[0001] The present invention relates to a hydraulic pump, particularly for dishwashers or
the like.
[0002] As is known, in dishwashing machines it is necessary to use the same pump to feed
the delivery conduits of two or more separate hydraulic circuits, such as for example
the circuit of the sprinkler of the upper dish-holder and that of the lower dish-holder.
A first type of hydraulic pump is known which is constituted by a casing which accommodates
an impeller and defines, around said impeller, a diffusion chamber with a passage
cross section which increases in the direction of the liquid propelled by the impeller.
The diffusion chamber is connected in output, i.e. at its greater passage cross section,
to a first delivery duct which feeds the sprinkler of the lower dish-holder. A second
delivery duct extends from said first duct after the pump and feeds the sprinkler
of the upper dish-holder.
[0003] A second type of hydraulic pump is also known; said pump is constituted by a casing
which accommodates an impeller and defines, about said impeller, a diffusion chamber
which is connected to two delivery ducts having angularly spaced inlets with respect
to the axis of the impeller; said delivery ducts respectively feed the sprinkler of
the lower dish-holder and the sprinkler of the upper dish-holder. The diffusion chamber
is practically divided into two chambers, the passage cross sections whereof increase
in the direction of the liquid propelled by the impeller towards the related inlet
of one of the delivery ducts. In this case the pump can be assimilated to two pumps
which have an equal head and a capacity which is proportional to the arc of extension
of the related diffusion chamber and separately feed the two delivery ducts.
[0004] Some dishwashing machines, which use pumps of the first type, can wash dishes contained
in the lower dish-holder, for example in case of small loads. In such machines the
upper sprinkler may be manually overturned so that the two sprinklers strike the dishes
contained in the lower dish-holder with the pump's entire capacity.
[0005] In other kinds of machine, the flow-rate can be adjusted in one of the delivery ducts
by acting manually on a valve arranged on a duct to be adjusted, generally on the
delivery duct which feeds the upper sprinkler.
[0006] Such known types of machines, though they respectively allow to wash the dishes contained
in a single dish-holder or to adjust the flow-rate along one of the delivery ducts,
have the disadvantages of requiring a manual intervention on the part by the user
and of not allowing a satisfactory adjustment of the flow-rate and/or of the head
on the delivery ducts according to the actual requirements of the machine's washing
cycles.
[0007] The aim of the present invention is to obviate the above described disadvantages
by providing a hydraulic pump, in particular for dishwashers, which allows to feed
one or both of the delivery ducts automatically according to the requirements.
[0008] Within the scope of this aim, an object of the invention is to provide a hydraulic
pump which allows to automatically adjust the flow-rate on the two delivery ducts
fed by said pump and/or of the head on only one of said ducts.
[0009] Another object of the invention is to provide a pump which fully meets the various
requirements of the preset washing cycles.
[0010] Still another object of the invention is to provide a pump which reduces consumption
and noise, particularly in the cycles which require low hydraulic power, such as for
example during rinsing or in so-called economy cycles.
[0011] Not least object of the invention is to provide a pump in which the various possible
adjustments can be controlled by an automatic programming element.
[0012] This aim, as well as these and other objects which will become apparent hereinafter,
are achieved by a hydraulic pump, particularly for dishwashers or the like, which
comprises a casing which rotatably accommodates an impeller and defines, peripherally
to said impeller, a diffusion chamber which has a first inlet for a first delivery
duct and a second inlet for a second delivery duct, characterized in that proximate
to at least one of said inlets, adjustment means are provided in said diffusion chamber
and can be controllably actuated to vary the degree of opening of said one of said
inlets.
[0013] Further characteristics and advantages of the invention will become apparent from
the description of a preferred but not exclusive embodiment of the pump according
to the invention, illustrated only by way of non-limitative example in the accompanying
drawings, wherein:
figure 1 is a schematic sectional view of the pump according to the invention, taken
along a plane which is perpendicular to the axis of the impeller, in an operating
condition; and
figure 2 is a schematic sectional view of the pump according to the invention, similar
to figure 1, in another operating condition.
[0014] With reference to the above described figures, the pump according to the invention,
generally indicated by the reference numeral 1, comprises a casing 2 which, like known
pumps, rotatably accommodates an impeller 3 with vanes 4. The casing 2 defines a diffusion
chamber 5 around the impeller 3; said chamber has a first inlet 6, to be connected
for example to a first delivery duct 7 which feeds the lower sprinkler of a dishwasher,
and a second inlet 8, to be connected for example to a second delivery duct 9 which
feeds the upper sprinkler. The diffusion chamber 5 is shaped so that its passage cross
section increases concordantly with the direction of the liquid propelled through
said chamber by the impeller 3.
