U.S. patent application number 10/257906 was filed with the patent office on 2004-02-12 for oscillation piston pump.
Invention is credited to Bahnen, Rudolf, Beyer, Christian, Boy, Hermann, Schonborn, Frank.
Application Number | 20040028532 10/257906 |
Document ID | / |
Family ID | 7639120 |
Filed Date | 2004-02-12 |
United States Patent
Application |
20040028532 |
Kind Code |
A1 |
Beyer, Christian ; et
al. |
February 12, 2004 |
Oscillation piston pump
Abstract
The invention relates to an oscillating piston pump (1), in
particular to an oscillating piston vacuum pump. The invention aims
to create a range of pumps of this type comprising members which
exhibit a different final pressure behaviour and/or a different
pumping capacities. To achieve this, the range consists of several
identically constructed modules (2) of an oscillating piston pump
that are connected in parallel and/or in series, according to
customer requirements and each module is equipped with an
oscillating piston drive.
Inventors: |
Beyer, Christian; (Koln,
DE) ; Boy, Hermann; (Kerpen, DE) ; Bahnen,
Rudolf; (Roetgen, DE) ; Schonborn, Frank;
(Koln, DE) |
Correspondence
Address: |
Thomas E Kocovsky Jr
Fay Sharpe Fagan Minnich & McKee
1100 Superior Avenue
Seventh Floor
Cleveland
OH
44114-2518
US
|
Family ID: |
7639120 |
Appl. No.: |
10/257906 |
Filed: |
September 3, 2003 |
PCT Filed: |
January 16, 2001 |
PCT NO: |
PCT/EP01/00422 |
Current U.S.
Class: |
417/62 ;
417/418 |
Current CPC
Class: |
F04B 35/045 20130101;
F04B 35/06 20130101; F04B 41/06 20130101 |
Class at
Publication: |
417/62 ;
417/418 |
International
Class: |
F04B 023/04 |
Foreign Application Data
Date |
Code |
Application Number |
Apr 18, 2000 |
DE |
100 19 106.1 |
Claims
1. Oscillating piston pump (1), in particular an oscillating piston
vacuum pump, wherein it consists of several modules (2) of the same
design of an oscillation piston pump which are, depending on
customer requirements, connected in parallel and/or in series, each
module being equipped with a drive for the oscillating piston.
2. Pump according to claim 1, wherein the oscillating piston pump
modules (2) are affixed jointly on to a rail (3).
3. Pump according to claim 2, wherein the inlet and the outlet (55,
56) of the oscillating piston pump modules (2) are located in the
area of one of the two face sides, where the modules (2) are
affixed at this face side to the rail (3), where in the instance of
modules (2) connected in parallel there is located in the rail each
a joint inlet channel (57) and a joint outlet channel (58) and
where one opening of the inlet channel forms the inlet (9) of the
pump (1) and one opening of the outlet channel forms the outlet
(10) of the pump (2).
4. Pump according to claim 2, wherein in the rail (3) there are
provided intermediate channels (61) which in the instance of series
connected modules (2) join the outlet (56) of one module (2) to the
inlet (55) of the next module (2).
5. Pump according to claim 2, wherein one of the face sides of the
oscillating piston pump modules (2) is each equipped with the inlet
(55) and the further face sides are each equipped with the outlet
(56) and where two rails (4, 5) are present of which one is
equipped with the joint inlet channel (57) and the other with a
joint outlet channel (58).
6. Pump according to claim 2, 3, 4 or 5, wherein the rail(s) (3, 4,
5) has/have carrying functions.
7. Pump according to one of the claims 2 to 6, wherein the rail(s)
(3, 4, 5) is/are a component of a frame, a cart (15, 16) or
alike.
8. Pump according to one of the claims 2 to 7, wherein the rail(s)
(3, 4, 5) is/are equipped with further channels (59) serving the
purpose of accommodating electrical cables.
