DE19918394A1 - pump - Google Patents

Abstract

The pump for liquid and gaseous media comprises a suction valve arrangement which is located at the end of the pump piston ( and includes a head section (26) fixed to the piston rod (28) and a suction valve plate (24) freely movable axially between the section (28) and the pump piston (12). Pressed against the head section during the suction stroke, the suction valve plate frees flow path (which is shut during the compression stroke) from the inlet (16) via the piston (12) into the pressure chamber of the pump.

Description

The invention relates to a pump with at least one delivery arrangement, which comprises a plunger axially guided in a cylinder, which with the far end of the drive varies the volume in a pressure chamber, against the suction stroke with at least one on the pressure chamber overlying side of the plunger and during the pressure stroke via a pressure valve arrangement with at least one Exhaust port communicates.

Such pumps are for example from US 3,920,356, the US 3,809,508 and US 3,652,188.

It is the problem underlying the invention, a pump of the type mentioned in the introduction, even with high pumping power and when operating at high speeds, especially with regard to Sealing of the plunger in the cylinder works trouble-free, versatile can be used and in particular also for the promotion of gaseous Condition present media can be used.

This object is achieved by the features of claim 1 and in particular in that the plunger on its drive NEN end carries a suction valve assembly, which is axially fixed with a Kol connected rod head and one between the plunger and the head part comprises axially freely movable suction valve plate, which at Suction stroke adjacent to the head part, a flow closed during the pressure stroke  mung connection from the inlet opening on the plunger in the Releases the pressure chamber.

It has been found that with the suction valve according to the invention arrangement an optimal seal between the cylinder inner wall and the free end of the plunger attached to the piston rod bens can be achieved, the trouble-free and low wear Operation of the pump over long periods of time is permitted and in particular allows the pressure chamber opposite the inlet opening during the pressure stroke tion or a delivery space into which the inlet opening opens, also seal securely when conveying gaseous media. That invented proper provision of the axially freely movable suction valve plate between between the plunger and the head section at the start of suction hubs for releasing the flow connection from the inlet opening into the pressure chamber solely due to the inertia of the suction valve plate, which is particularly advantageous when pumping gaseous media.

According to a preferred embodiment of the invention, the plun piston for centering in the cylinder on the piston rod at least in a small amount movably mounted. Storage is preferred of the plunger designed such that at least a small axial The plunger can move relative to the piston rod.

As a result, the plunger in the cylinder can in particular with regard to the sealing effect, trouble-free operation optimally aligning, thereby tolerances regarding the guidance of the piston rod can be compensated. The possible speed of self-adjustment of the plunger in the cylinder reduces the  Wear of the seals used and thus increases with the same bend good sealing properties the life of the pump.

According to a preferred embodiment of the invention Pressure chamber on the suction side abge on the one hand over the plunger seals. The plunger is preferably at least one order catch recess provided in which a seal is arranged, which in a particularly preferred variant as a glide made of Teflon sealing ring is formed. Alternatively, a could also be used for the mechanical seal especially high temperature resistant and impact resistant plastic, for example PEEK can be used. The mechanical seal can be used an elastically deformable, between the bottom of the peripheral recess tion and the O-ring arranged in the direction of the zy the inner wall must be prestressed. In this way, an optimal Sealing effect achieved with low frictional resistance.

On the other hand, the pressure chamber is sealed via the suction vents tilplatte, the z. B. in the form of axial holes in Plunger existing flow connection in the pressure chamber closes.

In a particularly preferred variant, the cylinder is made of aluminum manufactured, the cylinder inner wall made by a suitable Conversion process is made of alumina. In the aluminum Minium oxide can also contain Teflon particles.  

This gives even better sliding properties between the cylinders inner wall and the respective used seals of the plunger or the suction valve arrangement achieved.

According to a further preferred embodiment of the invention are the end faces of the suction valve arrangement which delimit the pressure chamber and touch the pressure valve assembly at the end of the pressure stroke smoothly approximated that the volume of the pressure chamber one negligible compared to the maximum value at the end of the suction stroke bar small value and is preferably approximately reduced to zero. In a preferred variant is the minimum distance between one another the facing end faces of the pressure valve arrangement and the suction valve arrangement less than 1 mm and is preferably in the range of 0.1 to 0.2 mm.

