NO144410B - DOSAGE PUMP DEVICE. - Google Patents

Description

The present invention relates to a dosing pump device for use in a flow system for infusing a fluid from a reservoir to the human body through a tube, where the pump device comprises a pump of peristaltic

tic type with a number of movable pressure means which press against the side wall of the tube for compression of its cross-sectional opening which repeatedly and progressively compresses and resumes its shape along a portion of the tube so that fluid is forced through the tube, and a flow limiting device for continuous, at least partial limitation of the cross-sectional opening downstream of said pipe part.

Infusion of fluids, such as parenteral solutions and blood, into the human body is usually performed by means of an administration set in conjunction with a suitable flow measuring device for controlling the flow rate of the fluid through the set. One form of flow measuring device which is potentially attractive for this application is a peristaltic type pump which operates by repeatedly compressing and expanding a section of a pipe or hose in such a way as to cause the fluid to flow through the pipe or hose. -gene in a controlled quantity. Unfortunately, the function of such peristaltic-acting pumps has not been completely satisfactory in connection with administration sets due to inaccuracies in the dosage or measurement, which is caused by the partially inelastic property of the vinyl plastic piping system usually used in such sets, and as a result of this, the use of such pumps has been limited to areas of application, such as blood treatment, which require a less critical control or management of flow rate or flow rate.

During the operation of a peristaltic pump, the pipe or hose section that the pump affects is subjected to a cyclically repeated compression under tension. Due to its partially inelastic nature, a piping system made of vinyl plastic or other thermoplastic materials may over time undergo a permanent change in shape and size as a result of such cyclic action, resulting in the amount of fluid being delivered

of the pump can change in an undesirable way. In known pumps of the peristaltic type, spigot followers, rollers, side supports or similar devices are used, which, after compression, form contact with the edges of the deformed pipe or hose section in an attempt to return the hose section to its

original form, but these known methods have had only limited success.

Another problem that arises when using peristaltic pumps together with infusion sets is that there is a possibility of an uncontrolled, gravity-induced fluid flow into the patient's body, if a tubing failure occurs or if the tubing is accidentally removed from the pump. Also, dissolved gases in a liquid, which is being infused, can be released in the form of bubbles when the liquid is subjected to pressure and/or temperature changes as the liquid passes through the peristaltic pump. These bubbles can unite and thereby form larger bubbles or gas pockets that can be introduced into the patient's body together with the liquid, which can be harmful or even fatal to the patient under certain circumstances.

In order to prevent the introduction of gas, sensors can be placed after the discharge end of the pump that automatically stop the pump if gas is detected or if the fluid flow is interrupted. - Although such sensors are effective in preventing the infusion of gas, the stopping of the infusion process which the sensors give rise to, be a risk for a critically ill patient, and this necessitates that medical staff must be constantly available to restore the process.

The present invention relates to a dosing device, with which a particularly good control or management of the fluid flow is achieved by reducing the physical and dimensional changes in the pipe or hose system to a minimum, and with which the release of dissolved gases from the fluid is reduced to a minimum, and with which protection is achieved against an uncontrolled fluid flow should the pump fail or seize

away accidentally.

In most known peristaltic pumps, a typical component comprises several rollers or the like against which a pipe or hose section is compressed by means of a spring-biased pressure plate, so that a pipe section is compressed and released repeatedly when the rollers are moved along the plate, whereby the fluid is made to flow through the pipe system. In such pumps, there is a change in the number of rollers that are in compressive contact with the pipe section as the rollers are moved forward, so that e.g. at one time there may be two rollers pressing the pipe section together, while at another time there is one roller pressing the pipe together. As the rollers act on a common pressure plate, the compressive force exerted on the pipe section by a roller will vary when the number of rollers pressing the tube together varies. If the compression force varies too much, e.g. in a ratio of 2:1, the vinyl plastic tubes that are usually used in infusion sets can be exposed to rapid deformations, stretching, squeezing, and possibly the tube can even be opened when broken. The end result can be a drop in or loss of fluid flow with the consequent possibility of injury to the patient.

The purpose of the invention is to produce a dosing pump device which provides a very accurate dosing of the fluid and provides good protection against uncontrolled fluid flow and bubble or gas formation in the fluid.

The characteristic features of the invention will be apparent from

the subsequent patent claims.

The invention will be explained in more detail below with reference to the accompanying drawings, where in the figures the same reference numerals denote similar elements, as:

Fig. 1 shows a perspective view of an infusion system

with the dosing pump device according to the invention.