[0015] The first inlet 6 is arranged in output to the diffusion chamber 5, i.e. at the greater
passage cross section of said chamber, while the second inlet 8 is arranged ahead
of the first inlet 6 with respect to the direction of flow of the liquid propelled
by the impeller 3.
[0016] According to the invention, adjustment means 10 are provided proximate to the second
inlet 8 in the diffusion chamber 5 and can be controllably actuated to vary the degree
of opening of the second inlet 8.
[0017] More particularly, the adjustment means 10 are constituted by a movable element 11
in the shape of a vane which is concave on the side directed toward the impeller 3
and can be controllably moved from an opening position, in which it keeps the second
inlet 8 open, to a closure position, in which it completely closes said inlet 8, with
the possibility of intermediate positions.
[0018] One of the ends of the vane 11 is pivoted to the casing 2 proximate to the wall thereof
which radially delimits the diffusion chamber 5, while the opposite end extends proximate
to the second inlet 8. The vane 11 can oscillate controllably about an axis 12 which
is parallel to the axis 23 of the impeller 3 to pass from the opening position to
the closure position or vice versa.
[0019] The impeller 11 has, on its side directed toward the impeller 3, a curved profile
which is connected to the inner surface of the casing, which radially delimits the
diffusion chamber 5, when said vane is in its closure position and connects to the
perimeter of the impeller 3 when the vane is in its opening position.
[0020] Proximate to its free end, on its side directed oppositely to the impeller, the vane
11 has a first portion 11a which connects to the perimeter of the impeller in its
opening position and a second portion 11b which is concave on its side directed towards
the inlet 8 and connects the first portion 11a to the inlet 8.
[0021] A cavity 13 is advantageously defined on the wall of the casing which radially delimits
the diffusion chamber 5; said cavity is adapted to partially accommodate the vane
11 in its closure position.
[0022] In this manner, by virtue of its configuration and of the cavity 13, the vane 11
has its free end close to the impeller in its opening position and divides the diffusion
chamber 5 into two hydraulically independent partial diffusion chambers; each chamber
is connected to one of the inlets 6 and 8 and its passage cross section increases
towards the related inlet.
[0023] In order to move the vane 11 from its opening position to its closure position, or
to an intermediate position, actuation means 15 can be used which act on the pivoting
pin 14 of the vane 11 or directly on the vane 11. In the illustrated embodiment said
actuation means are advantageously constituted by a known linear motor 16 which is
associated with the casing 2 proximate to the cavity 13 and has a control rod 17 pivoted
with its free end to the vane 11. More particularly, the free end of the actuation
rod 17 is pivoted in a slot 18 defined in the vane 11. Elastic means 19 are furthermore
provided between the vane 11 and the casing 2; said means are constituted for example
by a spring and elastically bias the action of the linear motor 16.
[0024] In order to vary the flow-rate and the head of the pump under invariant hydraulic
conditions set by positioning the vane 11, the impeller 3 may be advantageously actuated
by an electric motor of a known type, not illustrated, having a controllably variable
rpm rate.
[0025] The operation of the pump according to the invention is as follows.
[0026] If both the upper sprinkler and the lower sprinkler must be fed, the vane 11 is moved
to its open position (figure 1). In this manner the pump behaves like two independent
pumps which separately feed the two delivery ducts 7 and 9.
[0027] If only the lower sprinkler is to be fed, the vane 11 is moved to its closure position
so as to close the second inlet 8 (figure 2). In this manner the pump's entire capacity
is conveyed to the lower sprinkler.
[0028] During the steps of the washing cycle which require a reduced head and/or capacity
both on the first delivery duct 7 and on the second delivery duct 9 or only on the
second delivery duct 9, the rotation rate of the motor which actuates the impeller
3 can be reduced according to the various requirements, keeping the vane 11 respectively
in its opening position or in its closure position.
[0029] A further variation of the flow-rate and/or the head on the two ducts 7 and 9, according
to the requirements, can be obtained by appropriately arranging the vane 11 in an
intermediate position between its opening position and its closure position.
