EP0878575B1 - Method for balancing a rotating body - Google Patents

Description

The invention relates to a method for balancing rotating bodies using a device consisting of at least one concentrically rotating body to its axis of rotation arranged annular raceway, within the at least two weights are freely movable.

Such a device is known for example from FR 1 213 067. She uses it freely Weights that can be moved within the raceway to compensate for an imbalance. The balancing primarily refers to an unbalance caused by an uneven distributed laundry mass is caused in a laundry drum.

The disadvantage of such a device is that the compensatory effect only unfolded above the resonance frequency or critical speed of the system in which the rotating body is supported (see e.g. Kellenberger: elastic balancing; springer Publishing company; P. 402f). In the subcritical speed range, the existing unbalance is even strengthened. Therefore, the main field of application of such a device is fast rotating machines with a constant speed above all occurring resonance frequencies. However, there is a desire to use such a device, for example in Spin start-up of a washing machine with a horizontal axis of rotation. there should both the amplitudes in the steady supercritical state and in Driving through the resonances can be reduced.

EP 0 349 798 B1 describes a method for controlling the spinning process in washing machines known in which the drum from a fixed, previously determined position of the Unbalance is accelerated out. This procedure is designed to reduce unbalance Deflections of the vibrating system of the washing machine, but not to Remove or reduce the imbalance.

The invention therefore has the problem of a method and a device for balancing of rotating bodies of the type mentioned above, which (s) in subcritical range does not lead to an increase in the unbalance.

According to the invention, this problem is solved by a method with that in claim 1 specified features solved. Advantageous further developments of the method according to the invention and advantageous embodiments of an apparatus for performing this method result from the following subclaims.

The advantages achievable with the invention result from the fact that the acceleration of the Body takes place from a defined position, in which the weights are out of balance first fully or partially compensate. In this way, statistically, less Vibration amplitudes of the body to be balanced than with a random initial distribution the weights are expected. The speed is before reaching the critical speed advantageously increased suddenly or at least very quickly prevent the weights from being aligned in a position that increases the unbalance.

In washing machines, it is advantageous to determine the position of the unbalance during the spin-up determined in the distribution or application speed range. Here's the laundry already held a fixed position, d. that is, the possibly caused by unfavorable laundry distribution Imbalance is stationary.

In an advantageous device for performing the method according to the invention, in arranged a means to increase the running friction of the weights. At a horizontal axis of rotation of the body is ensured by such a means that the Balls rotate with the raceway and not due to their gravity in the lower area of the Roll off the web. A viscous damping agent, especially oil, has proven itself here, as liquids with low viscosity do not produce the desired effect and highly viscous masses or sand disturb the orientation of the balls in the supercritical area. Such damping agents unfortunately lead to considerable problems in their disposal. In addition, their viscosity strongly temperature-dependent, so that their use in rotating bodies with fluctuating Temperature, for example in washing machine drums in suds containers with different tempered lye, difficult.

In such an application, it is advantageous if a temperature detection device the ambient temperature of the track detected and if a control device Bodies from a dependent on the ambient temperature and the position of the unbalance Position accelerated to the second speed. As a result, the temperature influences of the Damping device on the position of the balls before accelerating to the supercritical Speed can be reduced.

Figur 1

eine Trommelwaschmaschine (1) und schematisch die Einrichtung zur Unwuchtsensierung

Figur 2

eine schematische Darstellung einer Waschmaschinentrommel (3) mit zwei Auswuchtsystemen (11)

Figur 3

einen Längsschnitt durch eine Laufbahn,

Figur 4

ein Drehzahl-Zeit-Diagramm

Figur 5-7

das drehzahlabhängige Verhalten des Auswuchtsystems anhand von Längsschnitten durch eine Laufbahn

Figur 8

einen Längsschnitt durch ein Auswuchtsystem mit Kugelzügen

An embodiment of the invention is shown purely schematically in the drawings and is described in more detail below. Show it

