EP0394383A1

EP0394383A1 - Hose pump.

Info

Publication number: EP0394383A1
Application number: EP89908964A
Authority: EP
Inventors: Manfred Streicher
Original assignee: KWW Gesellschaft fuer Verfahrenstechnik mbH
Current assignee: Crane Process Flow Technologies GmbH
Priority date: 1988-08-12
Filing date: 1989-08-09
Publication date: 1990-10-31
Anticipated expiration: 2009-08-09
Also published as: ATE83047T1; NO901500L; US5049048A; DK89590A; FI901853A0; WO1990001638A1; EP0394383B1; NO171381B; KR900702236A; DE58902903D1; NO901500D0; DK89590D0; NO171381C; DE3827405A1; DK171563B1; JPH03504528A; FI100676B; KR0126592B1

Abstract

PCT No. PCT/DE89/00522 Sec. 371 Date Apr. 23, 1990 Sec. 102(e) Date Apr. 23, 1990 PCT Filed Aug. 9, 1989 PCT Pub. No. WO90/01638 PCT Pub. Date Feb. 22, 1990.A hose pump has a housing (10) with a pressure connection (14) and an intake connection (12). A hose (22) is connected to the pressure connection and the intake connection and rests against the inner wall (24) of the housing (10). Squeezing members (26) can be moved along the hose (22) such that the hose is squeezed by each squeezing member from the direction of the intake connection (12) toward the direction of the pressure connection (14). The hose pump is characterized by at least one conduit (32) which is elastically deformable and whose one end (44) ends in the interior (46) of the housing (10) and whose other end (50) ends outside of the housing (10) and which is provided in the interior (46) of the housing such that by moving at least two additional squeezing members (26) which can be moved along the conduit, the conduit is squeezable from the direction of its one end (44) into the direction of its other end (50).

Description

DESCRIPTION

Peristaltic pump

TECHNICAL AREA

The invention relates to a peristaltic pump with a housing with a pressure and suction nozzle, with a first hose, which is connected to the pressure and suction nozzle and abuts the inner wall of the housing, and with at least two squeeze bodies, so on the The hose can be moved along such that the hose can be squeezed together by each squeeze body from the direction of the suction nozzle in the direction of the pressure nozzle.

STATE OF THE ART

Known peristaltic pumps of this type essentially have differences in how their hose is re-erected in the suction area behind a squeezing body that squeezes along.

Peristaltic pumps with an elastic hose are known which have a relatively high self-restoring force.

The desired restoring force then depends on the desired suction head of the pump.

In another known type of hose pump, the restoring force for the hose is generated by suppressing the inside of the pump. Various possibilities for generating or maintaining the required vacuum inside the hose pump are known from DE-PS 37 03 124. According to a first embodiment, the vacuum on the suction side required for resetting the squeezed hose is either caused by a separating device which consists of a sealing part and a separating part, the sealing part being a represents elastic seal, which is connected to the housing peripheral wall in the short area between the suction port and the pressure port and in this area rests sealingly on the separating part, front wall, rear wall and peripheral wall, while the separating part is formed as a seal which is guided around the rotor with the squeezing bodies and leads to the front wall and seals against the rear wall. With such a separating device, the vacuum on the suction side is created in each case in such a size that corresponds to the suction height just required. The same is achieved according to another embodiment in that all free spaces in the interior of the pump are filled with a liquid. If the squeeze body then moves a little further on the hose and squeezes a new section of the hose together, the previously squeezed hose section cannot remain squeezed together, since in this case a cavity would form in the filled liquid, which is not possible . The action of the liquid creates a negative pressure, which straightens up every squeezed piece of hose as soon as the squeeze body continues to run. The hose is thus erected by negative pressure. This enables very high speeds and thus delivery rates to be achieved. In this embodiment, the negative pressure that arises as the squeeze body continues to run precisely corresponds to the negative pressure in the hose on the suction side. With this pump, too, the suction head is set automatically.

Compared to the peristaltic pumps with an elastic hose, the peristaltic pumps, in which the hose is reset by negative pressure, are more complex in their construction, which is understandable due to the required vacuum-tight construction. Obtaining the negative pressure when installing the separating device depends on the vacuum-tight connection of the components moving relative to one another in the housing. When the vacuum pump is completely filled with liquid, there is a risk that if the vacuum is too great, the ge present inside the housing of the hose pump rings amount of the required lubricant foams, so that the restoring forces re-erecting the hose can not be built up or only in a reduced size.