This can result in the conveyance of gaseous media in the pressure chamber high pressures can be achieved. Another advantage is that a particularly securely closing pressure valve arrangement is used can be opened because the pressures achievable in the pressure chamber such pressure valve arrangements are sufficient.

According to a further preferred embodiment of the invention several at least essentially identical conveyor arrangements seen, the pump by connecting the inlet opening at least a conveyor arrangement with the outlet opening of at least two others Conveyor arrangements can be used as a multi-stage compressor.  

When conveying liquid media includes the invention Pump thus several basically working independently deranlagen whose plunger with a common drive can be provided. To switch to a gas production mode in a variant with three conveyor arrangements, a pressure line connected to a common outlet opening of two conveyor arrangements connected sen is connected to the inlet opening of the third conveyor arrangement become. In this way, in a first stage of the two he Most funding arrangements conveyed gas quantities by means of the third funding assembly compressed in a second stage before the gas passes through the Outlet opening of the third conveyor assembly leaves the pump. In the gas In this variant, the pump according to the invention works in the delivery mode with as a two-stage compressor.

Basically, according to the invention, by providing a larger one Number of delivery arrangements, the pump also in three or more stages ger compressor can be operated.

Because of the possibility of conveying fluids in both liquid and The pump according to the invention is also suitable in the gaseous state especially for use with carbon dioxide.

Further preferred embodiments of the invention are in the Un claims, the description and the drawing.

The invention will now be described by way of example with reference to the Drawing described. Show it:  

Fig. 1 is partially a pump according to an embodiment of the invention in a partially sectioned side view,

Fig. 2 is a view corresponding to FIG. 1 of a pump according to another embodiment of the invention,

FIGS. 3a and 3b are respectively is an illustration of a pump according to the invention for explaining a fluid handling or gas conveying mode, and

Fig. 3c shows schematically a way to arrange switching valves to the pump according to FIGS . 3a and 3b.

Fig. 1 shows a part of a pump according to an embodiment of the invention with three conveyor arrangements, the longitudinal axes 70 of which lie in a plane. The conveyor arrangements are identical in construction and each have a piston rod 28 which is driven by a common drive for executing axial reciprocating movements in a respective cylinder 10 . A common drive unit for the conveyor arrangements is not shown in Fig. 1.

Between a common holding element 40 and a common pressure housing 44 are - in Fig. 1 from left to right - a Zentrierele element 34 , a perpendicular to the longitudinal axis 70 Einlaßka channel 15 having suction housing 42 , the cylinder 10 and a Druckven valve body 18 of a pressure valve arrangement clamped by means of screw connections 46 . The suction housing 42 , the cylinder 10 and a plunger 12 delimit a delivery chamber 32 into which the inlet duct 15 having an inlet opening 16 opens. A suction line, not shown, can be connected to the inlet opening 16 .

A radially projecting, circumferential collar 18 a of the pressure valve body 18 is clamped between the end of the cylinder 10 remote from the drive and the pressure housing 44 . The drive end face of the cylinder 10 bears against a shoulder 45 of the suction housing 42 . An exit opening for the piston rod 28 from the delivery chamber 32 is limited by a ra dial inwardly projecting collar 43 of the suction housing 42 . On the drive side of the collar 43 of the suction housing 42 there is a cylindrical section of the centering element 34 , the inner surface of which faces the piston rod 28 and is provided with ring recesses 36 for seals 31 , 96 . In one of the ring recesses 36 , a sliding sealing ring 31 made of Teflon is arranged, which could additionally be prestressed in the direction of the piston rod 28, for example by means of a stainless steel spring. Instead of Teflon, a high temperature resistant and impact resistant plastic such as B. PEEK can be used for the mechanical seal 31 . On the drive side, the centering element 34 bears against a shoulder 41 of the holding element 40 . The suction housing 42 is centered for driving by the centering element 34 .

The plunger 12 is held by a screw 27 , the head of which is formed by a head part 26 , at the free end of the piston rod 28 , in such a way that the plunger 12 plugged onto the screw 27 to a small extent in the axial direction relative to the piston rod 28 is mobile. In this way, the plunger 12 , which is essentially inserted into the cylinder 10 with a precise fit, can be aligned at least to a certain degree independently of the piston rod 28 in the cylinder 10 .

