EP2766603A1

EP2766603A1 - Piston pump for a high-pressure cleaning device

Info

Publication number: EP2766603A1
Application number: EP12769117.8A
Authority: EP
Inventors: Thomas Hofer
Original assignee: Alfred Kaercher SE and Co KG
Current assignee: Alfred Kaercher SE and Co KG
Priority date: 2011-10-12
Filing date: 2012-10-08
Publication date: 2014-08-20
Anticipated expiration: 2032-10-08
Also published as: CN103874854A; JP2014528550A; CN103874854B; DK2766603T3; US20140219832A1; BR112014007739A2; JP5864764B2; EP2766603B1; WO2013053670A1; DE102011054442A1; US9932971B2

Abstract

The invention relates to a piston pump for a high-pressure cleaning device, comprising several pistons (18) that can be moved back and forth. Said pistons each plunge into a respective pump chamber (52) and are movably retained on a piston guiding part (22). The piston guiding part (22) has a bearing wall (26) on which several guiding elements (24) are arranged, which guiding elements (24) each guide a respective piston (18). In order to be able to produce the piston pump more economically, the bearing wall (26) is curved.

Description

PISTON PUMP FOR ONE

HIGH PRESSURE WASHING MACHINE

The invention relates to a piston pump for a high-pressure cleaning device, with a plurality of reciprocally movable pistons, which are each immersed in a pump chamber and slidably supported on a piston guide member, wherein the piston guide member has a support wall on which a plurality of guide elements are arranged, each one Guide the piston.

Such piston pumps are known for example from DE 39 18 022 C2. With their help, a liquid, preferably water, sucked and pressurized and then discharged. For this purpose, the pump chamber is connected via a suction valve with a suction line for sucking liquid and a pressure valve with a pressure line for discharging pressurized liquid. An accessory device can be connected to the pressure line, for example a high-pressure hose which carries a dispensing device at its free end, in particular a spray lance or a spray nozzle.

To convey the liquid, the pistons are reciprocally moved so that the volumes of the pumping chambers periodically change to aspirate, pressurize and dispense the liquid. The pistons are displaceably held on a piston guide part, which has a support wall and a plurality of guide elements. The guide elements each guide a piston. In many cases, the support wall forms a cover which is placed on the housing of a drive mechanism, for example on the housing. Housing a swash plate, which abut the piston and which is rotated by a motor in rotation.

The piston guide part is exposed to high mechanical loads. It therefore usually has reinforcing ribs and a considerable material thickness. This leads to increased manufacturing costs of the piston pump.

Object of the present invention is to develop a piston pump of the type mentioned in such a way that it is cheaper to produce.

This object is achieved in a piston pump of the generic type according to the invention that the support wall is curved.

In the piston pump according to the invention, a piston guide member with a curved support wall is used. Due to the curvature of the support wall on the one hand, the mechanical strength of the piston guide member can be considerably increased, without requiring the support wall reinforcing ribs or a large material must have strength. On the other hand, the curved surface of the supporting wall enlarges its surface, so that it also has an improved thermal load capacity, since due to the larger surface a reliable heat dissipation is ensured without necessarily having to provide cooling fins for the supporting wall. The relatively small amount of material required for the support wall reduces the weight of the piston guide member. In addition, the piston guide member with the curved support wall can be manufactured inexpensively, so that the manufacturing cost of the piston pump can be reduced. It is particularly advantageous if the supporting wall is curved in the same direction on its front side facing the pumping chambers and on its rear side facing away from the pumping chambers. The support wall thereby forms a cavity or depression which gives the support wall a particularly high mechanical load capacity.

In a preferred embodiment, the support wall is curved in the manner of a spherical cap. For example, it can form a spherical cap of a housing which accommodates a drive mechanism for the pistons.

In a preferred embodiment of the invention, the supporting wall is curved in the direction facing the pumping chambers or in the direction away from the pumping chambers. This has the advantage that its central region is axially offset from its outer periphery.

Preferably, the guide elements are integrally connected to the support wall and are on the side facing away from the pump chambers of the support wall from the support wall. For example, it can be provided that the supporting wall is arched in the direction of the pumping rooms, so that they are supported by the pump

Pumpräumen facing away from a depression or cavity forms, in which immerse the guide elements.

The support wall can, for example, form a cover for a swash-plate housing, wherein the cover is arched outwards or immersed in the housing.