9. Pump according to one of the claims 2 to 8, wherein the rail(s)
(3, 4, 5) is/are formed by an extruded profile component.
10. Pump according to one of the claims 1 to 9, wherein there are
located in the module (2) two or more pumping stages and where
these may be connected, depending on customer requirements,
parallel or in series.
11. Pump according to one of the above claims, wherein there is
located upstream of the oscillating piston pump (1) a high-vacuum
pump (12) and where the inlet of the high-vacuum pump (12) forms
the inlet (9) of the pumping system.
12. Pump according to claim 10 and one of the claims 2 to 8,
wherein the high-vacuum pump (12) is also affixed to the rail (3)
or at one of the rails (4, 5) respectively.
13. Pump according to one of the above claims, wherein all modules
(2) of the oscillating piston vacuum pump (1) and the possibly
present high-vacuum pump (12) are equipped with a joint power
supply, display and/or control unit (14).
14. Pump according to one of the above claims, wherein the modules
(2) are equipped with an outer casing (45) in which there are
located bores (51, 52) extending in parallel to the piston (21) of
which one forms the inlet bore and the other the outlet bore.
15. Pump according to claim 12, wherein the outer casing (45) is
designed to be oval in shape and where each one of the bores (51,
52) is located in the area of the thicker wall sections.
16. Method for operating a pump (1) according to one of the claims
1 to 13, wherein, the linear drives of the individual modules (2)
can be so driven that the oscillating pistons (21) of the pump
modules (2) perform in pairs an opposing motion with respect to
each other.
17. Method for manufacturing oscillating piston pumps (1), in
particular oscillating piston vacuum pumps with different pumping
capacities, wherein several oscillating piston pump modules (2) of
the same design are connected in parallel and/or in series and
where the number of modules connected in parallel and/or in series
is so selected that the sum of their pumping capacities corresponds
to the desired pumping capacity or so that the final pressure
corresponds to the desired final pressure.
18. Method according to claim 17, wherein they are mounted next or
above each other to a joint (3) or to two rails (4, 5) and where
the inlet openings (55) of the modules (2) are joined in a sealed
manner to a joint inlet channel (57) and the outlet openings (56)
of the modules (2) to a joint outlet channel (58).
Description
[0001] The present invention relates to an oscillating piston pump,
in particular to an oscillating piston vacuum pump, a method for
operating a pump of this kind as well as a method for manufacturing
a family of pumps of this kind.
[0002] Oscillating piston pumps are known from DE 41 02 710 A1.
They exhibit a piston which reciprocates in a cylinder. A linear or
reciprocating piston drive serves the purpose of driving the
piston, said drive being equipped with electromagnetic means
encompassing the piston.
[0003] When employing pumps of this kind as vacuum pumps these may,
when suitably selecting the material for the piston and for the
cylinder, be operated in a dry manner, i.e. free of lubricant. In
piston vacuum pumps in which a crank shaft drive is provided as the
means for driving the pistons, this advantage is already being
utilised.
[0004] In vacuum pumps it is generally common to manufacture and
offer a pump operating according to a certain pumping principle in
several sizes--swept volumes, single or multi-stage, so as to be
able to meet the customers demand for pumps having differing final
pressures and/or pumping capacities. The development and
manufacture of such families of pumps is involved.
[0005] It is the task of the present invention to create an
oscillating piston pump, in particular an oscillating piston vacuum
pump, in which the detailed relatively highly involved development
and manufacturing process for arranging a family of pumps covering
a broad pumping capacity range and/or final pressure range, is no
longer necessary.
[0006] This task is solved through the present invention in that
this pump, in particular the vacuum pump, consists of several
construction-wise identical modules of an oscillating piston pump
which may, depending on customers requirements, be connected in
parallel and/or in series and which each exhibit an oscillating
piston drive.