The with the piston rod 28 in the axial direction firmly screwed head part 26 has a pin 26 b and a flange portion 26 a, on the side facing away from the piston rod 28 of the head part 26 flush with the pin 26 b and thus a flat end face forms. The pin 26 b cooperates with an annular projection 12 a of the plunger 12 to hold the plunger 12 on the piston rod 28 . The screw 27 can be rotated via recesses 26 c in the head part 26 by means of an appropriate tool.

An annular suction valve plate 24 is arranged on the head part 26 , the outer diameter of which is smaller than the inner diameter of the cylinder 10 . The resulting space between the outer edge of the suction valve plate 24 and the cylinder inner wall is part of a pressure chamber 14 described in more detail at another place.

The suction valve plate 24 and the head part 26 are provided with each other in the radial direction overlapping flange portions 24 a, 26 a, the suction valve plate 24 having an annular portion 24 b on the flange portion 26 a of the head part 26 is slidably mounted.

The plunger 12 is provided with a recess 90 in the form of an annular channel delimited radially by side walls extending obliquely to the longitudinal axis 70 . Axial bores 52 of the plunger 12 open into the recess 90 . The plunger 12 facing side of the suction valve plate 24 is conical in such a way that it - correspondingly the position shown in FIG. 1 - fills the recess 90 during the pressure stroke and rests sealingly on the inclined side walls thereof, annular sealing elements 92 being provided for sealing.

The sum of the axial heights of the flange portions 24 a, 26 a of the suction valve plate 24 and the head part 26 is smaller than the axial height of the part of the pin 26 b protruding from the plunger 12 . As a result, the suction valve plate 24 between the head part 26 and the Plungerkol ben 12 is axially freely movable. Between the overlapping flange sections 24 a, 26 a in the radial direction, a gap or space 50 is present in the state according to FIG. 1.

Fig. 1 shows the plunger 12 and the suction valve plate 24 and the head portion 26 formed suction valve at top dead center, ie at the end of the compression stroke. The suction valve plate 24 rests on the plunger 12 and fills the recess 90 in such a way that the axial bores 52 in the plunger 12 , which open radially outside the tapering end of the piston rod 28 into the delivery chamber 32 , are closed by the suction valve plate 24 . During the pressure stroke there is no flow connection between the axial bores 52 in the plunger 12 and the annular space between the outer edge of the suction valve plate 24 and the cylinder inner wall.

At the top dead center shown in Fig. 1, the suction valve assembly 24 , 26 has a perpendicular to the longitudinal axis 70 , flat end face, which is formed by the piston rod 28 facing away from the sides of the head part 26 and the suction valve plate 24 . The conveyor assembly is designed so that at top dead center, the end face of the suction valve assembly 24, 26 in such a way close to that of the suction valve 24, 26 to be facing front end of the - described in more detail below - pressure valve assembly 18 is moved up 20 that a very small, in Fig. 1 not recognizable axial space between the two end faces is present, which forms part of the minimized in this state Druckkam mer 14 of the conveyor arrangement. At top dead center, the pressure chamber 14 is thus essentially formed by the annular space between the outer edge of the suction valve plate 24 and the inner cylinder wall.

The indicated in Fig. 1 by an "A" distance between the facing end faces of the suction valve assembly 24 , 26 and the pressure valve assembly 18 , 20 at top dead center is about 0.1 to 0.2 mm, so that the end faces do not touch .

The pressure valve body 18 is part of a pressure valve assembly, which in addition comprises a pressure valve element 20 , which has approximately the shape of a cap with a cut cap and ge from a coil spring 21 ge from the pressure chamber 14 side of the Druckventilkör pers 18 is biased. The spring 21 is supported on a sleeve-shaped support element 13 which is screwed to the pressure valve body 18 and communicates via openings in the side wall with the outlet space 23 com.

A central opening 61 is formed in the pressure valve body 18 , the boundary surface of which widens in a funnel shape in the direction of the outlet space 23 in accordance with the shape of the pressure valve element 20 and in this way forms a valve seat.