A particularly high mechanical stability is achieved in an advantageous embodiment in that the guide elements have a base which is integrally connected to the support wall and projects at least on one side of the support wall. It is advantageous if the base protrudes from the support wall on both sides of the support wall.

Preferably, radially increasing reinforcing ribs are integrally formed on the outer sides of the guide elements to increase the mechanical and thermal load capacity of the piston guide part.

It is advantageous if the guide elements have a base which protrudes from the support wall on the side of the support wall facing the pump chambers and bears radially projecting reinforcing ribs on its outer side. Due to the use of the reinforcing ribs, the material used for the base can be kept low, without their mechanical or thermal capacity is impaired. It is particularly advantageous if the reinforcing ribs protrude in the axial direction over the base. With its axially projecting portion, the reinforcing ribs define a receiving space for an annular member of the piston pump which circumferentially surrounds the piston passing through the guide member. This may be, for example, a guide ring or a sealing ring. The reinforcing ribs not only have the purpose in such a configuration to increase the mechanical and thermal stability of the base, but also serve to define an annular member which surrounds a piston in the circumferential direction.

In an advantageous embodiment of the invention, the guide elements have an integrally connected to the supporting wall base, to which a guide sleeve connects in the axial direction, which surrounds a piston in a form-fitting manner in the circumferential direction. The base can have a higher material thickness than the guide sleeve. In particular, it can be provided that the outer side of the base merges via an inwardly directed, preferably radially aligned step into the outer side of the guide sleeve. On the outside of the guide sleeves radially projecting reinforcing ribs are favorably formed.

A particularly high mechanical stability is achieved in a preferred embodiment of the invention in that on the outer circumference of the support wall, a cylindrical collar is formed. The cylindrical collar immersed in a preferred embodiment in a cylindrical housing of a swash plate.

The following description of preferred embodiments of the invention is used in conjunction with the drawings for further explanation. Show it :

FIG. 1 shows a schematic sectional view of a first embodiment of a piston pump according to the invention;

Figure 2 is a sectional view of a piston guide member of the piston pump of Figure 1;

a perspective view of the piston guide member of Figure 2 obliquely from the front; a perspective view of the piston guide part of Fi gur 2 obliquely from behind; a sectional view of a second embodiment of a piston pump according to the invention; a sectional view of a piston guide member of the piston pump of Figure 5; a perspective view of the piston guide member of Fi gur 6 obliquely from the front and a perspective view of the piston guide member of Figure 6 obliquely from behind. FIGS. 1 to 4 schematically show a first embodiment of a piston pump according to the invention, which is generally designated by the reference numeral 10. It can be placed in a conventional manner on a motor, not shown in the drawing, which rotatably drives a swash plate 12 which is rotatably mounted in a swash plate housing 14 by means of a ball bearing 16. The piston pump 10 comprises a plurality of identically designed pistons 18, which bear against the front side of the swash plate 12 facing away from the ball bearing 16 and with the aid of return springs 20 in the direction of rotation. tion on the swash plate 12 are pressed. The pistons 18 are held linearly displaceable on a piston guide part 22 of the piston pump 10. For this purpose, the piston guide part 22 has guide elements 24 which each guide a piston 18 and which are integrally connected to a support wall 26 of the piston guide part 22.

The support wall 26 is designed in the manner of a spherical cap and curved in the embodiment shown in Figures 1 to 4 in the swash plate 12 facing away from the direction. It forms a lid which is placed on a cylindrical jacket 28 of the swash plate housing 14. On the outer circumference of the support wall 26, a cylindrical collar 30 is formed, which dips into the jacket 28 of the swash plate housing 14 with the interposition of a sealing element 32. The guide elements 24 are formed identically and each comprise an integrally connected to the support wall 26 cylindrical base 34 which protrudes both on the swash plate 12 remote from the front side 36 of the support wall 26 and on the swash plate 12 facing back 38 of the support wall 26 of the support wall , In the direction of the wobble plate 12, a guide sleeve 40 integrally connects to the base 34, which surrounds the respective piston 18 in a form-fitting manner. The material thickness of the base 34 is chosen to be greater than the material thickness of the guide sleeve 40th

As becomes clear in particular from FIG. 4, the outer sides of the pedestals 34 merge into the outer sides of the guide sleeves 40 via radially inwardly directed steps 42. On the outer sides of the base 34 radially projecting reinforcing ribs 44 are integrally formed on both sides of the support wall, the are arranged evenly distributed over the circumference of the base 34. The arranged on the front side 36 of the support wall 26 reinforcing ribs 44 protrude in the axial direction on the cylindrical base 34. This becomes clear in particular from FIG.

