[0001] The present invention relates to dishwashers, both for domestic and professional
use, and in particular to a dishwasher with an improved hydraulic circuit and a relevant
operating cycle.
[0002] It is well known that the increasingly stringent regulations concerning the energy
classes of household appliances, and in particular of dishwashers, push manufacturers
to reduce the operating temperatures and the volumes of water used, so that the same
quantity of dishes to be treated with less wash water leads the latter to a higher
concentration of dirt and detergent. As the hydraulic circuit inevitably has areas
where stagnation occurs at the end of the wash water drainage phase, these stagnation
areas become more polluted and it is therefore even more important to eliminate them
in order to have water that is as clean as possible in the subsequent rinse phases.
[0003] To this purpose, after the wash phase and before the final rinse with hot water,
an intermediate rinse is traditionally carried out with cold water, to reduce energy
consumption, in order to remove the residues of polluted water that remain after the
drainage of the wash water. In this way, the hydraulic circuit is cleaned in preparation
for the final rinse, which must be carried out with water that is as clean as possible,
but at the same time there is the disadvantage that the hydraulic circuit, the wash
tank and the dishes are also cooled.
[0004] As a result, compared to a cycle without an intermediate rinse, the dishwasher is
forced to heat the final rinse water more, resulting in higher energy consumption.
Obviously, it would be possible to avoid this by also using hot water for the intermediate
rinse, but the overall energy consumption would not change because the heating for
the intermediate rinse would compensate for the reduction in heating for the final
rinse. Similarly, it would be possible to dispense with the intermediate rinse, but
in that case the water for the final rinse would be polluted with not fully satisfactory
washing results.
[0005] To overcome these drawbacks, it is known from
EP 2759244B1 to introduce mains water into the dishwasher through the wash pump while it is turned
off, so that the water fed into the wash pump flows through it and from there goes
directly to the bottom sump of the wash tank through the relevant connecting pipes,
from where it is discharged by activating the drain pump. In this way, an almost complete
disposal of the residual wash liquid can be achieved without affecting the wash tank
and dishes by moving the water inlet from the sump to the wash pump.
[0006] However, it has been found that due to the pressure of the wash pump during normal
operation, the wash liquid can flow back into the mains water line with the risk of
undesirable contamination.
[0007] To solve this problem,
DE 102017129052A1 describes a dishwasher equipped with a mains water supply line controlled by a two-way
valve with a first outlet leading to the bottom sump of the wash tank, as in conventional
dishwashers, and a second outlet leading to the delivery duct of the wash pump. In
the intermediate rinse phase, water can be loaded by switching the valve to the second
outlet while the wash pump is off and the drain pump is running. In this way, the
advantage of
EP 2759244B1 of washing only the most critical areas of the hydraulic circuit, without affecting
the wash tank and dishes, is maintained, but during normal operation of the wash pump
there is no risk of contamination in the mains water line. In fact, in that phase
the two-way valve is switched to the first outlet and thus prevents the backflow of
washing liquid from the delivery duct of the wash pump.
[0008] This second solution is also not without drawbacks, as it requires an expensive and
bulky two-way valve and a more complex hydraulic circuit. In addition, both of the
above-mentioned prior art solutions involve a non-negligible consumption of water,
since the water is immediately discharged by the drain pump as soon as it enters the
sump after flowing back through the delivery duct and the wash pump.
[0009] The object of the present invention is therefore to provide a dishwasher which overcomes
said drawbacks. This object is achieved by means of a dishwasher provided with a recirculation
duct extending between the delivery duct of the wash pump and the sump, said recirculation
duct being provided with a shut-off valve. Other advantageous features of the present
dishwasher are specified in the dependent claims.
[0010] The main advantage of the dishwasher according to the present invention is that it
is possible to carry out the intermediate rinse by limiting it to the most critical
areas of the hydraulic circuit, without affecting the wash tank and the dishes, with
a simpler and less bulky hydraulic circuit. This result in a reduction of the dishwasher
cost both in terms of components and labor for its assembly, as well as greater designing
freedom in choosing the arrangement of the components.
[0011] A further advantage of this dishwasher and its operating cycle derives from the fact
that the intermediate rinse phase requires less water consumption because the drain
pump is activated only at the end of this phase, so that the water loaded for this
phase can be circulated several times for better cleaning of the affected portion
of the hydraulic circuit.
[0012] These and other advantages and features of the dishwasher according to the present
invention will be apparent to those skilled in the art from the following detailed
description of an embodiment thereof with reference to the accompanying drawings in
which:
Fig.1 is a schematic view illustrating the connections between the main elements of the
dishwasher;
Fig.2 is a bottom view of the main elements of the hydraulic circuit of the dishwasher;
and
Fig.3 is top perspective view similar to Fig.2.
[0013] Referring to Fig.1, it can be seen that a dishwasher according to the present invention
traditionally comprises a load duct, controlled by a shut-off solenoid valve 1, for
loading mains water from a tap to an air break 2, then passing through a softener
3 containing descaling resins, to be finally loaded into a sump 4 at the bottom of
the wash tank through an inlet 5. The water is then withdrawn for the wash/rinse phases,
through an outlet 6, by a wash pump 7, preceded by a resistor 8 arranged on the suction
duct 9. The wash pump 7 sends the water to the sprayers 10, 11 through a delivery
duct 12 and a diverter valve 18, which controls the inflow to the various sprayers
via its three outlets (there is also a third sprayer, not shown, on the ceiling of
the wash tank). The machine further comprises a drain pump 13, for sending water from
sump 4 to a drain duct 14.