The pressure valve assembly 18 , 20 is dimensioned such that in the closed state shown in FIG. 1, the suction valve assembly 24 , 26 facing, from the pressure valve body 18 and the pressure valve element 20 jointly formed end face one - in the variant explained below with chamfer 94 only approximately - is a flat surface that is perpendicular to the longitudinal axis 70 .

In a modification, the end face of the pressure valve body 18 can be beveled, as is indicated in FIG. 1 by dashed lines 94 , the illustration being exaggerated for clarification. From the bevel From a wedge-shaped, in the direction of the longitudinal axis 70 ge slightly widening annular gap between the opposite end faces of the suction valve assembly 24 , 26 and the Druckventilanord voltage 18 , 20 is available. In this way it is ensured that during the pressure stroke liquid flows in the direction of the longitudinal axis 70 and through the opening 61 without causing congestion or a blocking of the piston arrangement due to the liquid present between the end faces.

The on the side facing away from the pressure chamber 14 of the pressure valve body 18 components of the pressure valve assembly are located in the pressure valve body 18 and the pressure housing 44 be limited outlet space 23 , to which an outlet opening 22 pointing to the radial outlet channel 25, a pressure line, not shown, can be connected is.

The area of the cylinder 10 surrounded by the pressure housing 44 is provided with a spiral groove 48 which can be supplied via an inlet 47 with a cooling fluid, for which water is preferably used. Outside of the pressure housing 44 , the cylinder 10 is provided on its outside with cooling fins 49 .

The seal between the suction housing 42 and the centering element 34 , between the suction housing 42 and cylinder 10 and between the pressure housing 44 , cylinder 10 and pressure valve body 18 is provided by O-rings 60 arranged in corresponding circumferential recesses.

To seal the pressure chamber 14 relative to the delivery chamber 32 , the plunger 12 is provided with groove-shaped circumferential recesses 30 , in which mechanical seals 31 made of Teflon are arranged, and instead of Teflon a particularly high-temperature-resistant and impact-resistant plastic, for example PEEK, could also be used. For biasing the closer to the suction valve plate 24 seal ring 31 in the direction of the cylinder inner wall in an accordingly larger depth groove 30, an elastically deformable O-ring is inserted.

To generate optimal friction conditions between the sliding seal rings 31 and the cylinder inner wall, the cylinder 10 is made of aluminum, the cylinder inner wall made of aluminum oxide, which by a conversion process, for. B. a hard coat conversion is generated on the cylinder inner wall. Furthermore, Teflon particles are embedded in the aluminum oxide forming the inner wall of the cylinder.

The suction valve plate 24 and the pressure valve element 20 are made of PEEK. In principle, other, in particular high-temperature resistant and / or impact-resistant, plastic materials can also be used.

The delivery arrangement according to the invention is suitable for delivering fluids both in the liquid and in the gaseous state. During the intake stroke the plunger 26 1 12 moves together with the Saugven tilanordnung 24, in Fig. To the left so that the axially floating suction valve plate 24 rests on the head part 26, the gap 50 is not more that is available. There is thus a flow connection from the delivery chamber 32 into the pressure chamber 14 via the axial bores 52 in the plunger 12 and via a non-existent annular gap in the state of FIG. 1 radially outside the conical section from the suction valve plate 24 during the suction stroke.

In this way, the enlarging pressure chamber 14 is filled with liquid or gaseous fluid during the suction stroke, which flow through a suction line (not shown) coupled to the inlet opening 16 , the inlet channel 15 , the delivery chamber 32 and the plunger 12 and the suction valve arrangement 24 , 26 can. A Strömver connection from the pressure chamber 14 into the outlet space 23 through the opening 61 of the pressure valve body 18 is closed by the pressure valve element 20 , which is pressed by means of the spring 21 on the valve seat serving on this side as a valve body 18 .

During the subsequent pressure stroke, the Saugventilanord voltage 24 , 26 is automatically switched to a pressure mode due to the free axial mobility of the suction valve plate 24 , in which the suction valve plate 24 filling the recess 90 abuts the plunger 12 and - as shown in FIG. 1 - the axial bores 52 in the plunger ben 12 closes.

