and evaporates and gasifies to change into gas
refrigerant. The gas refrigerant passes through the four-way switching valve 103 and
the suction muffler 101 and flows back to the hermetically sealed compressor 100.
That is, the refrigerant circulates in such a manner as indicated by solid arrows in Fig. 3.
Because of this circulation of the refrigerant, the outdoor-side heat exchanger 104 that10
serves as an evaporator causes heat exchange to be performed between the refrigerant
and outside air, and the refrigerant sent to the outdoor-side heat exchanger 104
receives heat from the outside air. The refrigerant that has received heat is sent to the
indoor-side heat exchanger 106 that serves as a condenser, and exchanges heat with
indoor air to heat the indoor air.15
[0026]
In cooling operation of the refrigeration cycle apparatus 200, the four-way
switching valve 103 is connected to the outdoor-side heat exchanger 104 as indicated
by dotted lines in Fig. 3. High-temperature and high-pressure refrigerant obtained
through compression by the hermetically sealed compressor 100 flows to the outdoor-20
side heat exchanger 104 and condenses and liquefy to change into liquid refrigerant.
Thereafter, this liquid refrigerant is reduced in pressure by the pressure reducing device
105 to change into low-temperature and low-pressure two-phase refrigerant.
Thereafter, the low-temperature and low-pressure two-phase refrigerant flows to the
indoor-side heat exchanger 106 and evaporates and gasifies to change into gas25
refrigerant. The gas refrigerant passes through the four-way switching valve 103 and
the suction muffler 101 and flows back to the hermetically sealed compressor 100.
[0027]
To be more specific, when the operation is changed from the heating operation to
the cooling operation, the indoor-side heat exchanger 106 operating as a condenser30
15
changes to operate an evaporator, and the outdoor-side heat exchanger 104 operating
as an evaporator changes to operate as a condenser. As a result, the refrigerant
circulates in such a manner as indicated by dashed arrows in Fig. 3. Because of this
circulation of the refrigerant, at the indoor-side heat exchanger 106 operating as an
evaporator, the refrigerant exchanges heat with indoor air, and receives heat from the5
indoor air, thereby cooling the indoor air. The refrigerant that has received heat is sent
to the outdoor-side heat exchanger 104 serving as a condenser, and exchanges heat
with outside air and transfer heat to the outside air.
[0028]
In this case, R407C refrigerant, R410A refrigerant, R32 refrigerant, or another10
kind of refrigerant is used as refrigerant that flows in the refrigeration circuit.
[0029]
Fig. 4 is a cross-sectional view of the hermetically sealed compressor 100 that is
taken along line B-B' in Fig. 1, as viewed from above. Next, the electric motor 30
configured to transmit a rotational force to the compression mechanism 20 will be15
described. As illustrated in Fig. 4, the electric motor 30 includes a substantially
cylindrical stator 41 having a substantially cylindrical shape and fixed to the inner
circumference of the hermetically sealed container 10, and a substantially columnar
rotor 31 having a substantially columnar shape and located inward of the stator 41.
[0030]20
The rotor 31 includes a rotor iron core 32 that is formed such that core sheets
stamped out from a thin electromagnetic steel sheet are stacked together. As the rotor
31, a rotor using permanent magnets like a blushless DC motor or a rotor using
secondary winding like an induction motor is used. For example, in the case where the
electric motor 30 is such a blushless DC motor as illustrated in Fig. 4, magnet insertion25
holes 33 are provided in the axial direction of the rotor iron core 32, and in the magnet
insertion holes 33, permanent magnets 34 such as ferrite magnets or rare-earth
magnets are inserted. The permanent magnets 34 form magnetic poles on the rotor
31. Magnetic fluxes generated by the magnetic poles on the rotor 31 and magnetic
fluxes generated by windings 44 on the stator 41 effect rotation of the rotor 31. The30
16
winding 44 will be described later. In the case where the electric motor 30 is an
induction motor (not illustrated), secondary windings are provided on the rotor iron core
32, instead of the permanent magnets. The windings 44 on the stator 41 induce the
magnetic fluxes to the secondary windings on the rotor 31 to generate a rotational force
that causes the rotor 31 to rotate.5
[0031]
At the center of the rotor iron core 32, a shaft hole (not illustrated) is provided
through which the rotation shaft 21 extends. The main shaft portion 21a of the rotation
shaft 21 is fastened to the rotor iron core 32 by, for example, shrink fit. Thus, the
rotational motion of the rotor 31 is transmitted to the rotation shaft 21. Around the shaft10
hole, air holes 35 are provided. High-pressure and high-temperature refrigerant
obtained through compression by the compression mechanism 20 located below the
electric motor 30 passes through the air holes 35. It should be noted that the
refrigerant compressed by the compression mechanism 20 also passes through an air
space between the rotor 31 and the stator 41 and a gap between the windings 44, in15
addition to the air holes 35.
[0032]
Fig. 5 is an annular plan view of the stator 41 according to Embodiment 1. Fig. 6
is a plan view of a stator core 40 of the stator 41 according to Embodiment 1. Fig. 7 is
a plan view of a stator iron core piece (first core part 61) of the stator 41 according to20
Embodiment 1. Fig. 8 is a plan view of a stator iron core piece (second core part 62) of
the stator 41 according to Embodiment 1. Fig. 9 is a sectional view of a laminated
structure of stator iron cores 42 of the stator 41 according to Embodiment 1. Fig. 10 is
a plan view of C-shaped stator cores 40 of the stator 41 according to Embodiment 1.
