KR102020653B1 - Brushless DC Motor for Laundry Dryer - Google Patents

Abstract

The BLDC dryer motor according to the present invention protrudes into the stator core 21, the upper and lower insulators 22 and 23 coupled to the upper and lower portions of the stator core 21, and the stator core 21. A stator assembly 20 comprising a coil 24 wound around a plurality of teeth; A rotor assembly (40) including a main shaft (41), a rotor core (43) coupled to the main shaft (41) and positioned and rotating inside the stator assembly (20); An upper housing 10 coupled to an upper portion of the stator core 21; And a lower housing 30 coupled to a lower portion of the stator core 21, and positioned at an upper portion of the coil 24 wound on the tooth to be electrically connected to the coil 24. It further comprises a device.

Description

BLDC Dryer Motor {Brushless DC Motor for Laundry Dryer}

The present invention relates to a dryer motor. More specifically, the present invention relates to a BLDC dryer motor in which a BLDC motor is applied to a dryer to facilitate control of the motor, to cope with safety when the motor is overheated, and to increase driving efficiency of the motor.

In general, a dryer includes a drum for accommodating laundry therein, a heater for raising the temperature for drying the laundry inside the drum, a driving belt for rotating the drum, and a drum for rotating the drum by the driving belt to promote drying of the laundry. For the motor. As the motor used in such a dryer, a single phase AC motor is mainly applied. Such single phase AC motors for dryers are disclosed in US Pat. Nos. 7,609,491, 7,732,960 and the like.

On the other hand, BLDC motor is a brushless DC motor, it is easy to control the constant speed and variable speed of the motor, and has the advantage that the power density and efficiency are relatively higher than the AC motor. Therefore, if the AC motor used in the conventional dryer can be replaced with the BLDC is expected to implement a dryer with a higher efficiency.

Another advantage of the BLDC motor is that it electronically controls the operation of the motor, so when the temperature sensor is linked to the controller, it can easily cope with dangerous situations by blocking the current in the controller when the motor is overheated.

However, in the case of a device operating at a high temperature by a heater, such as a dryer, a separate safety device may be necessary rather than relying on the controller for overheating because the controller may have a slight possibility of malfunction due to high temperature.

Therefore, the present inventors propose a BLDC motor for a dryer that can block a current flowing in a coil without passing through a controller when the motor is overheated while applying a BLDC motor to the dryer.

An object of the present invention is to provide a BLDC dryer motor that can increase the operating efficiency of the dryer.

Another object of the present invention is to provide a BLDC dryer motor that can cope more safely without depending on the controller of the BLDC motor when the motor of the dryer is overheated.

The above and other inherent objects of the present invention can be easily achieved by the present invention described below.

BLDC dryer motor according to the present invention

A coil wound around a stator core 21, upper and lower insulators 22 and 23 coupled to upper and lower portions of the stator core 21, and a plurality of teeth protruding into the stator core 21. A stator assembly 20 comprising 24;

A rotor assembly (40) including a main shaft (41), a rotor core (43) coupled to the main shaft (41) and positioned and rotating inside the stator assembly (20);

An upper housing 10 coupled to an upper portion of the stator core 21; And

A lower housing 30 coupled to a lower portion of the stator core 21;

It is made, including

An overheat protection element positioned on an upper portion of the coil 24 wound around the tooth and electrically connected to the coil 24;

Characterized in that it comprises a.

In the present invention, it may further include a stator cover 28 coupled to the upper portion of the upper insulator 22 to fix the overheat protection element to the upper portion of the coil.

In the present invention, the stator cover 28 is preferably formed with a plurality of guide protrusions 28B protruding downward and positioned between the adjacent teeth and the distal side of the teeth.

In the present invention, it is preferable that a plurality of heat dissipation holes 28C are formed on the stator cover 28.

BLDC dryer motor according to another aspect of the present invention

A coil wound around a stator core 21, upper and lower insulators 22 and 23 coupled to upper and lower portions of the stator core 21, and a plurality of teeth protruding into the stator core 21. A stator assembly 20 comprising 24;

A rotor assembly (40) including a main shaft (41), a rotor core (43) coupled to the main shaft (41) and positioned and rotating inside the stator assembly (20);

An upper housing 10 coupled to an upper portion of the stator core 21;

A lower housing 30 coupled to a lower portion of the stator core 21;

A centrifugal actuator (45) coupled to the protruding side of the main shaft (41) toward the upper housing (10); And

A sliding collar (46) coupled to the upper side of the centrifugal actuator (45) and sliding in accordance with the operation of the centrifugal actuator (45);

Characterized in that comprises a.