[0007] For a pump of this kind it is required to develop and
manufacture only a module equipped with piston and linear drive. If
oscillating piston pumps of this kind are demanded with final
pressures lower than the final pressure attainable by the single
module, several such modules may be connected in series. If
oscillating piston pumps are demanded with a pumping capacity
higher than that of a single module, then several such modules may
be connected in parallel. If, for example the single module has a
pumping capacity of 1.5 m.sup.3/h then pumps having a pumping
capacity of 3, 4.5 or 6 m.sup.3/h can be produced by connecting 2,
3 or 4 pump modules in parallel. Additional benefits are:
[0008] use of the same parts for pumps with different final
pressures and for a broad pumping capacity range, whereby through
increased production quantities a reduction of costs is
attained;
[0009] use in different variants: paralleled modules; series
connected modules; in part in parallel, in part series connected
modules;
[0010] owing to the multitude of identical parts, the complexity of
having to stock individual components is reduced;
[0011] there result simplified spare parts systems, and maintenance
is simplified as well;
[0012] the necessity of having to extrapolate the linear drive
technology to demanding geometrical regions can be dispensed
with.
[0013] In all, with only one module, pump families can be created
the members of which have differing final pressure characteristics
and/or differing pumping capacities. The module itself is a member
of the family. It has the highest final pressure and the lowest
pumping capacity.
[0014] Further advantages and details of the present invention
shall be explained with reference to the schematically depicted
examples of embodiments in drawing FIGS. 1 to 10. Depicted are
in
[0015] drawing FIGS. 1 to 4 views of different embodiments for the
pumps according to the present invention,
[0016] drawing FIGS. 5.sup.1) to 7 sectional views through a single
module of the pumps according to the present invention, .sup.1)
Translator's note: The German text states "4" here whereas "5"
would be in line with the drawing figures. Therefore the latter has
been assumed for the translation.
[0017] drawing FIGS. 8 to 10 schematic representations of possible
variants.
[0018] The embodiments of the pump according to the present
invention depicted in drawing FIGS. 1 to 4 are designated as 1,
their oscillating piston pump modules as 2. The modules are affixed
to a rail 3 (drawing FIGS. 1, 2, 4) or to two rails 4, 5 which on
the one hand have a carrying function and which on the other hand
are equipped with channels which may be employed as a joint inlet
channel, a joint outlet channel, as intermediate channels or also
as channels for accepting electrical cables.
[0019] The drawing FIGS. 1 and 2 depict views of an embodiment with
three modules 2. These are arranged over each other on a rail 3
which is arranged vertically and which is equipped with a foot 6
extending under the modules 2. Inlet and outlet of the modules 2
each open out on one of their face sides. At this face side the
modules are affixed to the rail 3. The rail 3 is equipped with
channels extending in the longitudinal direction. One of these
forms the inlet channel to which all inlets of the modules 2 are
joined in a sealed manner. A second forms the outlet channel which
is joined to all outlets of the modules. On the side of the bottom
the inlet channel and the outlet channel are closed. In the area of
the upper face side of rail 3 they are equipped with connecting
ports 7, 8. The port 7 assigned to the inlet channel forms the
inlet 9, the port 8 assigned to the outlet channel forms the outlet
10 of the pump 1 according to the present invention.
[0020] The embodiment of the pump 1 in accordance with drawing
FIGS. 1 and 2 is equipped with three modules 2. Its pumping
capacity is equivalent to the sum of the pumping capacities of the
identical individual modules. When manufacturing pumps 1 of this
kind with a deviating pumping capacity, the number of modules 2 may
be varied correspondingly.
[0021] Drawing FIG. 3 depicts an embodiment in which the modules 2
are affixed to two rails 4, 5. The rails are supported by a joint
foot 6. In an embodiment of this kind the first rail 4 may accept
the inlet channel and the second rail 5 the outlet channel. For
this it is required that the inlet and the outlet of the modules 2
be located on different face sides. Rail 5 contains the outlet
channel with the connecting port 8 forming outlet 10.
