CH694495A5 - Dishwasher includes controller measuring current and phase shift at pump to recover information concerning state of hydraulic system - Google Patents

Abstract

During operation the controller (12) measures the current and/or phase shift between current and voltage at the pump (4, 10). Information is recovered concerning the state of the hydraulic system (1-11) from the variation in these measurements over time.

Description

The invention relates to a dishwasher according to the preamble of claim 1.

To optimize the operation of a dishwasher, its hydraulic system should be monitored. It should e.g. Check that there is enough water in the system. Thus, in case of incorrect loading (for example, because of a large bowl, which is located with the bottom down in the tub), the items to be washed bind a large amount of water, so that due to the lack of water in the rinse cycle proper flushing is not granted. It should also be monitored whether the pump is defective or whether nozzles or lines are clogged.

In conventional solutions, for this purpose e.g. the water level or water pressure monitored, but this is complex in terms of equipment and does not always bring satisfactory results.

Object of the present invention is to provide a dishwasher of the type mentioned, which allows monitoring of the hydraulic system in a simple manner. This object is achieved by the dishwasher according to claim 1.

According to the invention, therefore, the current and / or the phase shift between current and voltage at the pump are measured. Information about the state of the hydraulic system can then be obtained from the course of this or these values. This information can be used to control the operation of the hydraulic system as needed.

When the pump sucks in air, this makes e.g. in a "snorkeling" noticeable, which leads to a strong dispersion of the measured values. Blocking of the pump and blockages in lines or nozzles result in a high power consumption of the pump, i. to a change in the phase angle or an increase in the current. On the other hand, idling the pumps (when there is no or not enough water) results in a change in the phase angle or in a reduction of the current.

In order to detect a malfunction of the hydraulic system, the measured value or the scatter of the measured value can be compared with suitable limit values.

The inventive dishwasher can also be used to determine the rotational frequency of the or the spray arms. This manifests itself in periodic fluctuations of the current or the phase shift.

Further embodiments and advantages of the invention will become apparent from the dependent claims and from the following description with reference to FIG. 1 shows a schematic representation of the most important parts of a dishwasher, and FIG. 2 shows a simple method for determining the snorkeling.

The first figure shows a dishwasher with a washing compartment or tub 1, in which the items to be washed is arranged. At the bottom of the tub 1, a sump 2 is arranged, which has two outlets.

The first outflow 3 leads to an electrically operated circulating pump 4 with which the flushing liquor is pumped back into the tub 1 via supply lines 5, 6 and rotatable spray arms 7, 8. In the circulation circuit 3-6, a heater (not shown) is further arranged.

The second outflow 9 of the sump 2 leads to an electrically operated drainage pump 10, with which used rinse liquor (possibly with heat recovery) is removed.

 In the sump 2 also opens an inflow line 11, which supplies in a conventional manner via an ion exchanger (not shown) fresh water.

The motor of the circulation pump 4 in the present embodiment is a single-phase asynchronous motor, in which the drain pump 10 is a synchronous or shaded pole motor.

The operation of the electric motors of the pumps 4 and 10 is controlled and monitored by a controller 12. This control is equipped with measuring electronics that allow one or both of the following quantities to be measured for at least one of the motors, preferably both motors: - The phase shift? between the current and the voltage - the amplitude I 0 of the current

Both of these sizes are dependent on the load of the motor and thus allow conclusions about the current pump power.

In a preferred embodiment, the phase shift is? between current and voltage of the circulation pump 4, since this value can be used to obtain the most meaningful information about the state of the hydraulic system and since the measurement of the phase shift can be carried out in a simple manner, e.g. by measuring the time difference between the zero crossings of current and voltage.

The following describes what statements are possible on the basis of the measured values on one or both motors. 1. Snorkeling

If there is not enough water in the sump 1, then the circulating pump sucks in 4 air, which is noticeable in a so-called "snorkeling". This leads to pressure shocks in the circulation pump 4 in the range 1-100 Hz, which leads to scattering or a "jitter" of the values of the phase shift? or the current amplitude I 0 lead.

Figure 2 shows a simple method for determining snorkeling and its elimination. In a first step 20, a snorkel counter is set to 0. Then, in step 22, e.g. taken at intervals of 20 ms a total of 50 measured values. Preferably, this is the phase shift? between current and voltage of the circulation pump 4. In steps 24 and 26, respectively, the four largest and the four smallest measured values are determined and their average values m1 and m2 respectively are calculated. In step 28, the difference m1-m2 is compared with a threshold value G.

If m1-m2 ≤ G, the value of the counter is reduced by 1 in step 30 (if it is greater than 0). There is no snorkeling and the process continues with step 22.

If m1-m2> G, the scatter of the measured values is relatively strong and the counter is increased by 1 in step 30. In step 32, it is compared with a threshold X (e.g., X = 5). If m1-m2 ≦ X, no further measures are taken and the measurement is continued with step 22. However, if m1-m2 exceeds the value of X, it is concluded that the pump is snorkeling strongly and constantly. In this case, a predetermined amount of water is supplied to the hydraulic system in step 34 via the supply line 11. Then it is checked again whether the pump is snorkeling by proceeding to step 20.

