GB1568940A

GB1568940A – Peristaltic pump
– Google Patents

GB1568940A – Peristaltic pump
– Google Patents
Peristaltic pump

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Publication number
GB1568940A

GB1568940A
GB5413/78A
GB541378A
GB1568940A
GB 1568940 A
GB1568940 A
GB 1568940A
GB 5413/78 A
GB5413/78 A
GB 5413/78A
GB 541378 A
GB541378 A
GB 541378A
GB 1568940 A
GB1568940 A
GB 1568940A
Authority
GB
United Kingdom
Prior art keywords
housing
tube
roller
peristaltic pump
rollers
Prior art date
1977-02-10
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)

Expired

Application number
GB5413/78A
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)

Individual

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Individual
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
1977-02-10
Filing date
1978-02-10
Publication date
1980-06-11

1978-02-10
Application filed by Individual
filed
Critical
Individual

1980-06-11
Publication of GB1568940A
publication
Critical
patent/GB1568940A/en

Status
Expired
legal-status
Critical
Current

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Classifications

F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING

F04—POSITIVE – DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS

F04B—POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS

F04B43/00—Machines, pumps, or pumping installations having flexible working members

F04B43/12—Machines, pumps, or pumping installations having flexible working members having peristaltic action

F04B43/1253—Machines, pumps, or pumping installations having flexible working members having peristaltic action by using two or more rollers as squeezing elements, the rollers moving on an arc of a circle during squeezing