The formed on the back 38 of the support wall 26 to the base 34 guide sleeves 40 have, in contrast to the sockets 34 on the outside no reinforcing ribs. On the piston guide member 22, a pump block 46 of the piston pump 10 is placed and on the pump block 46, a pump head 48 of the piston pump 10 is placed. By means of clamping screws 50 of the pump block 46 and the piston guide member 22 between the pump head 48 and the swash plate housing 14 are clamped.

The pump block 46 has pump chambers 52 into each of which a piston 18 is immersed and which are in fluid communication with a suction line 56 via an inlet opening 54 and with an outlet opening 58 with a pressure line 60. Between the pump chambers 52 and the suction line 56 a per se known suction valve is not shown in the drawing, and between the pump chambers 52 and the pressure line 60 is a not shown in the drawing, known per se pressure valve arranged. The suction line 56 connects the pump chambers 52 with a suction inlet 62 of the piston pump 10, to which, for example, a suction hose can be connected. The pressure line 60 connects the pump chambers 52 with a

Pressure outlet 64 of the piston pump 10 to which, for example, a pressure hose can be connected.

When the swashplate 12 is rotated about its axis of rotation 66, the pistons 18 perform a reciprocating motion parallel to the axis of rotation 66, periodically changing the volume of the respective pumping chamber 52 into which they are immersed so that liquid passes through the suction inlet 62 and the suction line 56 sucked into the pump chamber 52, then pressurized and then discharged via the pressure line 60 and the pressure outlet 64. The pistons 18 are in the axial direction by means of the piston guide member 22, d. H. guided parallel to the axis of rotation 66. For this purpose, the pistons 18 each slide along a guide sleeve 40, which is connected in one piece with the support wall 26 via a base 34. The latter has a high mechanical stability due to its spherical cap-shaped configuration, which is reinforced by the cylindrical concentric with the axis of rotation 66 aligned collar 30 which is integrally connected to the support wall 26. In addition, the support wall 26 is characterized by a high thermal stability, since it has a relatively large surface over which heat can be dissipated.

FIGS. 5 to 8 show a second advantageous embodiment of a piston pump according to the invention, which is designated overall by reference numeral 70. The piston pump 70 is configured similarly to the above-described piston pump 10. The piston pump 70 is driven by a swash plate 72 which is rotatably mounted in a swash plate housing 74 and is rotated by a motor, not shown in the drawing.

On the swash plate 72 are piston 78, which are pressed by return springs 80 in the direction of the swash plate 72. The pistons 78 are held displaceably on a piston guide part 82 in the axial direction. The piston guide part 82 comprises guide elements 84, which are integrally connected to a support wall 86 of the piston guide part 82. The support wall 86 is placed on a jacket 88 of the swash plate housing 74 and on the outer periphery of the support wall 86, a cylindrical collar 90 is formed, which surrounds an end portion of the jacket 88 in the circumferential direction.

In a manner similar to the support wall 26 of the piston pump 10 explained above with reference to FIGS. 1 to 4, the support wall 86 of the piston pump 70 is configured in the manner of a spherical cap. In contrast to the support wall 26, however, the support wall 86 is arched in the direction of the swash plate 72 facing direction. The support wall 86 thus forms on its front side 96 facing away from the swash plate 72 a depression or cavity and with its swash plate 72 facing the rear side 98 in the swash plate housing 74 a. The guide elements 84 of the piston pump 70 each comprise a cylindrical base 94, which is integrally formed on the support wall 86 and protrudes on both the front side 96 and on the rear side 98 via the support wall 86. The swash plate facing 72 connects to the base 94, a guide sleeve 100 in one piece, the material thickness is selected to be lower than the material thickness of the cylindrical base 94. The outer side of the cylindrical base 94 via a radially inwardly directed step 102 in the Outside of the guide sleeve 100 via. This becomes clear in particular from FIG.