Fig. 11 is a plan view of the C-shaped stator cores 40 of the stator 41 according to25
Embodiment 1 before winding. Fig. 12 is a perspective view of the C-shaped stator 41
according to Embodiment 1 before winding. Fig. 13 is a perspective view of the C-
shaped stator 41 according to Embodiment 1 after winding. Fig. 14 is a plan view of
the C-shaped stator 41 according to Embodiment 1 after winding. Fig. 15 is a
perspective view of the stator 41 annularly shaped according to Embodiment 1 after30
17
winding. Fig. 16 is a flowchart indicating a manufacturing method of the stator 41
according to Embodiment 1. Fig. 17 is a plan view of an insulator 43a of the stator 41
according to Embodiment 1. Fig. 18 is a perspective view illustrating a method of
laying connecting wires 80 of the stator 41 according to Embodiment 1. Fig. 19 is a
perspective view illustrating a process of performing winding at the stator 41 according5
to Embodiment 1. Fig. 20 is a schematic explanatory view illustrating a process of
performing winding at a stator 71 of a comparative example. Fig. 21 is a sectional view
of the insulator 43a of the stator 41 according to Embodiment 1. Fig. 22 is a partially-
enlarged perspective view of the stator 41 according to Embodiment 1. Fig. 23 is a
sectional view of an upper portion of the stator 41 that is taken along an up-down10
direction at a portion of the stator 41 that is indicated by an arrow B in Fig. 22. Fig. 24
is a sectional view of the upper portion of the stator 41 that is taken along the up-down
direction at a portion of the stator 41 that is indicated by an arrow C in Fig. 22. Fig. 25
is a plan view illustrating the process of performing winding at the stator 41 according to
Embodiment 1. Fig. 26 is a sectional view of another configuration of insulators 43a15
and 43b in the stator 41 according to Embodiment 1. It should be noted that although
Figs. 17 and 21 and Figs. 23 to 26 illustrate the insulator 43a only, the insulator 43b has
the same configuration as the insulator 43a.
[0033]
Next, the configuration of the stator 41 will be described in detail. As illustrated20
in Figs. 5, 6, and 17, the stator iron cores 42 are provided with the insulators 43a and
43b that insulate the stator iron cores 42 from the windings 44. The insulators 43a are
provided on the upper sides of the stator iron cores 42. The insulators 43b are
provided on the lower sides of the stator iron cores 42. Back yokes 45 are fixed to an
inner circumferential surface of the hermetically sealed container 10, and extend in a25
circumferential direction of the hermetically sealed container 10. Teeth 46 protrude
inwardly in the radial direction from the centers of inner circumferential surfaces of the
respective back yokes 45 in the circumferential direction. The windings 44 are wound
around the teeth 46 through the insulators 43a and 43b. As illustrated in Figs. 17, 18,
and 22, the insulators 43a and 43b include end-face insulating portions 43a1 and 43b1,30
18
inner flange portions 43a2 and 43b2, and outer flange portions 43a3 and 43b3,
respectively. The end-face insulating portions 43a1 and 43b1 cover end faces of the
stator iron cores 42 in the axial direction. The inner flange portions 43a2 and 43b2
project from inner-circumferential-side end portions of the end-face insulating portions
43a1 and 43b1, respectively, toward circumferentially opposite sides, and extend in the5
axial direction away from the stator iron cores 42. The outer flange portions 43a3 and
43b3 project from outer-circumferential-side end portions of the end-face insulating
portions 43a1 and 43b1, respectively, toward circumferentially opposite sides, and
extend in the axial direction away from the stator iron cores 42. The windings 44 are
three windings 44 that are wound for respective U-, V-, and W-phases, and are wound10
continuously around a plurality of teeth 46. Therefore, as illustrated in Fig. 18, the
connecting wires 80 that connects the teeth 46 are laid along surfaces on the outer
circumferential side of the outer flange portions 43a3 and 43b3 of the insulators 43a and
43b.
[0034]15
The outer flange portions 43a3 and 43b3 protrude inwardly in the radial direction
relative to the stator iron core 42. The outer flange portions 43a3 and 43b3 have, on
their outer circumferential surfaces (surfaces located opposite to the rotation shaft 21),
set portions 50 on which the connecting wires 80 extending from the windings 44 are
set. Furthermore, as illustrated in Fig. 19, the outer flange portions 43a3 and 43b320
have, on the inner circumferential surfaces (surfaces located opposite to the rotation
shaft 21), recessed insulator portions 49 that are curved surfaces gradually deeper from
circumferentially opposite ends toward the center in the circumferential direction.
Since the recessed insulator portions 49 are formed curvedly, formability of the
insulators 43a and 43b at the time of forming the insulators 43a and 43b by injection25
molding can be improved, as compared with the case where the recessed insulator
portion 49 are formed in the shape of a square recess. As illustrated in Fig. 17, the
recessed insulator portion 49 has a width W1 in the circumferential direction that is
greater than a width W2 of each of the end-face insulating portions 43a1 and 43b1 in
19
the circumferential direction and smaller than a width W3 of each of the outer flange
portions 43a3 and 43b3 in the circumferential direction.
[0035]
Where an end portion of the recessed insulator portion 49 that is far from the
stator iron core 42 in the axial direction is a first end portion E1, and an end portion of5
each of the inner flange portions 43a2 and 43b2 that is far from the stator iron core 42 in
the axial direction is a second end portion E2, as illustrated in Fig. 21, the first end
portion E1 is farther from the stator iron core 42 than the second end portion E2.
Where an end portion of the recessed insulator portion 49 that is closer to the stator iron
core 42 in the axial direction is a third end portion E3, and the third end portion E3 is10
closer to the stator iron core 42 than the second end portion E2 of each of the inner
flange portions 43a2 and 43b2. A stepped portion G is formed at a boundary between
the third end portion E3 of the recessed insulator portion 49 and the inner
circumferential surface of the outer flange portions 43a3 and 43b3.