The method according to FIG. 2 can be modified in many different ways. So it is e.g. it is also conceivable, instead of the values m1, m2, to determine the standard deviation or variance of the measured values. 2. Idle

If there is very little water in the hydraulic system (for example because of a defect), can this also be done via the phase shift? or the current amplitude I 0 are detected. Since in this case the pump runs idle and consumes little power, the current or the phase shift takes on a dependent on the motor characteristic, unique value. Thus, idling can be detected.

It can be seen that the current amplitude I 0 is better suited for the detection of idling, since it depends less on the supply voltage. It is also conceivable, however, both I 0 and? to measure what allows to perform a redundant measurement. 3. Clogging, blocking

If the ducts, screen or nozzle arms become clogged, or if the pump is blocked, the power consumption of the motor increases, i.e., it will increase. the current amplitude increases or the phase shift? changes in a previously known way. Thus, clogging or blocking can be detected.

Also in this case, it turns out that the current amplitude I 0 is better suited for detection, since it depends less on the supply voltage. 4. Speed measurement of the spray arms

Due to small asymmetries, the spray arms 7, 8 generate small, periodic pressure fluctuations in the lines 5 and 6 during their rotation, which lead to corresponding fluctuations in the current amplitude I 0 or the phase shift? to lead. For a good measurement, however, it is advisable to artificially increase the pressure fluctuations by means of suitable measures, e.g. by coupling the spray arms with shutters, which are moved by their rotation and lead to periodic constrictions in the lines 5 and 6, respectively.

 To distinguish the pressure fluctuations of the two spray arms, the fact can be exploited that rotate the spray arms with different frequency. If both spray arms are in operation, they produce two peaks in the Fourier spectrum of the measuring signals which correspond to the respective circulating frequencies. If one or both of these tips are missing, it must be concluded that at least one arm is not rotating.

In the examples so far described, the current and / or phase shift of the pump motors was measured. In addition, the supply voltage U can also be measured so that the power consumption of the motors can be accurately determined from the value I 0 × U × cos ()), which allows a measurement which is more independent of the supply voltage.

Thanks to the present invention, it is possible to monitor the hydraulic system of the dishwasher in a simple manner. In particular, in the manner described above, a snorkeling or idling of the pump and thus a lack of water can be detected and new water can be added as needed, which reduces water consumption. Also, a water meter in the inflow can be omitted.

Also when pumping the tub, the pump can be monitored for snorkeling or idling to determine when all the water has been pumped out.

Claims (11)

Dishwasher with at least one pump for moving water in a hydraulic system (1-11) and with a controller (12), characterized in that the controller (12) is designed for measuring the current (I 0) and / or the phase shift (?) between current and voltage at the pump (4, 10) in operation for obtaining information about the state of the hyd-raulischen system from the course of the current or the phase shift. 2. Dishwasher according to claim 1, characterized in that the controller (12) is designed for measuring the current (I 0). 3. Dishwasher according to one of the preceding claims, characterized in that the controller (12) is designed for measuring the phase shift (?) Between current and voltage. 4. Dishwasher according to one of the preceding claims, characterized in that the controller (12) is designed for measuring a scattering value (m1-m2), which is a measure of the dispersion of the current or the phase shift. 5. Dishwasher according to claim 4, characterized in that the controller (12) is designed to determine from the scatter value (m1-m2), whether the pump (4, 10) sucks in air. 6. Dishwasher according to one of claims 4 or 5, characterized in that the controller (12) is adapted to compare the scattering value (m1-m2) with a threshold value (G), and in particular that the controller (12) is configured to at to supply too much water to the hydraulic system. 7. Dishwasher according to one of the preceding claims, characterized in that the controller (12) is designed to determine on the basis of the current (I 0) or the phase shift (?) Whether water is pumped in sufficient quantity. 8. Dishwasher according to one of the preceding claims, characterized in that the controller (12) is designed to determine a blockage of the hydraulic system due to the current (I 0) or the phase shift (?). 9. Dishwasher according to one of the preceding claims, characterized in that the controller (12) is designed to determine on the basis of the current (I 0) or the phase shift (?), Whether there is sufficient water in the hydraulic system. 10. Dishwasher according to one of the preceding claims, characterized in that the pump is a circulating pump (4), with which water in the hydraulic system is recirculated. 11. Dishwasher according to one of the preceding claims, characterized in that the controller (12) is designed to due to periodic fluctuations of the current (I 0) or the phase shift (?) A rotational frequency of at least one Sprüharms (7, 8) in To determine dishwasher, and in particular that the spray arm (7, 8) is designed such that it generates a periodic constriction in the hydraulic system when it circulates by means of a diaphragm, which in turn causes a periodic pressure increase.