If liquid was previously sucked into the pressure chamber 14 , then the pressure valve arrangement 18 , 20 opens at the beginning of the pressure stroke, so that the liquid through the opening 61 of the pressure valve body 18 past the pressure valve element 20 lifted from the valve seat into the outlet space 23 and over the Outlet channel 25 and the outlet opening 22 can flow into the pressure line, not shown.

If a gaseous medium was previously sucked into the pressure chamber 14 , the gas in the pressure chamber 14 is compressed during the pressure stroke until there is sufficient pressure in the pressure chamber 14 to overcome the force applied by the spring 21 to the pressure valve element 20 , whereupon the gas can flow into the pressure line connected to the outlet opening 22 .

The conveyor arrangement according to the invention is advantageously dead space-optimized, since at the end of the pressure stroke the pressure chamber 14 only from the annular space between the outer edge of the suction valve plate 24 and the cylinder inner wall and from the minimum gap at "A" in Fig. 1 between the flat end faces the suction valve assembly 24 , 26 and the pressure valve assembly 18 , 20 is formed. In the recesses 26 c, plug elements are inserted after the assembly — not shown in FIG. 1 — so that the recesses 26 c do not contribute to the pressure chamber 14 .

The dead space optimization according to the invention also has in particular Conveying gaseous media results in very good efficiency.

The embodiment of a pump according to the invention shown in FIG. 2 differs from that of FIG. 1 in particular by the design of the plunger 12 and the suction valve arrangement formed by the suction valve plate 24 and a head part 98 . The aspects corresponding to the exemplary embodiment in FIG. 1 are not discussed in more detail below.

In this embodiment, the suction valve plate 24 is surrounded by the ring-shaped head part 98 , in turn flange portions 24 a, 98 a overlapping one another in the radial direction are provided. The head part 98 is screwed with a sleeve section 98 b onto a ring section 12 b projecting axially from the end of the plunger 12 remote from the drive and is axially displaceably mounted with a flange section 98 a on a ring section 24 b of the suction valve plate 24 . With its flange section 24 a, the suction valve plate 24 bears against the inside of the ring section 12 b of the plunger 12 .

The axial mobility of the suction valve plate 24 is ensured according to the embodiment of FIG. 1 by the gap 50 , which is present during the pressure stroke between the flange portions 24 a, 98 a overlapping in the radial direction.

Both end faces of the suction valve plate 24 and of the plunger 12 are flat and run perpendicular to the longitudinal axis 70 . Also in this embodiment, the pressure valve body 18 can be provided with a bevel 94 - indicated by the dashed lines. In the position shown in Fig. 2 at the end of the compression stroke, the axial bores 52 are closed in the plunger 12 by the suction valve 24th

The suction valve plate 24 has a central opening 99 , the diameter of which is somewhat larger than that of the head part 26 of the screw 27 , which in this embodiment is flush with the end face of the plunger piston 12 . In the opening 99 protrudes - its closed position taking - pressure valve element 20 , which is designed in this embodiment as a complete dome.

During the suction stroke, both liquid and gaseous medium can be supplied via the delivery chamber 32 , the axial bores 52 in the plunger 12 , a gap that is not present in the state of FIG. 2 between the plunger 12 and the suction valve plate 24 and the opening 99 into the pressure chamber 14 stream.

Not shown in Fig. 2 are plug elements, which are inserted after assembly Mon ge in the recesses 26 c of the screw head part 26 and fill the opening 99 such that a fluid flow from the axial bores 52 through the opening 99 in the suction stroke during the suction stroke Pressure chamber 14 is possible, but during the pressure stroke the pressure chamber 14 is essentially formed by the gap indicated by an "A" in FIG. 2 between the suction valve plate 24 and the pressure valve body 18 . The distance between the facing end faces of these two components is approximately 0.1 to 0.2 mm at the end of the pressure stroke. In this way, the conveyor arrangement according to the invention from FIG. 2 is advantageously optimized for dead space and optimally suited for conveying gaseous media with high efficiency.

It is also possible to design the pressure valve element 20 or its portion protruding through the opening 99 in such a way that as large a part of the space as possible due to the opening 99 is filled out.