PRESENTATION OF THE INVENTION

Based on this known prior art, the invention has for its object to provide a peristaltic pump of the type mentioned, which is simple in construction and in which the restoring forces re-erecting the hose can be activated by vacuum with certainty in the desired size. This invention is given by the features of claim 1 in the case of the hose connector mentioned at the beginning and known from the prior art. The hose pump according to the invention is accordingly characterized by at least one second hose which is elastically deformable, one end of which ends at the inside of the hose and the other end outside the housing, and which is present in the interior of the housing in such a way that the movement of at least one two second pinch bodies movable along it can be squeezed together from the direction of its one end towards its other end. The invention is therefore based on the knowledge that when the peristaltic pump is operated, air can be pressed out of the interior of the housing by squeezing this second tube together - in the same way as is done with the delivery hose, which creates a vacuum in the interior of the housing maintained or generated. This second hose can be very small in diameter. The hose available for the actual conveying does not need to be elastically deformable, but can be erected again by negative pressure, so that the advantages of a vacuum pump can be used.

The second hose that is used to maintain or create of the vacuum inside the peristaltic pump can be arranged in the interior of the peristaltic pump in such a way that the first squeeze bodies, which serve to squeeze the delivery hose together, can also be used as the second squeeze bodies, which are present for creating or maintaining the vacuum. This brings a considerable simplification of the construction principle of such

Peristaltic pump with itself. The hose pump according to the invention can only function fully when the required negative atmospheric pressure has built up inside. At the start-up time of such

To keep the peristaltic pump as low as possible, the second hose is connected to the atmosphere surrounding the housing via a check valve, which opens in the direction of the atmosphere. When the peristaltic pump is not in operation, no air can penetrate into the interior of the housing, so that the respective negative pressure is not lost, even if the squeeze body should not lie close to the second peristaltic tube when the peristaltic pump is at a standstill, which is for the longest possible service life of the tube may be desirable. This provides one

Peristaltic pump almost at full capacity immediately. A further simplification results when the second

Hose is present within the wall of the first hose. When laying the first hose - for example during initial assembly or when replacing the same - the second hose is also laid at the same time. This ensures that the second hose is always in the correct position with respect to the first hose and thus to the existing squeeze bodies.

A simple way of producing this second hose can be achieved if the second hose is formed by a cavity in the wall of the first hose. An actual hose wall for the second

This eliminates the need for a hose because the second hose is then can only represent a channel-like opening and thus a recess in the wall of the first hose.

A very significant advantage is obtained if the second hose or the channel-like cavity in the first hose is present in the hose jacket closer to the inside than to the outside of the first hose. Of course, the second hose must be arranged circumferentially in the first hose so that when the first hose is squeezed, its cross section is also fully squeezed together. The second hose will therefore preferably be present in the bending area of the first hose. Since it is also positioned more on the inside than on the outside of the first hose, it is present in the jacket region of the first hose which is maximally stressed when squeezed together. If the first hose is damaged, which cannot be avoided after a more or less long operating time, the jacket area surrounding this second hose will first tear inwards, so that the inside of this second hose is connected to the interior of the first hose. This has the great advantage that when the peristaltic pump is operated, the respective medium conveyed in the first hose emerges from the opening of the "second hose". When the squeeze body is operated, the medium conveyed in the first hose is now pressed into the second hose and pushed out of the latter. This can be determined by suitable monitoring devices and the tube pump can then be brought to a standstill immediately. The second hose thus acts as one

Hose monitor for the main hose, since it lies in the area at maximum risk and can therefore immediately indicate that the main hose is partially cracked and should therefore be replaced, since it is still at full capacity at the moment but it can be expected that the hose will be completely torn up in a more or less short time and will be destroyed. The hose can be used when conveying food the pump must be switched off before the main hose breaks, so that the pumped food cannot mix with the lubricating fluid inside the hose pump. Peristaltic pumps can now also be safely used to convey food.

BRIEF DESCRIPTION OF THE DRAWING The invention is described and explained in more detail below with reference to the exemplary embodiment shown in the drawing. Show it:

1 shows a cross section through a peristaltic pump according to the invention,

Fig. 2 is a perspective view of a portion of the ski used in the hose pump of Fig. 1 and Fig. 3 shows the hose of Fig. 2 in a squeezed

Status.

WAYS OF CARRYING OUT THE INVENTION

A housing 10 of a hose pump has two nozzles, of which - in the drawing - the left nozzle as the suction nozzle 12 and - in the drawing - the right nozzle as the pressure nozzle 14. The direction of rotation 16 of a rotor 18 present in the housing 10 corresponds to the counterclockwise direction.

The two connecting pieces 12, 14 protrude through the upper region 20 of the housing 10 into the interior 46 thereof and are connected to one another by a hose 22.

This hose 22 lies in the lower, circular-cylindrical pinched area 24 of the housing 10 on the inside of the Ge house 10 directly or indirectly via a cushion layer - not shown in the drawing. The runner 18 and its crushing bodies 26 which are present on it and are in contact with the tube in a squeezing manner form a cylindrical outer surface 30, which sealingly abut the end walls of the housing 10 against the end faces, which lie parallel to the sheet plane. In this respect, the above components correspond to the components known from known peristaltic pumps.