[0036]15
As illustrated in Fig. 6, the stator core 40 includes a plurality of stator iron cores
42. The stator iron cores 42 are divided cores and each includes the tooth 46 and the
back yoke 45. The stator iron cores 42 are plate-like core pieces formed of magnetic
material. The teeth 46 are formed in such a manner as to protrude toward the rotation
shaft 21. The plurality of stator iron cores 42 are connected annularly, thereby forming20
the stator core 40.
[0037]
The stator iron cores 42 are made up of first core parts 61 and second core parts
62. As illustrated in Fig. 7, the first core parts 61 are a plurality of core pieces
continuously arranged through end faces 60c and 60d. As illustrated in Fig. 8, the25
second core parts 62 are a plurality of core pieces continuously arranged through the
end faces 60c and 60d. Each of the core pieces of the first core parts 61 has a stator
iron core protruding portion 60a and a stator iron core recessed portion 60b (see Fig. 9)
formed on top and back sides of a one-end-side edge portion as coupling means (that
is, a coupling mechanism). Each of the core pieces of the second core parts 62 has30
20
the stator iron core protruding portion 60a and the stator iron core recessed portion 60b
(see Fig. 9) formed on top and back sides of the other-end-side edge portion as
coupling means (that is a coupling mechanism). The stator iron core recessed portions
60b of the first core part 61 and the second core part 62 are formed on the back side of
the stator iron core protruding portions 60a as illustrated in Fig. 9. On one end side of5
each of the first core part 61 and the second core part 62, the end face 60c is formed in
the shape of a protruding arc around the stator iron core protruding portion 60a and the
stator iron core recessed portion 60b. On the other end side of each of the first core
part 61 and the second core part 62, the end face 60d is formed in the shape of a
recessed arc that can be fitted to the end face 60c of an associated adjacent core piece.10
[0038]
As illustrated in Fig. 9, the first core parts 61 and the second core parts 62 are
alternately laminated such that positions located between the core pieces of the first
core parts 61 (that is, positions located between the stator iron core protruding portions
60a and the stator iron core recessed portions 60b) are shifted in the longitudinal15
direction (the lateral direction in Fig. 9) from positions located between the core pieces
of the second core parts 62 (that is, the positions between the stator iron core
protruding portions 60a and the stator iron core recessed portions 60b), and edge
portions of the core pieces that are adjacent to each other in a lamination direction in
which the core pieces are laminated overlap with each other. The edge portions of the20
core pieces that are adjacent to each other in the lamination direction are rotatably
coupled with each other, since the stator iron core protruding portions 60a and the stator
iron core recessed portions 60b at the one-end-side edge portions of the core pieces of
the first core parts 61 are fitted to the stator iron core protruding portions 60a and the
stator iron core recessed portion 60b at the other-end-side edge portions of the core25
piece of the second core part 62.
[0039]
The stator iron cores 42, at the edge portions of the core pieces adjacent to each
other in the lamination direction, are rotatably coupled with each other, since the stator
iron core protruding portions 60a and the stator iron core recessed portions 60b at the30
21
one-end-side edge portions of the core pieces of the first core parts 61 are fitted to the
stator iron core protruding portions 60a and the stator iron core recessed portions 60b
at the other-end-side edge portions of the core piece of the second core parts 62.
Furthermore, as illustrated in Fig. 10, the stator iron cores 42 are open at stator
circumferential end portions 52 and 53. Thus, it is possible to vary the widths of slot5
openings 54 that are spacings between inner circumferential portions of adjacent teeth
46 of the stator iron cores 42.
[0040]
Next, the manufacturing method of the stator 41 will be described with reference
to Fig. 16.10
First, a winding process of performing winding is carried out. In the winding
process, the plurality of stator iron cores 42 connected annularly are arranged in a C-
shape that is open at one point, whereby the spacings between the teeth 46 are
increased, and winding is simultaneously wound around a plurality of adjacent teeth,
using a plurality of winding nozzles 90.15
[0041]
Specifically, as illustrated in Figs. 10 and 11, prior to the winding, the stator core
40 is deformed to have a C-shape and is fixed, such that slot openings 54 that are the
spacings between inner circumferential portions of a plurality of teeth 46 (three teeth 46
in Figs. 10 and 11) around which windings 44 are to be wound and inner circumferential20
portions of teeth 46 adjacent to the above teeth 46 are widened relative to slot openings
54 that are the spacings between inner circumferential portions of the other teeth 46
adjacent to each other (step S1 in Fig. 16).
[0042]
Next, as illustrated in Fig. 14, the winding nozzles 90 are inserted from the25
widened slot openings 54, and the windings 44 are wound around the plurality of
adjacent teeth 46 (the three teeth 46 in Figs. 10 and 11). Each of these slot openings
54 has a width that is greater than or equal to the outside diameter of each of the
winding nozzles 90 that is greater than or equal to the diameter of each of the windings
22
44 × 1.5 + 0.6 mm. After the windings 44 are wound around the plurality of adjacent
teeth 46, the stator is brought into a state illustrated in Fig. 13 (step S2 in Fig. 16).
[0043]
It should be noted that in the winding process of step S2 in Fig. 16, in the case of
winding windings 44 that are to be in contact with portions of the insulators 43a and 43b5
that are located opposite to the back yokes 45, the winding nozzles 90 are made to
pass through the recessed insulator portions 49. Thus, the windings 44 can be
brought into tight contact with the above portions of the insulators 43a and 43b that are
located opposite to the back yokes 45, thereby improving winding density.