BLDC dryer motor according to the present invention can increase the operating efficiency of the dryer, and has the effect of the invention that can cope with overheating more safely.

Figure 1 is a perspective view of the dryer motor according to the present invention from the top side.
Figure 2 is a perspective view of the dryer motor according to the present invention from the bottom side.
Figure 3 is a perspective view showing an exploded dryer motor according to the present invention.
4 is a perspective view showing the rotor assembly of the dryer motor according to the present invention.
5 is a perspective view showing a stator assembly of a dryer motor according to the present invention.
6 is a perspective view showing a state in which the stator cover is disassembled in the stator assembly of the dryer motor according to the present invention.
7 is a three-phase circuit diagram to which the overheat protection element is applied in the dryer motor according to the present invention.
Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

Figure 1 is a perspective view of the dryer motor according to the present invention from the top side, Figure 2 is a perspective view from the bottom side, Figure 3 is a perspective view showing an exploded dryer motor according to the present invention.

As shown in FIGS. 1 to 3, the dryer motor according to the present invention includes an upper housing 10, a stator assembly 20, a lower housing 30, and a rotor assembly 40.

The upper housing 10 is coupled to the top of the stator core 21 of the stator assembly 20. The upper housing 10 covers the upper portion of the stator assembly 20 to protect the upper insulator 22, the coil 24, and the like coupled to the stator core 21, and the centrifugal actuator 45 of the rotor assembly 40. Play a role. An upper bearing seat 10A protruding upward is formed at the center of the upper housing 10. The upper bearing 47 is inserted into the upper bearing seat 10A to support the rotation of the main shaft 41, and the upper shock absorbing member 11 is coupled to the outside. The upper shock absorbing member 11 uses a shock absorbing material such as rubber and serves to absorb vibration of the motor and prevent noise when the dryer motor is coupled to the dryer set.

The main shaft 41 penetrates to the center of the upper housing 10, and the pulley 42 is coupled to the upper end of the main shaft 41. One side of the upper housing 10 is formed with a roller support portion 10B protruding upward. The roller 12 is coupled to the roller support portion 10B so as to be rotatable by the roller shaft 14. The pulley 42 and the roller 12 rotate together by the drive belt 13. Rotation of the roller 12 is configured to rotate a drum (not shown) containing the laundry.

The upper housing 10 is formed with an opening portion 10C penetrating therein. In this opening 10C, a sliding collar 46 of the rotor assembly 40 is located. The switch assembly 15 is coupled to cover the opening 10C.

The lower housing 30 is coupled to the lower portion of the stator core 21 of the stator assembly 20. A lower bearing seating portion 30A protruding downward is formed at the center of the lower housing 30. The lower bearing 48 supporting the rotation of the main shaft 41 is inserted into the lower bearing seating portion 30A, and the lower buffer member 31 is coupled to the outside. The lower shock absorbing member 31 uses a cushioning material such as rubber as the upper shock absorbing member 11, and when the dryer motor is coupled to the dryer set, it serves to absorb vibration of the motor and prevent noise.

The stator assembly 20 allows the rotor assembly 40 to rotate by forming a varying magnetic field by applying a constant polarity to each tooth by the application of an external power source. Detailed configuration of the rotor assembly 40 will be described with reference to FIG. 4.

4 is a perspective view showing the rotor assembly 40 of the dryer motor according to the present invention.

Referring to FIG. 4, the rotor assembly 40 of the present invention includes a main shaft 41, a pulley 42, a rotor core 43, a rotor mold 44, a centrifugal actuator 45, a sliding collar 46, An upper bearing 47 and a lower bearing 48.

The pulley 42 is coupled to the upper end of the main shaft 41. The rotor core 43 is located at a substantially central portion of the main shaft 41 and is fixedly coupled to the main shaft 41. The rotor mold 44 is formed around the rotor core 43, and a plurality of magnets (not shown) are inserted in the rotor core 43 in the longitudinal direction. The rotor mold 44 is preferably formed by insert injection molding in a state where the main shaft 41, the rotor core 43 and the magnet are located in the injection mold.