The wall 31 of the hose 22 present in the interior of the housing 10 has a channel-like opening 32 which is present parallel to the longitudinal axis 34 thereof. The channel-like opening 32 is closer to the inside 36 than to

Outside 38 of the wall 31 aligned. In terms of its circumference, it is also arranged in such a way that it is located in the bending region 40 of the hose 22, which is on the left in FIG. 3, in which the cross section of the hose is deflected by 180 degrees due to the force 42 of the squeeze body 26 and is thus subjected to a maximum load.

This channel-like opening 32 of the hose 22 has an opening 44 in the area of the suction nozzle 12, which opens into the interior 46 of the housing 10, in the upper area thereof. In the area of the pressure port 14, the channel-like opening 32 has an airtight connection with an outlet channel 50, which exits to the atmosphere with its other end outside the housing 10, whereby it pierces the sealing ring 52. The pressure port 14 has at its upper end

External thread 54, on which a union nut 56 is screwed against the sealing ring 52 and against the upper region 20 of the housing 10. Similarly, the suction nozzle 12 is also attached to the housing 10 and thus also to the hose 22. Only the suction nozzle 12 does not have the outlet opening 50, since there the channel-like opening 32 opens into the interior 46 of the housing 10 through the opening 44. The peristaltic pump according to FIGS. 1 to 3 works as follows.

When the rotor 26 rotates in the direction of rotation 16, air is sucked in from the interior 46 through the opening 44, and from the outlet duct 50 into the one surrounding the housing 10

Atmosphere. Just as the squeeze body 26 fully compress the tube 22 at one point during its rotation in the direction of rotation 16 and thus completely close the cross section at this point (FIG. 3), the channel-like opening 32 is also at these points of the tube 22 by the Squeeze body 26 fully squeezed together and thus closed. Should the hose 22 tear over time, such a crack formation will first appear on the inside in the area of the bending areas 40, 41. Since the channel-like opening 32 is also located in one of these areas, such a crack would open the channel 32 inwards, so that the channel-like opening 32 would no longer exist as such. In that state it would be

Hose 22 but still fully functional; only the medium to be conveyed through the interior of the hose 22 would emerge from the outlet opening 50 instead of air. When using the peristaltic pump in the food sector, I would leak part of this soup, for example, when conveying soup from the outlet channel 50. The peristaltic pump could thus be switched off at a time when the

Hose 22 would still exist intact and in which no mixing between the lubricating liquid present in the interior of the housing 10 and the soup or the like to be delivered could occur. Such a peristaltic pump could thus be used without hesitation in the food sector in terms of food law.

Claims

EXPECTATIONS

01) peristaltic pump

w ^ith

- A housing (10) with a pressure (14) and suction nozzle

(12),

- A first hose (22) with the pressure and

Suction port is connected and abuts the inner wall (24) of the housing (10),

- At least two squeeze bodies (26) so on the

Hose (22) can be moved along such that the hose can be squeezed together by each squeeze body from the direction of the suction nozzle (12) in the direction of the pressure nozzle (14), e e c e n e z i c h n e t d u r c h

- at least one second hose (32),

- - which is elastically deformable,

- - One end (44) in the interior (46) of the housing (10) and the other end (50) outside the housing (10) ends, and

- - Which is present in the interior (46) of the housing in such a way that it can be squeezed together by moving at least two second crushing bodies (26) movable along it from the direction of its one end (44) in the direction of its other end (50).

02) peristaltic pump according to claim 1,

d a d u r c h g e k e n n z e i c h n e t that

the first squeeze bodies (26) are at the same time the second squeeze bodies (26).

03) squeeze body according to claim 1,

d a d u r c h g e k e n n z e i c h n e t that

the second hose (32) is connected to the atmosphere surrounding the housing via a check valve and opens towards the atmosphere. 04) peristaltic pump according to claim 1 or 2,

d a d u r c h g e k e n n z e i c h n e t that

the second hose (32) is aligned parallel to the first hose (22) in the housing (10).

05) peristaltic pump according to claim 4,

d a d u r c h g e k e n n z e i c h n e t that

the second hose (32) within the wall of the first

Hose (22) is present.

06) peristaltic pump according to claim 5,

d a d u r c h g e k e n n z e i c h n e t that

the second hose (32) is formed by a cavity in the wall of the first hose (22).

07) peristaltic pump according to claim 5 or 6,

d a d u r c h g e k e n n z e i c h n e t that

the cavity (32) closer to the inside (36) than to the outside (38) of the first tube (22) is present in the same.