[0044]10
The improvement of the winding density will be described in detail. Fig. 19
illustrates the back yokes 45 and the insulators 43a and 43b according to Embodiment
1. The recessed insulator portions 49 are formed at respective inner circumferential
surfaces of the outer flange portions 43a3 and 43b3 of the insulators 43a and 43b. In
contrast, Fig. 20 illustrates the back yokes 45 and the insulators 43a in a comparative15
example. No recessed insulator portions 49 are formed at the outer flange portions
43a3 and 43b3 of the insulators 43a and 43b.
[0045]
In the manufacturing method of the stator 41 as illustrated in Fig. 19 and Figs. 22
to 25, that is, in the manufacturing method of the stator 41 according to Embodiment 1,20
the windings 44 to be in contact with the portions of the insulators 43a and 43b that are
located opposite to the back yokes 45 are wound such that the distal ends of the
winding nozzles 90 pass through the inside of the recessed insulator portion 49, while
laying the windings 44 led out from the distal ends of the winding nozzles 90, along the
stepped portion G. It is therefore possible to bring the windings 44 into tight contact25
with the portions of the insulators 43a and 43b that are located opposite to the back
yokes 45, thereby improving the winding density.
[0046]
The improvement of the winding density will be described in further detail. As
illustrated in Fig. 24, the windings 44 are wound after the distal end of the winding30
23
nozzle 90 passes through the inside of the recessed insulator portion 49, while laying
the winding 44 led out from the distal end of the winding nozzle 90, along the stepped
portion G, such that the distal end of the winding nozzle 90 is located closer to the stator
iron core 42 than the first end portion E1 and farther from the stator iron core 42 than
the second end portion E2. Therefore, as compared with the case where the winding5
44 is wound after the distal end of the winding nozzle 90 is moved to a position farther
from the stator iron core 42 than the first end portion E1, the length of part of the
winding 44 from the distal end of the winding nozzle 90 to the insulators 43a and 43b is
reduced. As a result, it is possible to more appropriately bring the winding 44 into tight
contact with the portions of the insulators 43a and 43b that are located opposite to the10
back yokes 45.
[0047]
It should be noted that as illustrated in Fig. 24, unless a recess depth D of the
recessed insulator portion 49 (a length of the recessed insulator portion 49 in the
direction length) is greater than or equal to the diameter of the winding 44 × 1.5, it is not15
possible to bring the winding 44 into tight contact with the portions of the insulators 43a
and 43b that are located opposite to the back yokes 45, even though the distal end of
the winding nozzle 90 is made to pass through the inside of the recessed insulator
portion 49. Therefore, the recess depth D of the recessed insulator portion 49 is set
greater than or equal to the diameter of the winding 44 × 1.5. It should be noted that20
the insulator 43b is formed to have the same configuration as the insulator 43a as
described above, and its description will thus be omitted.
[0048]
As illustrated in Fig. 24, unless the distance between the third end portion E3 of
the recessed insulator portion 49 that is closer to the stator iron core 42 in the axial25
direction and the end-face insulating portions 43a1 and 43b1 (that is, the height H of the
stepped portion G) is greater than or equal to the diameter of the winding 44, the
winding 44 cannot be laid along the stepped portion G even though the distal end of the
winding nozzle 90 is located in the recessed insulator portion 49. That is, the winding
44 cannot be brought into tight contact with the portions of the insulators 43a and 43b30
24
that are located opposite to the back yokes 45. Therefore, the height H of the stepped
portion G is set greater than or equal to the diameter of the winding 44. It should be
noted that in Embodiment 1, although the insulators 43a and 43b are formed such that
the height H of the stepped portion G is equal to the diameter of the winding 44 × 3 as
illustrated in Fig. 24, this is not limiting. As illustrated in Fig. 26, as another5
configuration in Embodiment 1, the insulators 43a and 43b may be formed such that the
height H of the stepped portion G is equal to the diameter of the winding 44.
[0049]
In such a manner as described above, the length D of the recessed insulator
portion 49 in the radial direction is set greater than or equal to the diameter of the10
winding 44 × 1.5. It is therefore possible for a person to visually confirm the winding
state of the winding 44 with ease through a space between the recessed insulator
portion 49 and the winding 44, and thus to easily confirm the quality of the winding 44.
[0050]
The distance between the end-face insulating portions 43a1 and 43b1 and the15
third end portion E3 of the recessed insulator portion 49 that is closer to the stator iron
core 42 in the axial direction than the other end portions is set greater than or equal to
the diameter of the winding 44. As a result, while an adequate strength is maintained
at part of the outer flange portions 43a3 and 43b3 that is close to the stator iron core 42,
the person can visually confirm the winding state of the winding 44 through the space20
between the recessed insulator portion 49 and the winding 44.
[0051]
As illustrated in Fig. 25, at the inner circumferential surface of the outer flange
portions 43a3 and 43b3, the recessed insulator portion 49 is a curved surface that
gradually becomes deeper from opposite ends in the circumferential direction toward25
the center in the circumferential direction. Thus, when the distal end of the winding
nozzle 90 is made to pass through the inside of the recessed insulator portion 49 along
the curve of the recessed insulator portion 49, the winding 44 led out from the distal end
of the winding nozzle 90 can be more easily laid along the stepped portion G.
[0052]30
25
In addition, since the recessed insulator portion 49 is provided, it is possible for
the person to visually confirm the winding state of the winding 44 through the space
between the recessed insulator portion 49 and the winding 44, and thus to easily
confirm the quality of the winding 44.