Fig. 3a shows schematically how a pump according to the invention, the three ne by side arranged, a common drive unit 80 having de conveying assemblies comprises Betrie in a liquid delivery mode is ben. Both in Fig. Lower conveyor assemblies 3a have single Lich either an inlet port or an outlet port 16 and 22 are inside the housing by in Fig. 3 only indicated channels 11 on the input side and output side connected to each other. The third, above re conveyor arrangement has both its own inlet opening 16 and its own outlet opening 22 .

In liquid delivery mode, the three conveyor assemblies are connected to a suction line Since they share 72 and is via the tung 72 Sauglei liquid delivered via a common pressure line 74 from transported. Alternatively, two suction lines 72 or pressure lines 74 which are not connected to one another can also be provided.

To operate the pump according to the invention in a gas delivery mode in which the pump operates as a two stage compressor, the common rail as shown in FIG. 3b connected 74 of the two in Fig. 3b lower conveyor assemblies to the inlet opening 16 in Fig. 3b upper conveyor assembly. The gaseous medium, for example carbon dioxide, which is conveyed via the common suction line 72 connected to the inlet opening 16 of the lower conveying arrangement, is supplied to the third, upper conveying arrangement after the outlet from the first stage of the pump formed by the two lower conveying arrangements . The third delivery arrangement forms the second stage of the pump operating in this gas delivery mode as a compressor.

The gas quantities conveyed by the two conveying arrangements of the first stage are thus compressed together in the second stage and transported away via the pressure line 74 of the conveying arrangement forming the second stage.

Fig. 3c shows a common representation of both the liquid delivery mode and the gas delivery mode and the arrangement of valves M1, M2, M3 and M4 in the respective lines. While in the liquid delivery mode the valves M1, M2 are closed and the valves M3, M4 are open, the gas delivery mode is characterized in that the valves M1, M2 are open and the valves M3, M4 are closed.

By providing the internal channels 11 , the number of valves required to switch between the two operating modes is minimized.

Reference list

10th

cylinder

11

channel

12th

Plunger

12th

a ring projection

12th

b ring section

13

Support element

14

Pressure chamber

15

Inlet duct

16

Inlet opening

18th

Pressure valve body

18th

a collar

20th

Pressure valve element

21

feather

22

Outlet opening

23

Outlet space

24th

Suction valve plate

24th

a flange section

24th

b ring section

25th

Exhaust duct

26

Headboard

26

a flange section

26

b cones

26

c recess

27

screw

28

Piston rod

30th

Circumferential recess

31

Mechanical seal

32

Funding area

33

O-ring

34

Centering element

36

Ring recess

40

Holding element

41

shoulder

42

Suction housing

43

collar

44

Pressure housing

45

shoulder

46

Screw connection

47

Inlet

48

Cold room, spiral groove

49

Cooling fins

50

gap

52

Axial bore

60

O-ring

61

opening

70

Longitudinal axis

72

Suction line

74

Pressure line

80

Drive unit

90

Recess

92

Sealing element

94

bevel

96

poetry

98

Headboard

98

a flange section

98

b sleeve section

99

opening
A distance
M1 valve
M2 valve
M3 valve
M4 valve

Claims (33)