[0030] In practice it has been observed that the pump according to the invention fully achieves
the intended aim, since it allows to automatically adjust the flow-rate and/or the
head on the two delivery ducts or on a single duct so as to fully meet the most disparate
washing requirements of a dishwasher, and furthermore achieves greater washing efficiency
and a reduction in costs. With such adjustments it is furthermore possible to adapt
the pump's hydraulic characteristics even to operating conditions which require reduced
flow-rates, thus avoiding noise.
[0031] The hydraulic pump thus conceived is susceptible to numerous modifications and variations,
all of which are within the scope of the inventive concept; all the details may furthermore
be replaced with technically equivalent elements.
[0032] In practice the materials employed, as well as the dimensions, may be any according
to the requirements and to the state of the art.
[0033] Where technical features mentioned in any claim are followed by reference signs,
those reference signs have been included for the sole purpose of increasing the intelligibility
of the claims and accordingly such reference signs do not have any limiting effect
on the scope of each element identified by way of example by such reference signs.
1. Hydraulic pump, particularly for dishwashers or the like, comprising a casing which
rotatably accommodates an impeller and defines, peripherally to said impeller, a diffusion
chamber which has a first inlet for a first delivery duct and a second inlet for a
second delivery duct, characterized in that proximate to at least one of said inlets,
adjustment means are provided in said diffusion chamber and can be controllably actuated
to vary the degree of opening of said one of said inlets.
2. Hydraulic pump, according to claim 1, characterized in that said first inlet is
arranged in output to said diffusion chamber and in that said second inlet is arranged
ahead of said first inlet, according to the direction of flow of the liquid propelled
by said impeller through said diffusion chamber, said adjustment means being constituted
by a movable element which is arranged proximate to said second inlet and is controllably
movable from an opening position, in which said second inlet is open, to a closure
position, in which said movable element closes said second inlet.
3. Hydraulic pump, according to claims 1 and 2, characterized in that in said opening
position said movable element divides said diffusion chamber into two partial diffusion
chambers which are hydraulically independent from one another, each of said diffusion
chambers being connected to one of said inlets.
4. Hydraulic pump, according to one or more of the preceding claims, characterized
in that said movable element is constituted by a vane which is concave on its side
directed towards said rotor and has one of its ends pivoted to said casing, proximate
to the wall which radially delimits said diffusion chamber, said movable element being
oscillable about an axis which is parallel to the axis of said impeller to move its
other end towards said impeller or away therefrom to close said second inlet.
5. Hydraulic pump, according to one or more of the preceding claims, characterized
in that said movable element has, on its side directed towards said impeller, a curved
profile which connects to the inner surface of said casing which radially delimits
said diffusion chamber when said movable element is in said closure position.
6. Hydraulic pump, according to one or more of the preceding claims, characterized
in that said movable element has, on its side directed towards said impeller, a profile
which connects to the perimeter of said impeller when said movable element is in said
opening position.
7. Hydraulic pump, according to one or more of the preceding claims, characterized
in that said movable element has, on its side directed opposite to said impeller,
a first portion which connects to the perimeter of said impeller and a second concave
portion which is directed towards said second inlet and connects said first portion
with said second inlet when said movable element is in said opening position.
8. Hydraulic pump, according to one or more of the preceding claims, characterized
in that on the wall of said casing which radially delimits said diffusion chamber,
a cavity is formed and is adapted to contain at least partially said movable element
in said closure position.
9. Hydraulic pump, according to one or more of the preceding claims, characterized
in that when said movable element is in its closure position the cross section of
said diffusion chamber increases towards said first inlet.
10. Hydraulic pump, according to one or more of the preceding claims, characterized
in that when said movable element is in its opening position the cross section of
said diffusion chamber increases towards said second inlet and increases from said
movable element towards said first inlet.
11. Hydraulic pump, according to one or more of the preceding claims, characterized
in that said impeller is actuated by a motor with a variable rpm rate.
12. Hydraulic pump, according to one or more of the preceding claims, characterized
in that it comprises actuation means which act on said adjustment means to vary the
degree of opening of said one of said inlets.
13. Hydraulic pump, according to one or more of the preceding claims, characterized
in that said actuation means comprises a linear motor which is supported by said casing
and has an actuation rod pivoted to said movable element, said linear motor being
arranged with said movable actuation rod along a direction which has a radial component
with respect to said impeller.
14. Hydraulic pump, according to one or more of the preceding claims, characterized
in that said movable element can oscillate about said axis which is parallel to the
axis of said impeller in contrast with elastic means or by virtue thereof.