[0053]5
In contrast, in the manufacturing method of the comparative example as
illustrated in Fig. 20, in the case of winding the winding 44 to be in contact with portions
of the insulators 43a and 43b that are opposite to the back yokes 45, the winding nozzle
90 is moved along a surface of an insulator 43a that is not recessed. Therefore, the
winding is wound in a loosened state around the portions of the insulators 43a and 43b10
that are opposite to the back yokes 45, as a result of which the winding density is
reduced, as compared with the case illustrated in Fig. 19.
[0054]
Next, when the winding nozzles 90 are moved from the teeth 46 on which the
winding has been finished to subsequent teeth 46, the opened part of the single body15
into which the stator iron cores 42 are connected to combine is closed to form into an
annular shape. Then, after the winding nozzles 90 are moved and the connecting
wires 80 are laid along the set portions 50, the connecting wire step of moving the
winding nozzles 90 to the subsequent teeth 46 is carried out.
[0055]20
Specifically, after the windings 44 are wound, the shape of the stator iron cores
42 is changed from the C-shape illustrated in Figs. 13 and 14 to the annular shape
illustrated in Figs. 5 and 15, and the stator iron cores 42 are fixed and kept annularly
(step S3 in Fig. 16). Thereafter, the winding nozzles 90 are moved along the surfaces
at the outer circumferential sides of the insulators 43a and 43b and the connecting wires25
80 are set along the outer circumferential sides of the insulators 43a and 43b (see Fig.
18) (in step S4 in Fig. 16).
[0056]
Next, after the connecting wires 80 are set, the stator iron cores 42 are re-
deformed from the annular shape illustrated in Figs. 5 and 15 to the C-shape illustrated30
26
in Figs. 13 and 14 and are then fixed. Thereafter, the winding 44 are wound around a
plurality of adjacent teeth 46 not yet subjected to the winding.
[0057]
After the connecting wire step ends, the winding step and the connecting wire
step are alternately repeated a predetermined number of times (step S5 in Fig. 16).5
After the winding 44 are wound around all the teeth 46 and the connecting wires 80 are
set (YES in step S5 in Fig. 16), the winding step and the connecting wire step are
completed.
[0058]
In such a manner as described above, in the stator 41 of the electric motor 3010
according to Embodiment 1, one part of a single body into which the stator iron cores 42
are connected to combine can be opened and C-shaped, and the winding 44 can be
wound in a state in which the slot openings 54 that are the spacings between the inner
circumferential portions of adjacent teeth 46 are increased in width. Thus, the range of
movement of the winding nozzles 90 is increased, and the winding density is improved.15
Furthermore, a plurality of adjacent teeth 46 are simultaneously wound using the
plurality of winding nozzles 90, thereby reducing the time required for the winding. In
the case where the diameter of the winding is large, the outer diameter of the winding
nozzle 90 is thus large. In this case, it is necessary to increase the width of the slot
openings 54. However, in the stator 41 according to Embodiment 1, since the opened20
state of the one part of the single body into which the stator iron cores 42 are combined
can easily be changed, even if the diameter of the winding is increased, it is possible to
deal with such a change. When the winding 44 to be in contact with the portions of the
insulators 43a and 43b that are opposite to the back yokes 45 is wound, the distal end
of the winding nozzle 90 is made to pass through the inside of the recessed insulator25
portion 49, while the winding 44 led out from the distal end of the winding nozzle 90 is
being laid along the stepped portion G. It is therefore possible to bring the winding 44
into tight contact with the portions of the insulators 43a and 43b that are opposite to the
back yokes 45, thus improving the winding density.
[0059]30
27
In contrast, at the time of setting the connecting wires 80, it is possible to easily
form the single body into which the stator iron cores 42 are connected to combine, into
an annular shape by closing the opened part of the single body. Since the connecting
wires 80 are laid along the annular shape, it is therefore possible to reduce the
likelihood that the connecting wires 80 will be loosened.5
[0060]
The manufacturing method of the stator 41 according to Embodiment 1 is a
manufacturing method of a stator 41 that includes: a stator core 40 including a plurality
of divided cores that are connected annularly and include respective back yokes 45 and
teeth 46, the back yokes 45 being fixed to an inner circumferential surface of a10
container having a cylindrical shape and extending in a circumferential direction of the
container, the teeth 46 protruding inwardly from inner circumferential surfaces of the
back yokes 45 in the radial direction; a winding 44 wound around the teeth 46 of the
divided cores; and insulators 43a and 43b isolating the divided cores from the winding
44. The insulators 43a and 43b have: respective end-face insulating portions 43a115
and 43b1 that cover end faces of the divided cores in an axial direction of the container;
respective inner flange portions 43a2 and 43b2 projecting in the circumferential
direction from respective inner-circumferential-side end portion of the end-face
insulating portions 43a1 and 43b1, and extending in the axial direction away from the
divided cores; and respective outer flange portions 43a3 and 43b3 projecting in the20
circumferential direction from respective outer-circumferential-side end portion of the
end-face insulating portions 43a1 and 43b1, and extending in the axial direction away
from the divided cores, each of the outer flange portions 43a3 and 43b3 having, on its
outer circumferential surface, an set portion 50 on which a connecting wire 80 extending
from the winding 44 is set, and having on its inner circumferential surface, a recessed25
insulator portion 49 having a recess, in which the recessed insulator portion 49 has a
width in the circumferential direction that is greater than the width of the end-face
insulating portions 43a1 and 43b1 in the circumferential direction, and smaller than the
width of the outer flange portions 43a3 and 43b3 in the circumferential direction. A first
end portion E1 is farther from the divided core than a second end portion E2, where the30
28
first end portion E1 is one of end portions of the recessed insulator portion 49 that is
farther from the divided core in the axial direction than the other end portion thereof, and
the second end portion E2 is one of end portions of each of the inner flange portions
43a2 and 43b2 that is farther from the divided core in the axial direction than the other
portion thereof. A third end portion E3 is closer to the divided core than the second5
end portion E2, where the third end portion E3 is one of end portions of the recessed
insulator portion 49 that is closer to the divided core in the axial direction than the above
one end portion thereof. The third end portion E3 is closer to the divided core than the
second end portion E2. A stepped portion G is provided at a boundary between the
third end portion E3 and an inner circumferential surface of the outer flange portions10
43a3 and 43b3. The manufacturing method includes: performing winding
simultaneously on adjacent ones of the teeth 46, using a plurality of winding nozzles 90,
after opening one part of a single body into which the divided cores are connected
annularly to combine, such that the single body is C-shaped, thereby increasing
distances between distances between the teeth 46; and laying the connecting wire, in15
the laying the connecting wire, each of the winding nozzles 90 is moved from one of the
teeth 46 that is subjected to winding to a subsequent one of the teeth 46, after the
opened part of the single body in which the divided cores are connected is closed such
that the single body is circularly shaped, and then the winding nozzle 90 is moved and
the connecting wire 80 is laid over the set portion 50. In the manufacturing method,20
the performing winding and the laying the connecting wire are alternately repeated, and
in the performing winding, the winding 44 to be in contact with portions of the insulators
43a and 43b that are located opposite to the back yokes 45 is wound such that a distal
end of the winding nozzle 90 is caused to pass through an inside of the recessed
insulator portion 49, while the winding 44 led out from the distal end of the winding25
nozzle 90 is being laid over the stepped portion G.