1. Pump with at least one delivery arrangement, which comprises a plunger ( 12 ) which is axially guided in a cylinder ( 10 ) and which, with its end remote from the drive, varies the volume in a pressure chamber ( 14 ) which during the suction stroke with at least one on the pressure chamber ( 14 ) opposite inlet opening ( 16 ) on the opposite side of the plunger ( 12 ) and communicates with at least one outlet opening ( 22 ) via a pressure valve arrangement ( 18 , 20 ) during the pressure stroke, characterized in that the plunger ( 12 ) has a suction valve arrangement ( 12 ) at its end remote from the drive. 24 , 26 ; 24 , 98 ), which has an axially fixedly connected to a piston rod ( 28 ) head part ( 26 ; 98 ) and between the plunger ( 12 ) and the head part ( 26 ; 98 ) axially freely movable suction valve plate ( 24 ) which, during the suction stroke on the head part ( 26 ; 98 ), adjoins a flow connection which is closed during the pressure stroke, from the inlet opening ( 16 ) via the plunger piston ( 12 ) in the pressure chamber ( 14 ) releases. 2. Pump according to claim 1, characterized in that the plunger ( 12 ) for centering in the cylinder ( 10 ) on the piston rod ( 28 ) is at least to a small extent movably mounted. 3. Pump according to claim 1 or 2, characterized in that the pressure chamber ( 14 ) is sealed to the suction side via the plunger ( 12 ). 4. Pump according to claim 3, characterized in that the plunger ( 12 ) comprises at least one preferably groove-shaped circumferential recess ( 30 ), in which a preferably at least partially made of Teflon or PEEK seal ( 31 , 33 ) is arranged. 5. Pump according to claim 4, characterized in that at least one seal comprises a mechanical seal ( 31 ). 6. Pump according to claim 4 or 5, characterized in that at least one seal is preferably biased in the direction of the cylinder inner wall by means of a in the peripheral recess ( 30 ) angeord Neten, elastically deformable O-ring ( 33 ). 7. Pump according to at least one of the preceding claims, characterized in that the pressure chamber ( 14 ) delimiting end faces of the suction valve arrangement ( 24 , 26 ; 24 , 98 ) and the pressure valve arrangement ( 18 , 20 ) are so close to one another at the end of the pressure stroke, that the volume of the pressure chamber ( 14 ) is reduced to a value which is negligible compared to the maximum value at the end of the suction stroke and preferably approximately to zero. 8. Pump according to at least one of the preceding claims, characterized in that the minimum distance between mutually facing end faces of the pressure valve arrangement ( 18 , 20 ) and the suction valve arrangement ( 24 , 26 ; 24 , 98 ) is less than 1 mm and preferably in the range from 0.1 to 0.2 mm. 9. Pump according to at least one of the preceding claims, characterized in that the cylinder ( 10 ) is made of aluminum, the cylinder inner wall preferably consisting of aluminum oxide formed in particular by a hard-coat conversion. 10. Pump according to at least one of the preceding claims, characterized in that in the cylinders wall, in particular in the cylinder inner wall forming aluminum umoxid, Teflon particles are embedded. 11. Pump according to at least one of the preceding claims, characterized in that at least the suction valve plate ( 24 ) of the suction valve assembly is made of a particularly high temperature-resistant and / or impact-resistant plastic, preferably made of PEEK. 12. Pump according to at least one of the preceding claims, characterized in that the suction valve plate ( 24 ) is annular and is preferably arranged in the radial direction with a precise fit on the head part ( 26 ). 13. Pump according to claim 12, characterized in that the outer diameter of the suction valve plate ( 24 ) is smaller than the inner diameter of the cylinder ( 10 ). 14. Pump according to claim 12 or 13, characterized in that the plunger ( 12 ) facing side of the suction valve plate ( 24 ) is cone-like and during the pressure stroke sealing on oblique to the longitudinal axis ( 70 ) of the cylinder ( 10 ) extending side walls of a recess Mung ( 90 ) of the plunger ( 12 ) abuts, in which at least one axial bore ( 52 ) of the plunger ( 12 ) opens. 15. Pump according to at least one of claims 12 to 14, characterized in that the Druckventilan arrangement ( 18 , 20 ) facing sides of the suction valve plate ( 24 ) and the head part ( 26 ) during the pressure stroke together an at least essentially flat end face of the suction valve arrangement ( 24 , 26 ) form. 16. Pump according to at least one of claims 1 to 11, characterized in that the head part ( 28 ) as the suction valve plate ( 24 ) surrounding and with the non-drive end side of the plunger ( 12 ) axially fixed, in particular screw-on, ring element is formed. 17. Pump according to at least one of the preceding claims, characterized in that the suction valve plate ( 24 ) and the head part ( 26 ; 98 ) with each other in the radial direction overlap penden flange sections ( 24 a, 26 a; 24 a, 98 a) are provided . 