Description

( 21) Application No 5413/78
( 31) Convention Application No.
9 ( 31 ( 00 ( 33) Australia (AU) ( 44) Complete Specificatik ( 51) INT CL 3 F 04 B 43/ ( 52) Index at acceptance Fl U 46 A ( 22) Filed 10 Feb 1978 /77 ( 32) Filed 10 Feb 1977 in in published 11 June 1980 ( 54) PERISTALTIC PUMP ( 71) I, ALLAN RICHARD JONES, an Australian citizen of 51 Badajoz Road, Ryde, New South Wales, 2112, Australia, do hereby declare the invention, for which I pray that a patent may be granted to me, and the method by which it is to be performed, to be particularly described in and by the following statement: –
This invention relates to peristaltic pumps of the kind utilizing a single and complete coil, or helix, of flexible tubing compressively engaged by roller means acting within said helix for the advancement of a fluid content of the tubing, and more particularly to such a pump incorporating provision for radial extension and withdrawal of said roller means.
Existing pumps of this nature invariably achieve a pulsating flow of fluid content which in many applications, such as in the case of surgical and metering pumps, is undesirable In some instances contemporary peristaltic pumps are unreliable due to frequent frictional wear and resulting damage to the flexible tubing, and in most instances major disassembly is required for replacement of the tubing.
Additionally, the full useful potential of peristaltic pumps has not been utilized due to the lack of any pump of this type behing provided in a modular form capable of assembly with similar modules in a bank of independent operable pumps deriving a common power drive.
It is the principal object of the invention to provide a pump of the peristaltic type which is substantially free from at least some of the above defects.
In accordance with the invention there is provided a peristaltic pump comprising a housing surrounding a cylindrically walled chamber, a flexible and resilient tube for containment of a fluid material to be pumped being wound in a single loop of a helix within and around the cylindical wall of the housing, at least one rotatable roller within the chamber and outwardly radially displaceable to bear upon the tube to compress same against said cylindrical wall of the housing, setting bar means ad 50 vanceable along its axis through the housing to effect outward displacement of said roller, drive apparatus for angularly displacing said roller around the inner circumference of the loop of the tube to 55 cause it to traverse said loop, and means for rotating said roller about its axis to cause it to roll over said tube during its passage around said loop.
Also according to the present invention, 60 a peristaltic pump assembly comprises a housing surrounding a cylindrical chamber and being formed from a plurality of sections clamped end-on-end axially of the chamber; each section of the housing in 65 cluding a plurality of of annular parts comprising a main body and a part having an internal ring gear, and a flexible and resilient tube for containment of a fluid material to be pumped being wound in a 70 single loop of a helix within and around the inner wall of said main body; a core assembly coaxially positioned for rotation wtihin said chamber, said core assembly radially slidably supporting sets of rotat 75 able rollers disposed end-on-end axially of the chamber in operative association with respective ones of the tube loops to progressively compress each tube loop against said inner wall of said main body with 80 radial extension of said rollers and rotation of said core assembly about the chamber axis, a setting bar advanceable axially through said core assembly to engage and radially extending each set of said rollers in 85 turn whereby the degree of its advancement determines how many sets of said rollers will be extended; and drive means for rotating said core assembly, said sets of rollers being provided with pinions en 90 PATENT SPECIFICATION ( 11) 1 568 940 W) “.4 1 568 940 gaging with respective ones of said ring gears to cause rolling of the rollers over their tube loops with rotation of said core assembly.
The invention will now be described by way of example only with reference to several preferred embodiments shown in the accompanying drawings, in which:
Figure 1 is an exploded perspective of a first embodiment; Figures 2 a and 2 b when assembled end-on-end as indicated depict an exploded perspective of a second embodiment composed of a bank of juxtaposed pumps; Figure 3 shows in inverted plan the internal shaping of a cover plate for use in any one of the pumps shown in the bank of Figures 2 a and 2 b; Figure 4 is an end elevation of the core member of the bank of pumps of Figures 2 a and 2 b; and Figure 5 shows partly diagrammatically a third embodiment of a peristaltic pump.
Peristaltic pumps in one known form comprise a cylindirecal housing for a flexible resilient tube entering at one point on the circumference thereof and extending around the interior of the housing for approximately 2600 to exit at another point on the housing substantially confronting the entry point A roller is forced into compressive engagement with the tube and rotated by gear means on the axis of the housing to provide the means for drawing a fluid substance in through one end of the tube and forcing it around the tube to the outlet by progressively compressively collapsing the tube By the provision of a restriction at the outlet side of the pump and the rotation of the roller at a relatively high speed the fluid substance can be pumped out of the tube at a higher pressure than that derived from its source In another known form the tube has been positioned within the housing to circumscribe a complete helix with its inlet and outlet end portions extending substantially tangentially with respect to the cylindrical housing Both forms of pumps have not been satisfactory for the many applications requiring substantially uniform flow of fluid, i e, as opposed to a pulsating flow.
It can be readily appreciated that such decompresssurization of the fluid substance can in fact induce reverse flow thus requiring a non-return or check valve to be installed to avoid such unwarranted and dangerous effect if the pump is being utilized for surgical purposes, such as blood transfusion.