[0061]
In the manufacturing method of the stator 41 according to Embodiment 1, in the
process of performing winding, windings are wound around adjacent ones of the teeth
46 simultaneously using the winding nozzles 90, in a state in which the single body in30
29
which the divided cores are connected is opened at one portion and is C-shaped,
whereby time required for the winding can be reduced, and in the process of setting a
connecting wire, the connecting wire is laid after the single body in which the divided
cores are connected is closed to be shaped circularly, whereby it is possible to reduce
the likelihood that the connecting wire 80 will loose. In the case of winding the winding5
44 to be in contact with portions of the insulators 43a and 43b that are located opposite
to the back yokes 45, the distal end of the winding nozzle 90 is made to pass through
the inside of the recessed insulator portion 49, while the winding 44 led out from the
distal end of the winding nozzle 90 is being laid over the stepped portion G. It is
therefore possible to bring the winding 44 into tight contact with the portions of the10
insulators 43a and 43b that are located opposite to the back yokes 45, thereby
improving the winding density.
[0062]
In the manufacturing method of the stator 41 according to Embodiment 1, the
recessed insulator portion 49 is a curved surface that gradually becomes deeper from15
the opposite ends in the circumferential direction toward the center in the circumferential
direction on the inner circumferential surface of the outer flange portions 43a3 and
43b3.
[0063]
In the manufacturing method of the stator 41 according to Embodiment 1, since20
the recessed insulator portion 49 is formed into a curved shape, formability of the
insulators 43a and 43b to be formed by injection molding can be improved, as
compared with the case where the recessed insulator portion 49 is formed in the shape
of a square recess.
[0064]25
In the manufacturing method of the stator 41 according to Embodiment 1, the
length D of the recessed insulator portion 49 in the radial direction is formed greater
than or equal to the diameter of the winding 44 × 1.5, and the distance between the
third end portion E3 and the end-face insulating portions 43a1 and 43b1 is set greater
than or equal to the diameter of the winding 44.30
30
[0065]
In the manufacturing method of the stator 41 according to Embodiment 1, the
length D of the recessed insulator portion 49 c is set greater than or equal to the
diameter of the winding 44 × 1.5. As a result, the person can easily visually check a
winding state of the winding 44 through a space between the recessed insulator portion5
49 and the winding 44, and can thus easily check the quality of the winding 44. In
addition, the distance between the third end portion E3 and the end-face insulating
portions 43a1 and 43b1 is set greater than or equal to the diameter of the winding 44.
This configuration enables the person to visually check the winding state of the winding
44 through the space between the recessed insulator portion 49 and the winding 44,10
while an adequate strength is maintained at portions of the outer flange portions 43a3
and 43b3 that are close to the stator iron core 42.
[0066]
Embodiment 2
Hereinafter, Embodiment 2 will be described. However, regarding Embodiment15
2, descriptions that have already been made regarding Embodiment 1 will not be re-
made, and components that are the same as or equivalent to those in Embodiment 1
will be denoted by the same reference signs.
[0067]
A manufacturing method of the stator 41 according to Embodiment 2 will be20
described below.
In the manufacturing method of the stator 41 according to Embodiment 2, at
boundary portions between the back yokes 45 and the teeth 46 of the stator iron cores
42, the back yokes 45 and the teeth 46 form a right angle. In this regard, the
manufacturing method of the stator 41 according to Embodiment 2 is different from the25
manufacturing method of the stator 41 according to Embodiment 1.