[0014] The innovative aspect of this dishwasher consists in the possibility of choosing
an alternative water delivery path thanks to a recirculation duct 15, provided with
a shut-off valve 16, extending between the delivery duct 12 and an additional inlet
17 of sump 4. In fact, by closing all outlets of the diverter valve 18 and opening
the shut-off valve 16, it is possible to send the water from the delivery duct 12
directly into sump 4 through the additional inlet 17, without having it reach the
sprayers.
[0015] In the light of the above description, the simple and effective operation of the
dishwasher according to the present invention is readily understood.
[0016] In the phase of water loading into sump 4 through inlet 5 at the beginning of the
operating cycle, followed by the wash phase, valve 16 is closed. After the wash phase,
in the water loading phase for the intermediate rinse, valve 16 is opened and the
three outlets of valve 18 are closed, so that the water goes from the delivery duct
12 to the recirculation duct 15.
[0017] The wash pump 7 thus circulates the water only in the bottom part of the hydraulic
circuit of the dishwasher, along the delivery duct 12 and the recirculation duct 15
until it enters sump 4 through inlet 17, and then flows back towards the wash pump
7 through the suction duct 9 and resistor 8. Upon completion of the circuit cleaning,
the water is discharged by the drain pump 13 through the drain duct 14, leaving the
wash/rinse circuit clean and ready for the final rinse.
[0018] Note that the duration of the intermediate rinse phase and the amount of water loaded
for this phase (indicatively 200-300 ml) can be freely chosen depending on the specific
circuit cleaning requirements. In addition, this phase could be divided into multiple
sub-phases, that is, it could include multiple sequences of water loading, circuit
cleaning, and water draining.
[0019] Thus, the relevant operating cycle of a dishwasher according to the present invention
can be summarized in the following steps:
- (a) initial loading of water into sump 4;
- (b) performing of the washing phase;
- (c) discharge of the washing water;
- (d) opening of the shut-off valve 16;
- (e) closing of all outlets of the diverter valve 18;
- (f) loading water for the intermediate rinse into sump 4;
- (g) activation of the wash pump 7;
- (h) deactivation of the wash pump 7;
- (i) discharge of the intermediate rinse water;
- (j) closing of the shut-off valve 16;
- (k) opening of all outlets of the diverter valve 18;
- (l) loading the final rinse water into sump 4;
- (m) performing of the final rinse phase;
- (n) discharge of the final rinse water.
[0020] Note that, as mentioned earlier, the sequence of steps f)-i) could also be performed
several times, and the order of steps d)-f) could be varied freely, as could the order
of steps j)-1).
[0021] From the above, it is easy to understand how the dishwasher according to the present
invention can perform the final rinse with less energy consumption, since the wash
tank and the dishes have not been cooled by the cold water loaded in the previous
phase. Moreover, the quantity of water required for washing the wash/rinse circuit,
which is in any case the part of the hydraulic circuit with the greatest stagnation
of polluted water, is significantly less than that required for a traditional intermediate
rinse.
[0022] Note that softener 3 and/or air break 2 could be absent, and that in the case of
an industrial dishwasher, pump 7 and sprayers 10, 11 would only be intended for washing
and there would be a further pump and two further sprayers specifically intended for
rinsing, but the part of the circuit illustrated in the figures would not change.
[0023] It is clear that the embodiment of the dishwasher according to the above-described
and illustrated invention is only an example susceptible to numerous variations. In
particular, the exact shape and arrangement of valves 16 and 18, of ducts 9, 12, 14,
15 and of inlets 5 and 17, as well as of the possible softener 3 and/or air break
2, may be freely varied according to specific constructional requirements, as long
as their relative arrangement within the hydraulic circuit illustrated above is maintained.
1. A dishwasher comprising a load valve (1) controlling the inflow of water from the
mains through a load duct to load water into a bottom sump (4) through an inlet (5),
a wash pump (7) that draws water from said bottom sump (4) through a suction duct
(9) and sends it to a plurality of sprayers (10, 11) through a delivery duct (12)
and a diverter valve (18) that controls the flow of water to said sprayers (10, 11),
and a drain pump (13) connected to a drain duct (14) so as to discharge water from
the bottom sump (4), characterized by comprising a recirculation duct (15), provided with a shut-off valve (16), extending
between said delivery duct (12) and an additional inlet (17) of the bottom sump (4).
2. Operating cycle of a dishwasher according to claim 1, comprising the following steps:
(a) initial loading of water into the bottom sump (4);
(b) performing of the washing phase;
(c) discharge of the washing water;
(d) loading of water for the intermediate rinse into the bottom sump (4);
(e) activation of the wash pump (7);
(f) deactivation of the wash pump (7);
(g) discharge of the intermediate rinse water;
(h) loading of water for the final rinse into the bottom sump (4);
(i) performing of the final rinse;
(j) discharge of the final rinse water;
characterized by comprising between steps (c) and (d) the additional steps of:
(c') opening of the shut-off valve (16);
(c") closing of all outlets of the diverter valve (18);
and between steps (g) and (h) the additional steps of:
(g') closing of the shut-off valve (16);
(g") opening of all outlets of the diverter valve (18);
where the order of steps c')-c")-d) can be varied freely, and the order of phases
g')-g")-h) can be varied freely.
3. Operating cycle according to claim 2, characterized in that the sequence of steps d)-g) is performed several times.
4. Operating cycle according to claim 2 or 3, characterized in that in step d) an amount of water of 200-300 ml is loaded.