The embodiment of Figure 1 consists of a body 6 in the form of a tubular cylindrical housing 7 which has an upper cap or cover 8 fixed by any suitable means, such as screws (not shown) to the upper portion of the housing The join line 9 between the two parts of the housing 7 is in a plane passing approximately diametrally through inlet and outlet passages 10 and 11 in the upper half of the housing A length of 70 silicon elastomer flexible resilient tubing 12 is entered through the inlet passage 10 and coiled in a single complete helix in contact with the inner wall of the housing 7 and passes out through the outlet passage 75 11 It will be noted that the two external end portions of the tubing are in approximately the same plane which is a substantial tangent to the inner cylindrical wall of the housing 7 80 A core member 13, functioning as a roller support assembly, is axially entered into the housing 7 and consists of a cylindrical plug 14 bored along its axis to accept a shaft 15 A forward end 16 of the shaft 85 may be provided with suitable facility (not shown) for deriving power drive for the core member 13 The shaft 15 is preferably splined or keyed to the plug 14 so that the two rotate in unison Two dia 90 metrally opposed radial slots 17 and 18 are cut in the plug 14 for slidable housing of individual roller assemblies 19 and 20 Each assembly 19 or 20 comprises a substantially rectangular plate having bearing bars 21 95 at their inner ends and a pair of forked arms 22 at their outer ends Individual rollers 23 and 24 are rotatably supported on spindles 25 supported between respective pairs of arms 22 Each spindle 25 is 100 extended to one sided fixed to a pinion 26.
When the core member 13 is entered into the housing 7 the pinions 26 confront a ring gear 27 secured to one end of the housing 7 The ring gear 27 is preferably a 105 separable annulus 28 held to the end of the housing 7 by an end plate 29 A further end plate (not shown) may be fixed over the other end of the housing 7 to retain the core member 13 therein 110 ‘ The rollers 23 and 24 together with their entire assemblies 19 and 20 are extensible and retractible within their enclosing plug 14 As shown in Figure 1 such radial movement is effected by sliding keys 30 and 115 31 which are secured by linkages 32 to control means for extending and withdrawing them along keyways provided in the shaft 15 It can be seen that with extension into the plug 14 of either key 30 or 31 its 120 G forward ramp-shaped surface 33 will cause the respective roller assembly at 19 or 20 to be readily extended As the rollers are positioned adjacent and within the confines of the helix of the tubing 12, either 125 roller 19 or 20 when extended will compress the tube 12 against the inner surface of the housing 7 Drive on the shaft 15 will then cause the extended roller to progressively traverse the helix thereby forc 130 1 568 940 ing any fluid content along the tube towards its outlet while drawing fluid from its source The two rollers shown in Figure 1, being driven by reciprocating keys 30 and 31 always driven 1800 out of phase provide an “exchanging roller” facility in that as one roller 23 extends the other roller 24 retracts Providing that the exchanging feature is kept precisely 1800 out of phase it will be possible to obtain a fluid content flow from the pump which is sub9 tantially uniform, i e non-pulsating Preferably, the retraction of each roller in turn during its traverse of the helix commences to occur immediately preceding the crossover point 34 in the helix of the two end portions of the tubing 12 and is complete at the central part of this crossover and then commences to extend progressively towards the far side of the crossover point 34 The linkages 32 connected to the keys 30 and 31 may be hydraulically or mechanically controlled, according to the user’s requirements.
23 As an alternative to the embodiment of Figure 1 a single roller assembly 19 or 20 may be provided in the plug 14 and reasonably non-pulsating fluid flow achieved if the cap 8 on the housing 7 should be provided with internal grooving for accommodation of the end portions of the tubing 12 such as that shown in Figure 3 The juxtaposed grooves 35 and 36 are staggered as shown and become progressively shallower towards their inner ends 37 It is desirable that the ends 37 of the two grooves occur in the same transverse plane 38 of the cap 8 to avoid any overlap of these grooves Thus, the single roller assembly 17 utilized in this form will not require to be radially retracted during traversing around the helix Nevertheless, retractability thereof is still provided for the following purpose.
Apart from the facility of substantially uniform fluid content flow retractability of the roller assemblies 17 and 18, regardless of whether one, two or more such assemblies are provided in any pump, enables all roller assemblies 17 to be retracted simultaneously for simplicity of replacement of a tubing 12 in the event of either damage thereto or replacement of a different capacity tubing The replacement may be readily made by removal of the cap 8 and retraction of the rollers In order to retain retraction of the rollers 23 and 24 the linkages 32 may be selectively withdrawn in unison or alternatively the shaft 15, functioning as a setting bar, may itself be withdrawn from the plug 14 For added convenience during replacement of tubing 12 return springs (not shown) may be associated with the roller assemblies 17 and 18 so that they are normally retracted and extended by the keys 30 and 31 against the action of these springs It will be seen that the power means for linkages 32 to the keys 30 and 31 must be communicated through rotatable couplings as operation 70 of these keys will be required during rotation of the shaft 15, but this will not involve any difficulty.
Provision is also made within the pump of Figure 1 to avoid slippage of the rollers 75 23 and 24 on the tubing 12 during traversing around the helix in order to avoid damage through friction therebetween.