[0022] In the example of an embodiment in accordance with drawing
FIG. 3 there is located upstream of the two modules 2 a high-vacuum
pump 12 (for example, a friction vacuum pump like a turbomolecular,
molecular or compound pump). This pump is affixed to rail 4. Its
outlet is joined to the inlet channel in rail 4. In this instance
the inlet channel is closed at both face sides of the rail 4. The
inlet port 13 of the high-vacuum pump 12 forms the inlet 9 of the
pump system in accordance with drawing FIG. 3.
[0023] Drawing FIG. 3 depicts by way of an example that a joint
power supply, control and/or display unit for several or all pumps
2, 12 may be affixed to one of the rails 4, 5. The required cables
can be run through channels located in the rails 4, 5. A unit 14 of
the kind detailed utilised jointly for all pumps may be present
also for the pumps 1 in accordance with drawing FIGS. 1, 2 or 4
having only one rail 3 and said unit may be affixed to this rail 3.
A joint control.sup.2) unit 14 for the modules 2, permits
especially pumps 1 equipped with an even number of modules 2 to be
operated free of vibrations. In accordance with the present
invention this is attained in that the pistons of the modules 2 are
operated in pairs at identical frequencies and with opposing moving
directions. .sup.2) Translator's note: The German text states
"Stuergerat" here whereas "Steuergerat" would be correct. Therefore
the latter has been assumed for the translation.
[0024] Drawing FIG. 4 also depicts an embodiment with two
oscillating piston pump modules 2 and a high-vacuum pump 12. The
difference compared to drawing FIG. 3 is, that only one rail 3 is
provided in which the joint inlet channel and the joint outlet
channel are located. The inlet channel is closed on both sides. The
inlet port of the high-vacuum pump 12 forms the inlet 9 of the pump
1. The outlet channel opens out into the outlet port 8 on the face
side, said outlet port forming the outlet 10 of the pump 1. Also
different compared to drawing FIG. 3 is, that the rail 3 is
supported on a mobile underpart 15 with handle 16--here a kind of
sack trolley. Finally, a unit 14 is not depicted in drawing FIG.
4.
[0025] Drawing FIGS. 5, 6 and 7 schematically depict the
construction of an example of an embodiment for an oscillating
piston pump module 2. In drawing FIGS. 5, 6 longitudinal sectional
views through a module 2 are depicted perpendicular with respect to
each other. These views depict on the one hand a side view of rail
3 (drawing FIG. 5) and on the other hand a sectional view (drawing
FIG. 6). Drawing FIG. 7 is a sectional view through the module 2 in
accordance with drawing FIGS. 5, 6 at the level of the line
VII-VI.
[0026] In drawing FIGS. 5 to 7 the centrally arranged piston is
designated as 21. The piston is guided in cylinder sections 22, 23
axially spaced apart. The piston 21 carries a permanent magnetic
ring 24. This ring 24 is located between permanent magnetic rings
25, 26 being components of the stator 27. The sum of the distances
between the ring 24 and the ring 25, 26 corresponds to the
amplitude of the piston's motion. A further component of the stator
27 is a yoke component 28 encompassing coils 29 and said yoke
component being assigned to the permanent magnetic rings 24, 25,
26.
[0027] Together with a first casing 31 encompassing the stator 27,
the module 2 is of a rotationally symmetrical design. In the area
of the piston's face sides 21 the casing 31 forms the compression
chambers 32 and 33. Located to the side next to the compression
chambers 32, 33 is each a gas inlet chamber 34 and 35 respectively.