The cylindrical base 94 has reinforcing ribs 104 on the outside only in its region projecting beyond the front side 96, whereas the region of the cylindrical base 94 projecting beyond the rear side 98 bears no reinforcing ribs on the outside. Instead, 100 further reinforcing ribs 105 are formed on the outside of the guide sleeves, which make it possible to keep the material thickness of the guide sleeves 100 low without thereby affecting the mechanical or thermal stability of the guide sleeves 100.

The piston pump 70 comprises a pump block 106, which is placed on the piston guide part 82, and a pump head 108 which is placed on the pump block 106. By means not shown in the drawing clamping screws of the pump block 106 and the piston guide member 82 between the pump head 108 and the swash plate housing 74 are clamped. The pump block 106 has pump chambers 112, in each of which a piston 78 is immersed and which are in fluid communication via an inlet opening 114 with a suction line 116 and via an outlet opening 118 with a pressure line 120. The pumping spaces 112 are connected to a suction inlet 122 via the suction line 116, and the pumping spaces 112 are connected to a pressure outlet 124 via the pressure line 120. Between the pumping chambers 112 and the suction line 116 is a not shown in the drawing, the expert known per se suction valve, and arranged between the pump chambers 112 and the pressure line 120 is in each case arranged in the drawing, not shown in the drawing, known in the art per se pressure valve.

When the swash plate 72 is rotated about its axis of rotation 126, the pistons 78 are reciprocally moved so that the volume of the respective pumping chamber 112 into which the pistons 78 dip periodically changes to aspirate, pressurize and dispense liquid. The pistons are in the axial direction, d. H . parallel to the axis of rotation 126 each guided by a guide sleeve 100 which is integrally connected via a cylindrical base 94 with the support wall 86. Due to its curved configuration, the support wall 86 has a high mechanical and thermal stability. The mechanical stability is additionally reinforced by the integrally formed on the support wall 86, concentric with the axis of rotation 126 aligned collar 90.

Claims

P A T E N T A N S P R E C H E

Piston pump for a high-pressure cleaning device, with a plurality of reciprocally movable pistons (18, 78), each immersed in a pump chamber (52, 112) and slidably held on a piston guide member (22, 82), the piston guide member (22, 82) a support wall (26, 86), on which a plurality of guide elements (24, 84) are arranged, each having a piston (18, 78), characterized in that the support wall (26, 86) is curved.

Piston pump according to claim 1, characterized in that the support wall (26, 86) on its the pump chambers (52, 112) facing the front side (36, 96) and on the pump chambers (52, 112) facing away from back (38, 98) in the same direction is arched.

Piston pump according to claim 1 or 2, characterized in that the support wall (26, 86) is designed in the manner of a spherical cap.

Piston pump according to claim 1, 2 or 3, characterized in that the support wall (26) in the pumping chambers (52, 112) facing direction or in the pumping chambers (52, 112) facing away from direction is curved.

Piston pump according to one of the preceding claims, characterized in that the guide elements (24) are integrally connected to the support wall (26) and on the pump chambers (52) off

facing rear side (38) of the support wall (26) of the support wall (26) protrude.

6. Piston pump according to one of the preceding claims, characterized in that the guide elements (24, 84) have a base (34, 94) which is integrally connected to the support wall (26, 86) and at least from one side of the support wall ( 26, 86) protrudes.

7. Piston pump according to one of the preceding claims, characterized in that on the outer sides of the guide elements (24, 84) radially projecting reinforcing ribs (44, 104, 105) are integrally formed.

8. Piston pump according to one of the preceding claims, characterized in that the guide elements (24, 84) have a base (34, 94) which on the pump chambers (52, 112) facing the front side (36, 96) of the supporting wall ( 26, 86) protrudes from the support wall (26, 86) and bears on its outside radially projecting reinforcing ribs (44, 104) projecting in the axial direction over the base (34, 94).

9. Piston pump according to one of the preceding claims, characterized in that the guide elements (24, 84) integrally connected to the support wall (26, 86) base (34, 94), to which in the axial direction a guide sleeve (40 , 100), which surrounds a piston (18, 78) in a form-fitting manner in the circumferential direction. Piston pump according to claim 9, characterized in that on the outside of the guide sleeve (100) radially projecting reinforcing ribs (105) are integrally formed.

Piston pump according to one of the preceding claims, characterized in that a cylindrical collar (30, 90) is integrally formed on the outer circumference of the support wall (26, 86).