Furthermore, distortion of the tubing may result from this friction especially when 80 viscous liquids are being pumped To avoid this the rollers 23 and 24 are controllably rotated by engagement of pinions 26 within the teeth of ring gear 27 It is desirable that the pitch circle diameter of each 85 pinion 26 be equal to the diameter of its respective roller 23 while the pitch circle diameter of the ring gear 27 be equal to the internal diameter of the housing 7 less the dimension equal to twice the wall 90 thickness of the tubing 12 This will then ensure that the tubing 12 is fully closed off during operation of the pump but the closure pressure applied by a roller 23 is insufficient to cause damage to the pump 95 or to the tubing It will be important that the pitch of the teeth in both the pinion 26 and the ring gear 27 be chosen so that the surface speed of rotation of the roller corresponds with the speed of traverse by 100 the roller of the tube helix.
Reference is now made to the exploded view of Figures 2 and 2 b, and to Figure 4.
In these drawings the same numerals as used above are applied to like parts The 105 drawing is of an assembly of a plurality of independent modular pumps similar in many respects to that depicted in Figure 1, except that three roller assemblies 17 A equally circumferentially spaced are em 110 ployed, and a single common setting bar A passes through the core member 13.
Therefore, the ” exchanging roller ” feature is not incorporated in this embodiment, although by suitable modification 115 the exchanging roller core member 13 of Figure 1 may be applied Where a common setting bar 1 SA is used it will be necessary to utilize for the three separate caps 8 shown in Figure 2 the form of tapering 120 slots depicted in Figure 3, if the derived flow of fluid content in the pump tubing 12 is to be non-pulsating.
Three independent modular pumps are illustrated each comprising a tubular cylin 125 drical housing 7 with removable cap 8 secured thereto by screws 8 A The assembled bank of pumps comprises for each pump a housing 7, an annulus 28 containing a ring gear 27 held between two spacer plates 130 1 568 940 39 adjacent one side of the housing 7 All of the spacers are formed as similar annuluses to the annulus 28 and all plates together with the housing 7 are provided with a pair of mounting holes 40 at diametrally opposite parts of each annulus A separate threaded rod 41 passes through corresponding holes 40 in register on opposite sides of the assembly and are screwed to a far end plate or spacer 39 provided with a thread in its holes 40 to clamp the assembly together with a forward end plate 42 Preferably, each annulus 28 and spacer 39 as well as housing 7 is provided with a laterally projecting annular rib 43 on one side face and a matching annular groove 44 on the other side so that each adjacent section locks in tongue-andgroove fashion with its neighbouring section.
The setting bar 15 A extends through an axial sleeve 45 keyed, or splined, to the plug 14 of the core member 13 Suitable roller races 46 are secured by lock nuts 47 upon opposite ends of the sleeve 45 for support in housings which may be provided by the opposite end plates 39 and 42, or on separate housings (not shown).
The roller assemblies 17 A in each of the three separate pumps in the bank terminate at their inner end 48 with an inclined surface 49 facing towards the ends of the core member 13 at which the setting bar 15 A is inserted The setting bar 15 A has a forward lead-on taper 50 so that with its insertion progressively into the sleeve 45 it engages in turn with the inclined faces 49 of the roller assembly 17 A of each pump, successively, to radially extend the sets of rollers per pump into compressive engagement with the tubing 12 within the housing 7 of each pump Therefore by selective advancement, or retraction, of the setting bar 15 A an in creasing or decreasing number of the separate pumps in the bank may be brought into operation without interruption to those pumps already in operation Such a facility has special advantage when repair of a single pump may be required, or only selected pumps require to be in operation.
These facilities as well as others inherent in this embodiment renders it ideal for industrial application.
Figure 5 shows an embodiment of peristaltic pump according to the invention providing for selective electric control of the keys 30 and 31 shown in Figure 1, or similar types of ” exchanging roller” setting bar means It also is capable of providing for selected degrees of pulsation in the pump flow of fluid content Like parts have been labelled with similar numerals to those utilized in the foregoing description.
The keys 30 and 31 have similar ramplike shaped leading edges 33 which bear upon ball bearings or rollers captured between the keys and an inclined underface 51 of the roller assembly 17 B Each key 70 or 31 is actuated through linkage 32 in the form of a plunger operated on by electrical solenoids 52 The coils of these solenoids 52 are electrically wired to slip rings or brushes 53 engaging with a pulse 75 control unit 54 Thus, by positional arrangement of electrical conductors 55 on the pulse control unit 54 energization of the solenoids 52 will be obtained at a predetermined point in the angular rotation of 80 the roller assemblies 17 B in order to effect accurate “exchanging roller” functioning in the pump It can be seen from the drawing that the two sliding keys 30 and 31 are operated 1800 out of phase The 85 pump of this embodiment is ideally suited for chemical applications where metering and controlled pulsing are requirements, for example for analyzing equipment and artificial heart operation 90 In the two embodiments shown in Figures 1 and 5 it will be preferred that the depth of the teeth both in the pinion 26 and the ring gear 27 is sufficient to permit some radial displacement of the 95 roller assemblies 17 and 18 or 17 A without losing mesh between the pinion 26 and the ring gear 27 Furthermore, in all the abovedescribed embodiments it will be possible to create an oil bath within the housing 7 100 as it is totally enclosed Alternatively, the interior of the housing 7 may be placed under vacuum In either instance improved efficiency of the pump can be obtained.
Several embodiments have been de 105 scribed in the foregoing passages but it should be understood that other forms are also possible within the scope of the invention as defined in the appended claims.