Figure 1

a drum washing machine (1) and schematically the device for unbalance sensing

Figure 2

a schematic representation of a washing machine drum (3) with two balancing systems (11)

Figure 3

a longitudinal section through a career,

Figure 4

a speed-time diagram

Figure 5-7

the speed-dependent behavior of the balancing system based on longitudinal cuts through a raceway

Figure 8

a longitudinal section through a balancing system with ball trains

In Figure 1 is a drum washing machine (1) with a swinging suspended Indoor unit shown schematically. A washing drum is in a tub (2) (3) rotatably mounted and is driven by an electric motor (4). The Regulation (6) of the motor (4) and a device (7) for detecting the unbalance (15) of the Drum (3) are integrated in a microprocessor control (5). As an indication of a possibly This unbalance (15) can cause the fluctuations in the speed, the motor current consumption and / or the torque can be evaluated. In the present example, it creates with tachogenerator (8) connected to the motor shaft one of the respective rotational speeds of the laundry drum (3) corresponding voltage. To a control variable for the Mortorstromregel (6) e.g. in a known manner, the actual voltage generated by the tachometer generator (8) with a target voltage corresponding to the desired speed (reference voltage) compared. Depending on the control deviation, the motor control variable is influenced.

Balancing systems are used in the drum cap (9) and the drum base (10) (see FIG. 2), an inexpensive method of producing the annular raceways (12) Thermoforming process is used.

Figure 3 shows a longitudinal section through a raceway (12), with individual balls (13) as weights are recognizable. These can have a circular cross-section (12) move freely meridional. To ensure the maximum compensation, each track (12) in the densest packing in an angular range α ≈ 180 ° with balls (13) be filled. So with the horizontal axis of rotation the gravity acting on the ball (13) is overcome from a desired rotational speed and the balls (13) of the career, it must be with a viscous damping agent (14) be filled, advantageously using oil. Without this damping agent (14) the balls (13) would only be subject to rolling friction and thus at the lowest point of the Roll career (12) without developing their compensatory effect.

The operation of the balancing systems is described below:

As can be seen from the diagram in FIG. 4, the laundry drum (3) runs through a laundry distribution speed range t _V when accelerating from a washing speed n _W. In this distribution speed range t _V , the laundry is well distributed around the drum circumference; so that better dewatering of the laundry and the least possible imbalance (15) is achieved. Depending on the program control, a laundry application speed range t _A with a constant application speed n _{A can be} traversed following the laundry distribution speed range t _V. In the distribution speed range t _V and / or in the laundry supply speed range t _A , any imbalance (15) that may be present is sensed by the microprocessor control (5) of the drum washing machine (1). The size and the position of the unbalance (15) are sensed by evaluating the fluctuations in the speed, the motor current or the torque in relation to the motor control. The size of the change in speed is a measure of the size of the unbalance (15). The speed, the Mortor current consumption and the torque provide information about the position of the unbalance (15) in the drum (3).

When rotating with laundry application speed n _A , the balls (13) are still subject to gravity and try to roll to the lowest point of the raceway (12). Due to rolling friction and the viscous damping means (14), however, there is already a deflection in the direction of rotation (see FIG. 5). Will now be given a relatively rapid ramp up to the spin speed n _S, so to remain the balls (13), as shown in Figure 6, a compact compensating mass while passing through the resonance speed n _R before they are distributed properly in the supercritical phase above n _R ( see Figure 7).

If the unbalance (15) immediately before the spin start (clockwise rotation), as in Figure 6 shown, compared to the center of gravity of the weight, i.e. the total center of gravity S of all Balls (13) is ensured that the centrifugal force of the balls (13) and Counterbalance unbalance (15). Statistically speaking, lower amplitudes can then be used expected at the resonance passage.

