KR20010112681A - cooling device for the driving part of a washer - Google Patents

Abstract

A method of controlling the timing of a transmission time slot within a time frame comprises transmitting information over a channel in an allocated time slot at an allocated channel frequency, measuring a received interference level at the channel frequency around the start and around the end of the time slot, analysing the measured interference levels to detect the presence or absence of interferers at the channel frequency around the start and around the end of the time slot, and, if required, adjusting the timing of subsequent time slots for the channel to reduce interference from the detected interferers. Transmission slot timing of the invention enables dynamic avoidance of interference, which can therefore avoid both intermittent and continuous interferers, and can result in synchronisation of different systems to avoid sliding interferers. This method also enables the throughput of the communication system to be largely unaffected.

Description

Cooling device for the driving part of a washer}

The present invention relates to a washing machine, and more particularly, to improve the driving unit cooling device to improve the performance of the washing machine.

In general, as shown in FIG. 1, the washing machine has a main body 1, an outer tub 2 supported by a damper 5 in the main tub, and a cylindrical shape rotatably installed in the tub and into which laundry can be put. It is largely divided into the inner tub 3, and rotational force is transmitted by the drive part 4 to wash laundry in the inner tub.

In addition, the driving unit 4 is configured such that power generated by the rotor 4a and the stator 4b is directly transmitted to the inner cylinder shaft 3a, a pulley (not shown) provided on the inner cylinder shaft 3a, and the outer tank lower end. A motor (not shown) mounted on one side is connected to each other by a belt (not shown) to transmit power generated by the motor to the inner shaft 3a, and the power is supplied to the inner shaft by various other methods. There is one configured to be delivered.

The washing machine configured as described above performs the following operation.

Put the laundry to be washed into the inner tank (3), if you select the washing mode provided in the control unit while the detergent is put in the detergent container washing is completed while washing stroke ▶ rinsing stroke ▶ dehydration stroke continuously.

That is, if the washing mode is selected, the water supply device is operated to supply water to be washed into the inner tank (3) rotatably installed in the outer tank (2), the water level sensor after the water supply is filled by the appropriate level Water supply is interrupted by (not shown), and the said drive part 4 performs forward and reverse driving repeatedly.

As described above, when the driving unit 4 performs the forward and reverse driving, the rotational force of the driving unit is applied to the inner tank 3, and the impact of the water flow generated by the inner tank applied with the rotational force forward and reverse rotation and the detergent Washing of the laundry is made by the decomposition of the.

After the washing stroke is completed, the rinsing is performed while going through the same process as the washing stroke, and after the rinsing stroke is completed, the following dehydration stroke is performed.

As the inner tank 3 is rotated at a high speed by the drive unit 4, centrifugal force is applied to the laundry and its water located in the inner tank, wherein the moisture is released out of the inner tank to dehydrate the laundry.

However, the following problems occurred during the washing process to perform the washing, rinsing and dehydration administration.

The continuous rotation of the drive 4 overheated the windings and other heat sensitive components of the drive, thereby reducing the efficiency of the washing machine.

That is, in the washing process, the driving unit 4 takes a very large load, and the heat generated at this time causes the following problems.

First, when the limit temperature of the drive unit 4 is momentarily exceeded by the heat, the insulating material surrounding the windings melts and the windings are shorted to cause a malfunction.

Second, although the limit temperature of the drive unit 4 has not exceeded, when the ambient temperature is increased by the heat, even if the insulating material is not melted, the resistance is increased by the ambient temperature, thereby increasing the power consumption.

Therefore, in order to solve the above problem, as shown in Figures 2a and 2b, the prior art drive unit cooling apparatus has been developed, the components are as follows.

Drive unit 11 for generating a rotational force in the forward / reverse direction, the shaft 12 is rotated in the forward / reverse direction by receiving the rotational force of the drive unit, and coupled to the shaft to transfer the rotational force in the forward / reverse direction It is composed of a cooling fan (13) having a flat blade (13a) arranged side by side with the shaft so as to blow the wind at the same time as receiving.

The prior art made as described above performs the following roles and operations.