Fig. 2 shows an enlarged front view of the pump device and a flow-limiting station, which are included in the infusion system according to fig. 1. Figures 3a and 3b show enlarged views of part of the infusion system illustrating the effect of the flow limiting station on the system. Fig. 4 shows a front elevation of a pump of the linear peristaltic type and a flow limiting station which is connected thereto and which is suitable for use in connection with that in fig. 1 showed infusion system. Fig. 5 shows an enlarged view of a pump of the rotary peristaltic type and an associated, flow-limiting sta- . tion, which makes use of a common support block. Fig. 6 shows an enlarged front elevation of a rotary peristaltic pump similar to that in fig. 5, but with a different construction of the flow limiting station. Fig. 7 shows an enlarged front elevation, partly in section, of details of the one in fig. 2 showed the construction of the flow limiting station. Fig. 8 shows a front elevation of another construction of the flow limiting station. Fig. 9 shows a section of yet another construction of the flow limiting station. Fig. 10 shows a front elevation, partially in section, of a further embodiment of the flow limiting station. Fig. 11 shows a front elevation of a peristaltic pump according to the invention in an inoperative, open position. Fig. 11a shows a partial front elevation of the peristaltic pump and the flow limiting station in Fig. 11,

and shows the system's function further.

Fig. 12 shows a section along the line 12-12 in fig. 11 of the peristaltic pump and shows the flow limiting station in the open position. Fig. 12a shows a similar section as fig. 12, but shows the flow limiting station in the closed position. Fig. 13 shows a section along the line 13-13 in fig. 12 and shows the control and working surfaces of a plunger piston for restricting the flow. Fig. 14 shows a front elevation of the peristaltic pump in a closed operating condition with certain parts omitted to show the arrangement of pressure rollers located in the pump rotor. Fig. 15 shows a section of the peristaltic pump along the line 15-15 in fig. 14.

Reference is made to the drawings, especially fig. 1, where a infusion system for introducing a fluid into a vein or an artery from a reservoir 11 comprises a single-use administration set and consists of a first pipe or hose section 12, a drip chamber 13, a second pipe or hose section 14,

a pipe clamp 18 for flow control, as well as a needle holder 19 to which a needle or needle of suitable size is attached

and form. The tube sections in the administration set, which may be of conventional design and construction and may be packaged in a sterile and non-pyrogenic condition, are preferably formed of a thermoplastic material, such as vinyl plastic.

The second pipe section 14 in the administration set runs through a pump device 15 which comprises a rotating peristaltic pump 16 and a flow limiting station 17 downstream of the pump. The pump device comprises a suitable mechanical coupling 22 for decoupling the pipe 14 from the pump and the flow limiting station during assembly and disassembly operations. Suitable control circuits for the pump can also be arranged to enable accurate and consistent control and measurement of the amount of fluid that is introduced into the patient's body. Such a circuit can comprise a photocell 20 and a light source 21 which cooperates with this and which is designed to detect missing fluid in the tube, a dose counter 23 for summarizing the delivered fluid quantity, as well as control devices 24 and 25 for controlling the delivery quantity flow respectively the total dosage.

As shown in fig. 2, the peristaltic pump 16 comprises a rotor 30 with several pressure rollers 31 placed at the same distance from each other along the circumference of the rotor. A pressure block 32 with a working surface which in shape largely corresponds to the circumference of the pump rotor 30 is placed so that the tube 14 is brought into pressure-transmitting contact with part of the rollers 31, so that the rollers allow fluid in the tube's interior to pass through the tube towards the needle holder when the rotor 30 rotates (clockwise in fig. 2). In fig. 2

are three rollers 31a, 31b and 31c in engagement with the pipe 14 and thereby form two isolated sections 14a and 14b along the pipe, in which the fluid is located as it moves forward. It should be noted that the tube 14 must be compressed substantially completely under the rollers and at least partially returned to its normal, unclamped state in the areas between the rollers in order for the peristaltic pump to function.

After passing through the peristaltic pump, the tube 14 runs between the light source 20 and the photodetector 21 to the flow limiting station. This step comprises a pressure or counterholder block 33 which is displaceably mounted, and a wedge-shaped plunger piston 34 which forms contact with the pipe wall when the pipe is held in position against the pressure block. As a result of this, the pipe opening is reduced to form a pipe section 14c between the contact point of the last roller 31 in the pump and the contact point of the wedge-shaped plunger piston 34. The plunger piston 34 is mounted displaceably in a housing 35 and is biased in the direction of the pipe 14 by by means of a coil spring 36 in the housing 35, which rests against a collar 37 which is attached to the plunger piston,

and a plug or cap 38 which is removably screwed into the back of the housing.