[0068]
Next, the configuration of the stator 41 will be described in detail. As illustrated
in Figs. 5, 6, and 17, the winding 44 is wound around the teeth 46 extending from the
back yokes 45 toward the inner circumferential side of the stator 41, through the30
31
insulators 43a and 43b. As illustrated in Figs. 17, 18, and 22, the insulators 43a and
43b include the end-face insulating portions 43a1 and 43b1, the inner flange portions
43a2 and 43b2, and the outer flange portions 43a3 and 43ab, respectively. The end-
face insulating portions 43a1 and 43b1 cover end faces of the stator iron cores 42 in the
axial direction. The inner flange portions 43a2 and 42b2 project from inner-5
circumferential-side end portions of the end-face insulating portions 43a1 and 43b1,
respectively, toward opposite sides in the circumferential direction, and extend in the
axial direction away from the stator iron cores 42. The outer flange portions 43a3 and
43b3 project from outer-circumferential-side end portions of the end-face insulating
portions 43a1 and 43b1, respectively, in the circumferential direction, and extend in the10
axial direction away from the stator iron cores 42. The winding 44 is made up of three
windings 44 to be wound for respective U-, V-, and W-phases, and is wound
continuously around the plurality of teeth 46. Therefore, as illustrated in Fig. 18, the
connecting wires 80 that connect the teeth 46 are arranged along surfaces on the outer
circumferential side of the outer flange portions 43a3 and 43b3 of the insulators 43a and15
43b.
[0069]
The outer flange portions 43a3 and 43b3 protrude toward the axial direction
relative to the stator iron cores 42. Each of the outer flange portions 43a3 and 43b3
has, on its outer circumferential surface (that is located opposite to the rotation shaft20
21), the set portions 50 on which the connecting wires 80 extending from the winding 44
are set. Furthermore, as illustrated in Fig. 19, each of the outer flange portions 43a3
and 43b3 has, on its inner circumferential surface (that faces the rotation shaft 21), the
recessed insulator portion 49 that is a curved surface gradually deeper from opposite
ends in the circumferential direction toward the center in the circumferential direction.25
Since the recessed insulator portion 49 is formed into a curved shape, formability of the
insulators 43a and 43b to be formed by injection molding can be improved, as
compared with the case where the recessed insulator portion 49 is formed in the shape
of a square recess. As illustrated in Fig. 17, the recessed insulator portion 49 has the
width W1 in the circumferential direction that is greater than the width W2 of the end-30
32
face insulating portions 43a1 and 43b1 in the circumferential direction, and smaller than
the width W3 of the outer flange portions 43a3 and 43b3 in the circumferential direction.
[0070]
In the stator 41 of the electric motor 30 according to Embodiment 2, the stator
iron cores 42, in which the back yokes 45 and the teeth 46 forms a right angle at the5
boundary portions between the back yokes 45 and the teeth 46, include the outer flange
portions 43a3 and 43b3 extending in the axial direction away from the stator iron cores
42. Each of the outer flange portions 43a3 and 43b3 has, on its outer circumferential
surface (that is located opposite to the rotation shaft 21), the set portion 50 on which the
connecting wires 80 extending from the winding 44 are set. Furthermore, each of the10
outer flange portions 43a3 and 43b3 has, on its inner circumferential surface (that faces
the rotation shaft 21), the recessed insulator portion 49 that is a curved surface
gradually deeper from the opposite ends in the circumferential direction, toward the
center in the circumferential direction. The stator iron cores 42 are provided with the
insulators 43a and 43b. The winding 44 is wound around the teeth 46 extending from15
the back yokes 45 toward the inner circumferential side of the stator 41, through the
insulators 43a and 43b.
[0071]
Due to this configuration, even when the stator iron cores 42, in which the back
yokes 45 and the teeth 46 form a right angle at the boundary portions between the back20
yokes 45 and the teeth 46, are used, it is still possible to wind the winding 44 such that
the distal end of the winding nozzle 90 is made to pass through the inside of the
recessed insulator portion 49, while the winding 44 led out from the distal end of the
winding nozzle 90 is being laid over the stepped portion G. As a result, it is possible to
bring the winding 44 into contact with portions of the insulators 43a and 43b that are25
located opposite to the back yokes 45.
[0072]
In Embodiment 2, it is possible to use the stator iron cores 42 in which the back
yokes 45 and the teeth 46 form a right angle at the boundary portions between the back
yokes 45 and the teeth 46, thus reducing an iron loss. It is therefore possible to30
33
achieve a high-efficiency electric motor 30. It should be noted that in the related art,
the back yokes 45 and the teeth 46 do not form a right angle at the boundary portions
between the back yokes 45 and the teeth 46, that is, the boundary portions are formed
in the shape of a circular arc, since it is necessary to ensure a path for winding by the
winding nozzle 90.5
[0073]
In the manufacturing method of the stator 41 according to Embodiment 2 as
described above, the back yokes 45 and the teeth 46 form a right angle at the boundary
portions between the back yokes 45 and the teeth 46.
[0074]10
In the manufacturing method of the stator 41 according to Embodiment 2, since
the back yokes 45 and the teeth 46 form a right angle at the boundary portions between
the back yokes 45 and the teeth 46, thus reducing an iron loss. It is therefore possible
to achieve a high-efficiency electric motor 30.
[0075]15
It should be noted that in Embodiments 1 and 2, the stator iron cores 42 have
nine teeth 46, and the winding 44 is wound around three adjacent ones of teeth 46
using three winding nozzles 90; however, this is not limiting. Even in other
configurations regarding a combination of the number of teeth 46 and the number of
winding nozzles 90 (for example, even in the case where the number of teeth 46 is 3n20
(n≥2) and the number of winding nozzles 90 is 3n (n≥1)), it is possible to obtain the
same advantages as in Embodiments 1 and 2.