Claims (1)

WHAT I CLAIM IS: 110
1 A peristaltic pump comprising a housing surrounding a cylindrically walled chamber, a flexible and resilient tube for containment of a fluid material to be pumped being wound in a single loop of a 115 helix within and around said cylindrical wall of the housing, at least one rotatable roller within the chamber and outwardly radially displaceable to bear upon the tube to compress same against said cylindrical 120 wall of the housing, setting bar means advanceable along its axis through the housing to effect outward displacement of said roller, driving apparatus for angularly displacing said roller around the inner cir 125 cumference of the loop of the tube to cause it to traverse said loop, and means for rotating said roller about its axis to cause it to roll over said tube during its passage around said loop 130 1 568 940 2 A peristaltic pump according to claim 1, wherein said rotating means for said roller is a pinion rotatable with said roller and meshing when said roller is outwardly displaced with a stationary ring gear within said chamber and juxtaposed to said loop.
3 A peristaltic pump according to claim 2, wherein the pitch diameter of the pinion and of the ring gear and the pitch ratio therebetween is such that the linear surface speed of the roller substantially corresponds to the speed of traverse of said roller around said loop to avoid friction between said roller and said tube.
4 A peristaltic pump according to any one of claims 1 to 3, wherein said housing is tubular and includes end plates closing the housing at its ends, said tube has inlet and outlet end portions protruding from inlet and outlet ports in the wall of said housing, and said cylindrical wall has a removable sector joined to the remainder of said wall at a junction line which passes through both the inlet and outlet ports, whereby with removal of said sector said tube may be readily withdrawn from said housing.
A peristaltic pump according to claim 4, wherein with withdrawal of said setting bar means from said housing radial retraction of said roller occurs to provide clearance between said roller and said housing wall to facilitate said ready withdrawal of said tube.
6 A peristaltic pump according to any one of claims 1 to 5, wherein there are at least two rollers equally spaced circumferentially from each other with respect to said loop, and a core assembly is coaxially positioned within said housing and radially slidably supports said rollers.
7 A peristaltic pump according to claim 6, wherein said core assembly comprises a shaft non-rotatably secured thereto and having keyways, and said setting bar means comprises an individual bar slidable in a respective keyway and associated with each of said rollers, said setting bars being slidable in staggered relationship.
$ 0 8 A peristaltic pump according to claim 7, wherein driving apparatus for said setting bars comprises individual plungers and electrical solneoids therefor, said solenoids being energized under control of a stationary adjustable device connected to said solenoids by slip-rings to provide desired selective operation of said setting bars for control of the degree of pulsation in the pumping of said fluid material.
9 A peristaltic pump assembly comprising a housing surrounding a cylindrical chamber and being formed from a plurality of sections clamped end-on-end axially of the chamber; each section of the housing including a plurality of annular parts comprising a main body and a part having an internal ring gear, and a flexible and resilient tube for containment of a fluid material to be pumped being wound in a single loop of a helix within and around 70 the inner wall of said main body; a core assembly coaxially positioned for rotation within said chamber, said core assembly radially slidably supporting sets of rotatable rollers disposed end-on-end axially of the 75 chamber in operative association with respective ones of the tube loops to progressively compress each tube loop against said inner wall of said main body with radial extension of said rollers and rotation of 80 said core assembly about the chamber axis, a setting bar advanceable axially through said core assembly to engage and radially extend each set of said rollers in turn whereby the degree of its advancement 85 determines how many sets of said rollers will be extended; and drive means for rotating said core assembly, said sets of rollers being provided with pinions engaging with respective ones of said ring gears 90 to cause rolling of the rollers over their tube loops with rotation of said core assembly.
A peristaltic pump assembly according to claim 9, wherein each said tube has 95 inlet and outlet end portions protruding from inlet and outlet ports in said main body of its respective housing section, and said annular main body of each of said sections has a removable sector joined to 100 the remainder of said main body at a junction line passing through both the inlet and outlet ports, whereby with removal of said sector said tube can be readily withdrawn from the pump assembly 105 11 A peristaltic pump assembly according to claim 10, wherein the inner face of said removable sector has semi-hemispherical grooves staggered in alignment and made progressively shallower towards 110 a mid-point of said surface, the inner end of said grooves both terminating on the same transverse line through said sector, so that with passage of said rollers over said tube beneath said sector substantial 115 reduction in pulsing of the fluid material in said tube is achieved.
12 A peristaltic pump substantially as herein descsribed with reference to Figure 1, or Figure 1 as modified by Figure 3, 120 or Figure 5 of the accompanying drawings.
13 A peristaltic pump assembly substantially as herein described with reference to Figures 2 a, 2 b, 3 and 4 of the accompanydrawings 125 W P THOMPSON & CO, Coopers Building, Church Street, Liverpool, L 1 3 AB.
Chartered Patent Agents.
hkinted for Her Majesty’s Stationery Office by The Tweeddale Press Ltd, Berwick-upon-Tweed, 1980.
Published at the Patent Office, 25 Southampton Buildings, London, WC 2 A IAY, from which copies may be obtained