The centrifugal actuator 45 is located on the upper side of the rotor core 43 and rotates together with the main shaft 41. The rotor core 43 is located at the center of the stator assembly 20, and when the power is applied to the stator assembly 20, the rotor core 43 rotates. As the rotor core 43 rotates, the main shaft 41 rotates, so that the centrifugal actuator 45 and the sliding collar 46 coupled to the centrifugal actuator 45 rotate together. When the centrifugal actuator 45 reaches a constant rotational speed, the centrifugal actuator 45 is operated to push the sliding collar 46 to slide upward. When the sliding collar 46 moves upward, the switch assembly 15 is mechanically operated to be installed in the dryer set to activate a heater (not shown) for raising the temperature inside the drum. When the dryer is stopped, the centrifugal actuator 45 again slides the sliding collar 46 in the opposite direction to mechanically move the heater operation switch of the switch assembly 15 off. The detailed configuration and operating principle of such a centrifugal actuator 45 is disclosed in extinct US Pat. No. 5,153,471, the contents of which may be incorporated as part of this specification to the extent necessary.

The upper bearing 47 and the lower bearing 48 are for supporting rotation of the main shaft 41 and are rotatably coupled to the upper side and the lower side of the main shaft 41, respectively. As mentioned above, the upper bearing 47 is coupled to the upper bearing seat 10A of the upper housing 10 and the lower bearing 48 is coupled to the lower bearing seat 30A of the lower housing 30.

5 is a perspective view illustrating a stator assembly 20 of a dryer motor according to the present invention, and FIG. 6 is a perspective view illustrating an exploded state of the stator cover 28 in the stator assembly 20.

5 and 6 together, the stator assembly 20 of the present invention includes a stator core 21, an upper insulator 22, a lower insulator 23, a coil 24, a power connector 25, and overheat protection. Elements 26 and 27 and stator cover 28.

The stator core 21 has a rotor core 43 of the rotor assembly 40 at the center thereof and has a plurality of teeth projecting inwardly so as to face the rotor core 43. Upper and lower insulators 22 and 23 of insulating material are coupled to the upper and lower portions of the stator core 21. Thus, the upper and lower portions of the teeth protruding into the stator core 21 are insulated by the upper and lower insulators 22 and 23, and the inner sides of the teeth are also upper and lower insulators 22 and 23 or separate insulation. It is insulated by a film or the like. Coil 24 is wound around each insulated tooth. Since the dryer motor according to the invention is a BLDC motor, each tooth is made of the winding of the coil 24 along u, v, w. The wound coil is connected to the power connector 25, and external power is supplied to the coil 24 through the power connector 25.

The thermal protectors 26 and 27 are electrically connected to the coils to block the current flowing through the coils by opening the coils when the temperature rises above a certain temperature due to an overcurrent flowing through the coils. Do it. The number of the overheat protection elements is not particularly limited, but in order to effectively cut off the current of the three-phase winding, it is preferable to apply two as shown in FIG. 6. In the present invention, as shown in Figure 6, the first overheat protection element 26 and the second overheat protection element 27 is provided. The first and second overheat protection elements 26, 27 are placed directly above the coil wound on the tooth. Accordingly, the stator cover 28 is coupled to the upper insulator 22 to fix the positions of the first and second overheat protection devices 26 and 27.

The stator cover 28 is coupled to the top of the upper insulator 22, and the first and second overheat protection elements 26 and 27 are fixed without moving between the coil 24 and the inner side of the stator cover 28. To be combined. The coupling method of the stator cover 28 and the upper insulator 22 is not specifically limited. In FIG. 6, a plurality of coupling protrusions 22A are formed on the upper insulator 22, and a coupling groove 28A is formed on the side of the stator cover 28 at a position corresponding to the coupling protrusion 22A on the side surface thereof. The method of engaging the engaging projection 22A by the hook method is applied to 28A. The number of coupling protrusions 22A and coupling grooves 28A is not particularly limited, and it is preferable to apply three or more couplings for a firm coupling.

The lower part of the stator cover 28 is provided with the guide protrusion 28B which protrudes below and is located between the ends of two adjacent teeth. The guide protrusion 28B serves to prevent the coil 24 from protruding from the tooth and the tooth. When the overheat protection element is installed in the wound coil 24, the wound coil may be loosened. If this causes the coil to protrude into the space between the teeth and the teeth, the coil may contact the rotor. Can have a serious impact on Therefore, in order to prevent this, guide protrusions 28B are formed in the stator cover 28. The number of guide protrusions 28B is not particularly limited, but preferably, the number of guide protrusions 28B is greater than the number of overheat protection elements. A plurality of heat dissipation holes 28C are formed in the upper part of the stator cover 28 to allow heat generated from the coil 24 to be discharged. The number of heat radiating holes 28C is not specifically limited, It can apply suitably according to a design environment.