Via inlet gaps 36 and 37 respectively in the cylindrical sections
22, 23 said gas inlet chambers open out into the respective
compression chamber 32 and 33. The motion of the piston effects
opening and closing of the inlet gaps 36, 37. Assigned to the
compression chambers 32, 33 are on the face side each an outlet
valve 41 and 42 respectively these also being actuated by.sup.3)
piston 21. These are located in outlet chambers 43, 44 being formed
in a second outer casing 45 accepting the first casing 31. Outlet
valves of this kind are known only from DE 196 34 517 A1. A
flexible or flexibly suspended valve disk 46 is actuated by piston
21. In the presented example of an embodiment, the face sides of
the piston 21 are equipped at the side with naps 47 which lift the
outer rims of the flexibly designed valve disk 46 located centrally
in the outlet chambers 43, 44. .sup.3) Translator's note: The
German text states "zum Kolben" here whereas "vom Kolben" would be
correct. Therefore the latter has been assumed for the
translation.
[0028] In particular from drawing FIG. 7 it is apparent that the
outer casing 45 has a cross-section of approximately oval design.
It encompasses the rotationally symmetrically designed linear drive
in casing 31. In opposing areas having a thicker casing wall there
is located on one side an inlet bore 51 and on the other side an
outlet bore 52. These extend in parallel to the piston 21. The
inlet bore 51 is linked via lateral bores 53 to the gas inlet
chambers 34, 35. The outlet chambers 43, 44 are linked via lateral
bores 54 to the outlet bore 52.
[0029] In the embodiment depicted, both bores 51, 52 open out at
one of the face sides of the module 2 (c.f. in particular drawing
FIG. 6) and form the inlet 55 and outlet 56 respectively of the
module 2. Assigned to this face side is the rail 3. Located in the
rail 3 is the inlet channel 57 which is linked to the inlet 55 of
the modules 2 in a sealed manner. At the level of the outlets 56 of
the modules 2 there is located the outlet channel 58 of the rail 3
which are also--through means not explicitly depicted, mechanical
means or adhesive--joined in a sealed manner. Inlet channel 57 and
outlet channel 58 are outlined in drawing FIG. 7 by dashed
lines.
[0030] Further channels 59 in the rail 3 are depicted in drawing
FIG. 6. These serve the purpose of accepting electric cables
employed for supplying power to the linear drives, for example.
Also linking of the modules 2 as well as--if present--the
high-vacuum pump 12 to a joint power supply, display and control
unit (drawing FIG. 3) may be effected through the further
channels.
[0031] Drawing FIGS. 8 to 10 depict further possible variants with
respect to connecting the modules 2.
[0032] In the solution in accordance with drawing 8a, b all modules
2 are connected in parallel. This then expediently also applies to
the stages present in a module 2 if it is of a two-stage design
(drawing FIGS. 5, 6). At the face sides, the inlets 55 of the
modules 2 open out into a joint inlet channel 57 in rail 3 (drawing
FIG. 8b). The outlets 56 open into the joint outlet channel 58.
[0033] In the embodiment in accordance with drawing FIGS. 9a, 9b
all modules 2 are connected in series, for example also the stages
contained in module 2, as detailed in DE 199 17 560.8. The inlet
channel 57 in rail 3 (drawing FIG. 9b) extends only up to the inlet
55 of the first module 2. Intermediate channels 61 connect each the
outlet 56 of a module 2 to the inlet 55 of the next module 2. The
outlet 56 of the last module 2 is linked to an outlet channel 58',
which may, for example, be provided separately (c.f. also drawing
FIG. 5, dashed addition) in rail 3.
[0034] Drawing FIGS. 10a, b depict a solution in which the first
two modules 2 are connected in parallel and the two further modules
2 are connected in series (drawing FIG. 10a). The corresponding
arrangement of the channels 57, 58, 58', 61 in rail 3 is depicted
in drawing FIG. 10b.
[0035] The so far described modules 2 of the pump 1 according to
the present invention have compression chambers 32, 33 at both face
sides of the piston 21. Within the scope of the present invention
also modules equipped with only one or more than two compression
chambers respectively may be employed. The latter are basically
known from EP 607 687 A2. The therein detailed piston pumps are,
however, equipped with a crankshaft drive.
* * * * *