18. A pump according to at least one of the preceding claims, characterized in that the Druckventilanord voltage (18, 20) has an at least partially, the pressure chamber (14) confining pressure valve body (18) and a pressure valve element (20) which during the suction stroke against the Druckkam mer ( 14 ) opposite side of the pressure valve body ( 18 ) is pre-tensioned and from a pressure generated during the pressure stroke in the pressure chamber ( 14 ) releases at least one fluid connection from the pressure chamber ( 14 ) to the outlet opening ( 22 ). 19. Pump according to claim 18, characterized in that the suction valve assembly ( 24 , 26 ; 24 , 98 ) facing sides of the pressure valve element ( 20 ) and the pressure valve body ( 18 ) during the suction stroke together an at least approximately flat end face of the Druckventilanord voltage ( 18 , 20th ) form. 20. Pump according to claim 18, characterized in that the preferably dome-shaped pressure valve element ( 20 ) during the pressure stroke on the suction valve assembly ( 24 , 26 ; 24 , 98 ) facing side of the pressure valve body ( 18 ) protrudes and into the pressure chamber ( 14 ) protrudes into it. 21. Pump according to at least one of the preceding claims, characterized in that at least the pressure valve element ( 20 ) of the pressure valve arrangement ( 18 , 20 ) made of a particularly high temperature resistant and impact-resistant plastic, preferably made of PEEK. 22. A pump according to at least one of the preceding claims, characterized in that the piston rod (28) derraum by communicating with the inlet opening (16) För (32) and surrounded outside the conveying space (32) by an annular centering element (34) whose inner surface facing the piston rod ( 28 ) is provided with at least one seal ( 38 ) arranged in an annular recess ( 36 ), preferably at least partially made of Teflon or PEEK. 23. Pump according to claim 22, characterized in that at least one seal ( 38 ) comprises a mechanical seal. 24. Pump according to claim 22 or 23, characterized in that at least one seal ( 38 ) is preferably biased by means of a steel spring in the direction of the piston rod ( 28 ). 25. Pump according to at least one of claims 22 to 24, characterized in that the centering element ( 34 ) between a holding element ( 40 ) and the cylinder ( 10 ), preferably one adjoining the drive side of the cylinder ( 10 ) and preferably by means of the centering element ( 34 ) centered Saugge housing ( 42 ) is arranged. 26. Pump according to at least one of claims 22 to 25, characterized in that the centering element ( 34 ), the cylinder ( 10 ) and the pressure valve arrangement ( 18 , 20 ) between the holding element ( 40 ) and a pressure housing ( 44 ) by means of least a screw connection ( 46 ) are clamped in the axial direction. 27. Pump according to at least one of the preceding claims, characterized in that at least between egg nem pressure housing ( 44 ) and one of the pressure housing ( 44 ) vice area of the cylinder ( 10 ) at least part of a preferably water-operable cooling circuit forming cooling space ( 48 ) is available. 28. Pump according to claim 27, characterized in that the cooling space in the form of at least one on the outer surface of the cylinder ( 10 ) is formed th spiral groove ( 48 ). 29. Pump according to at least one of the preceding claims, characterized in that it comprises several preferably at least substantially identical conveyor arrangements and by connecting the inlet opening ( 16 ) at least one För deranordung with the outlet opening ( 22 ) at least one other conveyor arrangement as a multi-stage compressor in particular Promotion of gaseous fluids can be used. 30. Pump according to claim 29, characterized in that three delivery arrangements are preferably provided with approximately in one plane longitudinal axes ( 70 ), wherein in a liquid delivery mode each an inlet opening ( 16 ) with a suction line ( 72 ) and each outlet opening ( 22 ) a pressure line ( 74 ) and, in a gas delivery mode, an inlet opening ( 16 ) is connected to two outlet openings ( 22 ). 31. Pump according to claim 29 or 30, characterized in that at least two conveyor arrangements have a single common inlet opening ( 16 ) and / or a single common outlet opening ( 22 ). 32. Pump according to the preamble of claim 1, characterized in that the pressure chamber ( 14 ) delimiting end faces of the suction valve arrangement ( 24 , 26 ; 24 , 98 ) and the pressure valve arrangement ( 18 , 20 ) at the end of the pressure stroke are so close to each other that the volume of the pressure chamber ( 14 ) is reduced to a value that is negligible compared to the maximum value at the end of the suction stroke and preferably approximately to zero. 33. Pump according to claim 32 with the features of at least one of the Claims 1 to 31.