Reference Signs List
[0076]
10: hermetically sealed container, 11: upper container, 12: lower container, 20:25
compression mechanism, 21: rotation shaft, 21a: main shaft portion, 21b: eccentric
shaft portion, 21c: sub-shaft portion, 22: rolling piston, 23: cylinder, 23a: cylinder
chamber, 23b: back pressure chamber, 23c: vane groove, 24: upper bearing, 25: lower
bearing, 26: vane, 27: discharge muffler, 30: electric motor, 31: rotor, 32: rotor ion core,
33: magnet insertion hole, 34: permanent magnet, 35: air hole, 40: stator core, 41:30
34
stator, 42: stator iron core, 43a: insulator, 43a1: end-face insulating portion, 43a2: inner
flange portion, 43a3: outer flange portion, 43b: insulator, 43b1: end-face insulating
portion, 43b2: inner flange portion, 43b3: outer flange portion, 44: winding, 45: back
yoke, 46: tooth, 47: power line, 48: glass terminal, 49: recessed insulator portion, 50: set
portion, 52: stator circumferentially end portion, 53: stator circumferentially end portion,5
54: slot opening, 60a: stator iron core protruding portion, 60b: stator iron core recessed
portion, 60c: end face, 60d: end face, 61: first core part, 62: second core part, 70: stator,
71: stator, 80: connecting wire, 90: winding nozzle, 100: hermetically sealed
compressor, 101: suction muffler, 101a: suction connection pipe, 102: discharge pipe,
103: four-way switching valve, 104: outdoor-side heat exchanger, 105: pressure10
reducing device, 106: indoor-side heat exchanger, 200: refrigeration cycle apparatus
35
We Claim :
[Claim 1]
A manufacturing method of a stator that includes
a stator core including a plurality of divided cores that are connected
annularly and include respective back yokes and teeth, the back yokes being fixed to an5
inner circumferential surface of a container having a cylindrical shape and extending in
a circumferential direction of the container, the teeth protruding inwardly from inner
circumferential surfaces of the back yokes in a radial direction,
a winding wound around the teeth of the divided cores, and
insulators insulating the divided cores from the winding,10
wherein each of the insulators includes
an end-face insulating portion covering an end face of an associated one of
the divided cores in an axial direction of the container,
an inner flange portion projecting in the circumferential direction from an
inner-circumferential-side end portion of the end-face insulating portion, and extending15
in a direction away from the divided core in the axial direction, and
an outer flange portion projecting in the circumferential direction from an
outer-circumferential-side end portion of the end-face insulating portion, and extending
in the axial direction away from the divided core,
wherein the outer flange portion has20
on an outer circumferential surface of the outer flange portion, a set portion
on which a connecting wire extending from the winding is set, and
on an inner circumferential surface of the outer flange portion, a recessed
insulator portion having a recess, and
wherein the recessed insulator portion has a width in the circumferential direction25
that is greater than a width of the end-face insulating portion in the circumferential
direction, and smaller than a width of the outer flange portion in the circumferential
direction,
wherein a first end portion is further form the divided core than a second end
portion, where the first end portion is one of end portions of the recessed insulator30
36
portion that is farther from the divided core in the axial direction than the other end
portion of the recessed insulator portion, and the second end portion is one of end
portions of the inner flange portion that is further from the divided core in the axial
direction than the other end portion of the inner flange portion,
wherein a third end portion is closer to the divided core than the second end5
portion, where the third end portion is the other end portion of the recessed insulator
portion that is closer to the divided core in the axial direction than the one end portion of
the recessed insulator portion, and
wherein a stepped portion is provided at a boundary between the third end
portion and an inner circumferential surface of the outer flange portion,10
the manufacturing method comprising:
performing winding simultaneously on adjacent ones of the teeth, using winding
nozzles, after opening one part of a single body into which the divided cores are
connected annularly to combine, such that the single body is C-shaped, thereby
increasing distances between the teeth; and15
laying the connecting wire, in the laying the connecting wire, each of the winding
nozzles is moved from one of the teeth that is subjected to winding to a subsequent one
of the teeth, after the opened part of the single body in which the divided cores are
connected is closed such that the single body is circularly shaped and then the winding
nozzle is moved and the connecting wire is laid over the set portion,20
wherein the performing winding and the laying the connecting wire are alternately
repeated, and
in the performing winding, the winding to be in contact with portions of the
insulators that are located opposite to the back yokes is wound such that a distal end of
the winding nozzle is caused to pass through an inside of the recessed insulator portion,25
while the winding led out from the distal end of the winding nozzle is being laid over the
stepped portion.
[Claim 2]
The manufacturing method of the stator of claim 1, wherein at the inner
circumferential surface of the outer flange portion, the recessed insulator portion is a30
37
curved surface that gradually becomes deeper from opposite ends in a circumferential
direction toward a center in the circumferential direction.
[Claim 3]
The manufacturing method of the stator of claim 1 or 2, wherein at boundary
portions between the back yokes and the teeth, the back yokes and the teeth form a5
right angle.
[Claim 4]
The manufacturing method of the stator of any one of claims 1 to 3, wherein
a length of the recessed insulator portion in a radial direction is set greater than
or equal to a diameter of the winding × 1.5, and10
a distance between the third end portion and the end-face insulating portion is set
greater than or equal to the diameter of the winding.
[Claim 5]
A stator of an electric motor, the stator being manufactured by the manufacturing
method of the stator of any one of claims 1 to 4.15
[Claim 6]
An electric motor comprising:
the stator of an electric motor of claim 5; and
a rotor of an electric motor, the rotor being provided inward of the stator.
[Claim 7]20
A hermetically sealed compressor comprising:
the electric motor of claim 6;
a compression mechanism configured to be driven by the electric motor and to
compress fluid sucked from outside; and
a hermetically sealed container housing the electric motor and the compression25
mechanism.
38
[Claim 8]
A refrigeration cycle apparatus comprising: the hermetically sealed compressor of
claim 7; an outdoor-side heat exchanger; a pressure reducing device; and an indoor-
side heat exchanger.