In the washing process in which several strokes such as washing and rinsing are performed, the inner tank 3 and the cooling device which receive the rotational force of the driving unit 11 transmitted to the shaft 12 are subjected to forward / reverse driving.

At this time, the inner tank 3 performs the washing process, and the cooling device cools the drive unit 11.

However, the prior art made as described above has the following problems.

First, since the cooling fan 13 is axially coupled to the shaft 12, while the inner tank 3 performs the forward / reverse drive, the cooling fan also performs the forward / reverse drive. It is not rotated, the pause or the RPM is reduced in accordance with the rotation direction of the drive unit has reduced the cooling efficiency of the cooling device.

Second, since the vanes 13a of the cooling fan are arranged side by side with the shaft 12 and have a planar shape, the air hit the vanes 13a of the cooling fan when the cooling fan 13 is rotated. It is not concentrated in the desired direction but dispersed in all directions, the cooling efficiency of the cooling device is lowered.

The present invention has been made to solve the problems of the prior art, and the object of the present invention is to improve the structure of the drive unit cooling device to double the cooling efficiency and to extend the life of the drive unit.

1 is a configuration diagram showing the configuration of a general washing machine.

Figure 2a is a detailed view "A" of Figure 1 showing the configuration of the drive unit cooling apparatus according to the prior art.

Figure 2b is a plan view showing the shape of a cooling fan according to the prior art.

Figure 3a is a configuration diagram showing the configuration of the drive unit cooling apparatus according to the present invention.

Figure 3b is a perspective view showing the structure of a one-way bearing according to the present invention.

Figure 3c is a perspective view showing the shape of the cooling fan according to the present invention.

Explanation of symbols for main parts of the drawings

100: drive unit 200: shaft

300: cooling means 310: one-way bearing

311: inner ring 312: outer ring

313: ball 314: stopper

320: cooling fan 321: wing

In order to achieve the above object, the present invention is a drive unit for generating a rotational force in the forward / reverse direction, the axis receiving the rotational force of the drive unit to rotate in the forward / reverse direction, and axially coupled to the shaft, but the forward / reverse direction It provides a drive unit cooling device comprising a cooling means for transmitting the rotational force of only one direction to blow the wind to the drive unit.

Referring to the drawings to describe the above content in more detail as follows.

Figure 3a is a configuration diagram showing the configuration of the drive unit cooling apparatus according to the present invention, Figure 3b is a perspective view showing the structure of the one-way bearing according to the present invention, Figure 3c is a perspective view showing the shape of the cooling fan according to the present invention. .

As shown in Figure 3a, the present invention consists of the following components.

The driving unit 100 for generating a rotational force in the forward / reverse direction, the shaft 200 is rotated in the forward / reverse direction by receiving the rotational force of the drive unit, and the shaft is coupled to the rotational force in the forward / reverse direction It is configured to include a cooling means 300 for transmitting the wind to the drive unit only in the direction.

The present invention made as described above performs the following roles and operations.

During washing, when the driving unit 100 is operated, the forward / reverse rotational force of the driving unit is transmitted to the shaft 200 and also to the cooling unit 300.

At this time, the inner tank (not shown) to perform the washing receives the forward / reverse rotational force of the drive unit 100 to perform the washing, while the cooling means 300 is any one of the forward / reverse rotational force of the drive unit Only the rotational force in the direction is received to cool the drive unit.

That is, since the cooling means 300 rotates only in one direction, when the rotational force direction of the driving unit 100 is switched, the cooling means continues to rotate in the same direction by inertia without being paused.

Therefore, the cooling means 300 rotated in one direction improves the cooling efficiency of the cooling device because the rotation is temporarily stopped or the RPM decrease does not occur even when the rotation direction of the driving unit 100 is switched as described above. .

On the other hand, as shown in Figure 3a, the cooling means 300 of the configuration of the present invention consists of the following components.

One-way bearing 310 is coupled to the shaft 200 to transmit the rotational force of the forward / reverse direction only in one direction, and a cooling fan coupled to the one-way bearing to blow wind toward the drive unit 100 ( 320) is configured to include.

Cooling means made as described above performs the following role and operation.