GB5413/78A
1977-02-10
1978-02-10
Peristaltic pump

Expired

GB1568940A
(en)

Applications Claiming Priority (1)

Application Number
Priority Date
Filing Date
Title

AU903177

1977-02-10

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Publication Number
Publication Date

GB1568940A
true

GB1568940A
(en)

1980-06-11

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ID=3699747
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Application Number
Title
Priority Date
Filing Date

GB5413/78A
Expired

GB1568940A
(en)

1977-02-10
1978-02-10
Peristaltic pump

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US4205948A
(en)

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GB1568940A
(en)

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1969-11-17
Biotec Ab

DE2153052A1
(en)

*

1971-10-25
1973-05-03
Allen Longford & Associates Lt

PERISTALTIC PUMP

US3816035A
(en)

*

1972-10-24
1974-06-11
E Malbec
Peristaltic pump

1978

1978-02-01
US
US05/874,090
patent/US4205948A/en
not_active
Expired – Lifetime

1978-02-10
GB
GB5413/78A
patent/GB1568940A/en
not_active
Expired

Cited By (8)

* Cited by examiner, † Cited by third party

Publication number
Priority date
Publication date
Assignee
Title

EP0042399A1
(en)

*

1979-12-17
1981-12-30
Baxter Travenol Lab
Miniature infusion pump.

EP0042399A4
(en)

*

1979-12-17
1982-03-22
Baxter Travenol Lab
Miniature infusion pump.

EP0078092A1
(en)

*

1981-10-20
1983-05-04
Rudolph Berelson
Peristaltic pump

US4441867A
(en)

*

1981-10-20
1984-04-10
Rudolph Berelson
Peristaltic pump

EP0187914A2
(en)

*

1984-11-16
1986-07-23
Armour Pharmaceutical Company
Hose pump with squeezing rollers

EP0187914A3
(en)

*

1984-11-16
1987-03-25
Armour Pharmaceutical Company
Hose pump with squeezing rollers

FR2669685A1
(en)

*

1990-11-28
1992-05-29
Meditec
Device for freeing the crushing rollers of a peristaltic pump

EP0518290A1
(en)

*

1991-06-10
1992-12-16
Ebner & Co. KG Anlagen und Apparate
Tube pump

Also Published As

Publication number
Publication date

US4205948A
(en)

1980-06-03

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Legal Events

Date
Code
Title
Description

1980-08-28
PS
Patent sealed

1983-09-28
PCNP
Patent ceased through non-payment of renewal fee

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