7 is a three-phase circuit diagram to which overheat protection devices 26 and 27 are applied in a dryer motor according to the present invention. In FIG. 7, the overheat protection devices 26 and 27 according to the present invention electrically connect the first overheat protection device 26 to the U phase of the three-phase circuit and the second overheat protection device 27 to the V phase. Is showing. In the case of a BLDC motor, a separate temperature sensor may be installed and the current supplied to the coil may be cut off from the control circuit. However, the overheat protection devices 26 and 27 of the present invention may be electrically connected directly to the coil to directly open the coil to supply current. Since it can cut off, overheating by a control error can be prevented more reliably. In addition, it can be used as a secondary safety device by applying with the existing temperature sensor method.

It should be noted that the description of the present invention described above is merely illustrative for the purpose of understanding the present invention and is not intended to define the protection scope of the present invention. The scope of protection of the present invention is defined by the appended claims, and it should be understood that all simple modifications or variations of the present invention fall within the scope of the present invention.

10: upper housing 10A: upper bearing seat
10B: roller support portion 11: upper buffer member
12: roller 13: drive belt
14: roller shaft 15: switch assembly
20: Stator Assembly 21: Stator Core
22: upper insulator 22A: engaging projection
22B: Teeth end 23: Lower insulator
24: coil 25: power connector
26: first overheat protection element 27: second overheat protection element
28: Stator cover 28A: Coupling groove
28B: guide protrusion 28C: heat dissipation hole
30: lower housing 30A: lower bearing seat
31: lower buffer member 40: rotor assembly
41: main shaft 42: pulley
43: rotor core 44: rotor mold
45: centrifugal actuator 46: sliding collar
47: upper bearing 48: lower bearing

Claims (5)

A coil wound around a stator core 21, upper and lower insulators 22 and 23 coupled to upper and lower portions of the stator core 21, and a plurality of teeth protruding into the stator core 21. A stator assembly 20 comprising 24;
A rotor assembly (40) including a main shaft (41), a rotor core (43) coupled to the main shaft (41) and positioned and rotating inside the stator assembly (20);
An upper housing 10 coupled to an upper portion of the stator core 21;
A lower housing 30 coupled to a lower portion of the stator core 21; And
An overheat protection element positioned on an upper portion of the coil 24 wound around the tooth and electrically connected to the coil 24;
It is made, including
The coil is made of a three-phase winding, the overheat protection device is composed of a first overheat protection device 26 and a second overheat protection device 27 applied to two phases of the three-phase winding,
The first and second overheat protection elements 26, 27 are placed directly above the coil 24 wound on the tooth,
The first and second overheat protection elements are electrically connected directly to the coil (24), the BLDC dryer motor, characterized in that the current can be cut off by opening the coil directly. The method of claim 1,
And a stator cover (28) coupled to the top of the upper insulator to allow the overheat protection device to be fixed to the top of the coil. 3. The BLDC dryer motor according to claim 2, wherein the stator cover (28) is formed with a plurality of guide protrusions (28B) protruding downwardly and positioned between adjacent teeth and distal ends of the teeth. 3. The BLDC dryer motor according to claim 2, wherein a plurality of heat dissipation holes (28C) are formed on the stator cover (28). A coil wound around a stator core 21, upper and lower insulators 22 and 23 coupled to upper and lower portions of the stator core 21, and a plurality of teeth protruding into the stator core 21. A stator assembly 20 comprising 24;
A rotor assembly (40) including a main shaft (41), a rotor core (43) coupled to the main shaft (41) and positioned and rotating inside the stator assembly (20);
An upper housing 10 coupled to an upper portion of the stator core 21;
A lower housing 30 coupled to a lower portion of the stator core 21;
A centrifugal actuator (45) coupled to the protruding side of the main shaft (41) toward the upper housing (10);
A sliding collar (46) coupled to the upper side of the centrifugal actuator (45) and sliding in accordance with the operation of the centrifugal actuator (45); And
An overheat protection element positioned on an upper portion of the coil 24 wound around the tooth and electrically connected to the coil 24;
It is made, including
The coil is made of a three-phase winding, the overheat protection device is composed of a first overheat protection device 26 and a second overheat protection device 27 applied to two phases of the three-phase winding,
The first and second overheat protection elements 26, 27 are placed directly above the coil 24 wound on the tooth,
The first and second overheat protection elements are electrically connected directly to the coil (24), the BLDC dryer motor, characterized in that the current can be cut off by opening the coil directly.

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