Since the cooling fan 320 is coupled to the one-way bearing 310, the cooling fan 320 is rotated by receiving the forward / reverse rotational force of the shaft 200 in only one direction.

At this time, the cooling fan 320 flows ambient air and blows the air to the driving unit 100 to cool the driving unit.

On the other hand, as shown in Figure 3b, the one-way bearing 310 of the configuration of the present invention is composed of the following components.

A cylindrical inner ring 311 axially coupled to the shaft 200, a cylindrical outer ring 312 coupled to the cooling fan 320, and an inner ring provided between the inner ring and the outer ring; Ball 313 to reduce the friction of the outer ring, and the stopper 314 is provided between the inner ring and the outer ring to rotate the cooling fan 320 in only one direction.

In addition to the one-way bearing 310 having the above components as long as the component to rotate in one direction can be applied to the present invention.

One-way bearing 310 made as described above performs the following role and operation.

The one-way bearing 310 is to be rotated in only one direction, by the stopper 314 provided between the inner ring 311 and the outer ring 312, the cooling fan 320 is in the following direction It is controlled to rotate only.

First, when the shaft 200 is rotated in the forward direction by receiving the rotational force of the driving unit 100, the stopper 314 is in contact with the inner ring 311 and the outer ring 312 is locked (locked), The cooling fan 320 coupled to the outer ring receives the rotational force of the shaft 200 coupled to the inner ring to perform forward rotation.

Second, when the shaft 200 is rotated in the reverse direction by receiving the rotational force of the driving unit 100, the stopper 314 is not in contact with the inner ring 311 and the outer ring 312 is unlocked (unlocked) The reverse direction does not occur because the cooling fan 320 coupled to the outer ring does not receive the rotational force of the shaft 200 coupled to the inner ring.

Therefore, the cooling fan 320 cools the drive unit 100 while maintaining the forward rotational force by inertia.

On the other hand, as shown in Figure 3c, in the cooling fan 320, which is a configuration of the cooling means 300, the blade 321 of the cooling fan is preferably formed in a curved surface.

The reason for this is that when the cooling fan 320 is rotated, the air hit by the wing 321 can be blown in a desired direction.

That is, since the blade 321 of the cooling fan has a curved shape, it is possible to concentrate the flow of air generated by the cooling fan blades to the driving unit 100, thereby improving the cooling efficiency of the cooling device.

As described above, since the present invention allows the cooling fan to continuously rotate in one direction, the cooling efficiency of the cooling device can be doubled as mentioned above.

Since the blades of the cooling fan are formed in a curved surface, the flow of air generated by the blades of the cooling fan can be concentrated in the driving unit, thereby increasing the cooling efficiency of the cooling device.

On the other hand, by improving the cooling efficiency of the cooling device, since the temperature of the driving unit is lowered, the efficiency of the driving unit can be improved, and the life of the driving unit can be extended.

That is, since the resistance of the winding that is a component of the driving unit can be reduced, the efficiency of the driving unit can be improved and the life can be extended.

In addition, since the insulating material having low heat resistance can be used, the cost can be reduced.

Claims (4)

A drive unit for generating rotational force in the forward / reverse direction, An axis for rotating in the forward / reverse direction by receiving the rotational force of the driving unit; Drive shaft cooling device characterized in that it is coupled to the shaft, the cooling means for blowing the wind to the drive unit by transmitting the rotational force of the forward / reverse direction only in one direction. The method of claim 1, Cooling means; A one-way bearing coupled to the shaft for transmitting the forward / reverse rotational force in only one direction; Drive unit cooling apparatus characterized in that it comprises a cooling fan coupled to the one-way bearing for blowing the wind toward the drive unit. The method of claim 2, One-way bearing; A cylindrical inner ring axially coupled with the shaft, A cylindrical outer ring coupled to the cooling fan; A ball provided between the inner ring and the outer ring to reduce friction between the inner ring and the outer ring, And a stopper provided between the inner ring and the outer ring to rotate the cooling fan only in one direction. The method of claim 2, Drive blade cooling device characterized in that the wing of the cooling fan is formed in a curved surface.