The microprocessor control (5) therefore first senses the position of the unbalance (15) and starts the centrifugal run-up according to the invention exactly when unbalance (15) and Oppose the center of gravity of the ball diametrically. It should be noted that the microprocessor control (5) the location of the center of gravity (S) must be known. A sensation with the help of position sensors is used when using several individual balls (13) reasonable effort not possible. Therefore, the rolling behavior of the balls (13) must be in Test series observed and the friction-dependent position of the center of gravity (S) in be stored in a memory of the microprocessor control. The decisive factor here is The fact that the viscous damping with a drum washing machine (1) different lye temperature relevant temperature range between 20 ° C and 70 ° C Varies at least by a factor of 2, since no more viscosity-stable liquids are known. The The phase angle of the unbalance position during spin-up must therefore depend on the temperature () can be varied, since the drain position of the Balls (13) changes in the subcritical speed range. Acceleration must also be accelerated be modified because the time to distribute the balls (13) depending on Viscosity of the damping agent (14) changes and only then an amplitude reduction in Resonance passage is guaranteed. The temperature () of the damping agent is with the The alkali temperature is identical and can therefore be measured using an existing temperature sensor (18) be detected on the tub (2).

FIG. 8 shows another embodiment in which, instead of individual balls (13), ball trains (16) be used. At the ends of each ball train (16) there is one Bimetal plate (17), which, depending on the temperature, the gap width to the edges of the track (12) varies and thus keeps the viscous damping of the ball trains (16) constant. In this Trap will be the adaptation of the acceleration, as well as the temperature-dependent change dispensing with the phase spin angle. Another advantage of the ball trains (16) is in that the sliding friction with each other and the collision of the balls (13) is prevented, which has a positive effect on the noise situation.

Claims (11)

1. Method for the balancing of rotating bodies by using a device comprising an annular-shaped raceway (12), which rotates with the body and is disposed concentrically relative to its axis of rotation and within which at least two weights (13; 16) are disposed so as to be freely displaceable, characterised by the following method steps

   acceleration of the body to a first speed (n_V; n_A), at which a stationary imbalance (15) is developed,

   recording of the position of the imbalance (15),

   subsequent acceleration of the body to a second speed (n_S) above the critical speed of the body or of its bearing system from a position at which the imbalance (15) is located opposite the centre of gravity (S) of the weights.
2. Method for the balancing of rotating bodies according to claim 1, characterised in that the subsequent acceleration is effected in a sudden manner before the critical speed (n_R) is obtained.
3. Method for the balancing of the drum (3) of a drum washing machine (1) according to one of the claims 1 or 2, characterised in that the position of the imbalance (15) at the start-up of the spinning procedure is recorded in the distribution or application speed range (t_V ; t_A).
4. Device for the execution of the method for the balancing of rotating bodies, more especially the drum (3) of a drum washing machine (1), according to one of the claims 1 to 3, characterised in that a means for increasing the running friction of the weights is disposed in the raceway (12).
5. Device according to claim 4, characterised in that the raceway (12) is filled at least partially with a viscous damping means (14).
6. Device according to one of the claims 4 or 5, characterised by an arrangement for the recording of the size and the position of an imbalance (15) through the intermediary of a speed-dependent characteristic of the drive motor (14) for the rotating of the body.
7. Device according to claims 5 to 6, characterised in that a temperature recording arrangement (18) records the temperature (v) of the viscous damping means (14) and in that a control arrangement accelerates the body from one position, which is dependent on the temperature and on the position of the imbalance (15), to the second speed (n_S).
8. Device according to claim 7, characterised in that the control arrangement controls the rate of the increase in speed in a temperature-dependent manner.
9. Device according to one of the claims 4 to 8, characterised in that balls (13) are used as weights.
10. Device according to one of the claims 4 to 8, characterised in that ball trains (16) are used as weights.
11. Device according to claim 10, characterised in that at least one plate (17) is disposed on the ball trains (16), which plate (17) has a temperature-dependent changeable cross-sectional area at right angles to the direction of displacement.

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