According to a feature of the invention, the flow-limiting station serves to increase the pressure in the pipe section 14c. If this flow limiting station is not present, dissolved gases in the fluid being administered, as shown in fig. 3a could be separated from the fluid downstream of the pump station as a result of temperature and/or pressure changes brought about by the action of the pump rollers 31 or as a result of the fluid being heated by the pump device at low flow rates, and bubbles 39 are thereby formed between the needle holder 19 and the pump device. These bubbles, if they have the opportunity to unite, could form air pockets which, if introduced, could result in death or serious injury to a patient. As shown in fig. 3b, there is an increase in the fluid pressure in the pipe section 14c by means of the flow-limiting station, and thereby the excretion of dissolved gases is prevented.

According to the invention, the pressure in section 14c can also help to provide a certain expansion of the pipe walls after the last pressure roller 31 is no longer in engagement with the pipe. This is shown in fig. 3b, where the roller 31c is about to come out of engagement with the pipe, and the pressure built up in section 14c can just begin to help or contribute to a shape-wise return of the pipe wall, so that the fluid trapped in the pocket or section 14b can pass freely from the pumping station. It is this restoring force on the walls of the tube which enables a pump of the peristaltic type to be used together with the tubes or hoses of vinyl plastic or thermoplastic which are usually used in fluid administration sets.

The same principles apply when using a peristaltic pump of the linear type, which can replace the one in fig. 1-3 showed a rotary type peristaltic pump. In that case, the tube 14 is passed over a pressure or counterholder block 41, and a number of individually extendable fingers 42 are brought to form

installation against the pipe wall. These fingers 42 press the tube 14 together,

at least in two separate locations 14d and 14e, so that an isolated and non-compressed pipe section 14f is formed. During operation, the fingers are pushed out cyclically from left to right on one. in such a way that the isolated section 14f and thus the trapped fluid in this is moved forward through the pump.

The system comprises a flow-limiting station 17 which is located downstream of the pump 40, which can be similar to the station in the pump device 15 described above. A pipe section 14g is thereby formed where the fluid pressure is increased in order to prevent the release of dissolved gases from the fluid and for to contribute to the shape-wise return of the tube after compression by means of the fingers in the peristaltic pump 40.

To help keep the tube 14 firmly in position it can

in fig. 4, the pump device shown comprises a first pipe holder 43 upstream of the pump 40 and a second pipe holder 44 downstream of the flow limiting station 17. As in the pump device 15 described above, a light source 20 and a photodetector 21 can be arranged in connection with the pipe section 14g to detect a lack of fluid in the system.

It must be noted that different modifications can be made to the pump device 15 in the infusion system with a view to easier operation. E.g. can, as shown in fig. 5, a common pressure or moth<p>lder block 4 5 is used for both the peristaltic pump and the flow limiting station. The pressure block 45 comprises a curved part, which, in the same way as the corresponding component in fig. 2, brings the pipe 14 to form contact with the pressure rollers 31 on the pump raptor 30. The pressure block comprises a flat part downstream of the rotor, whereby a surface is formed against which the plunger piston 34 can form contact. This arrangement facilitates the insertion and removal of the tube 14, but other measures (such as a closing of the clamp 18) are required to prevent a gravity-induced flow if the block 45 fails or disconnects.

Fig. 6 shows a modification of the one in fig. 5 showed common pressure block. In this embodiment, the flow-limiting station comprises a wedge-shaped plunger piston 46 which is inserted displaceably in a channel 47 in a pressure block 48. The wedge-shaped end of the plunger piston 46 can be moved towards a stationary block 50 to narrow the tube 14 light opening. A manually rotatable gear wheel 49 engages with a rack face on the plunger piston and enables this to be moved selectively forwards or backwards by the user in order to vary the pressure exerted on the pipe, and to be able to accommodate pipes of different diameters and wall thicknesses, as well as for to be able to compensate for different temperature and pressure effects that may occur.

As shown in fig. 7, a similar pressure setting can be achieved in the one in fig. 1 and 2 showed the flow limiting station 17 by arranging an adjustable cap or plug 51 at the rear end of the spring 36, so that the force exerted by the spring, and thus the force exerted by the plunger, can be increased or decreased by the user. The cap or stopper 51 is screwed into the housing 35 and can be equipped with a grooved area 52 which can be grasped by the user and facilitate turning of the cap in relation to the housing.

A further embodiment of the flow limiting station is shown in fig. 8. In this embodiment, a pressure block 53 is arranged with a channel 54, and the pipe 14 forms an abutment against one wall in this channel, and a leaf spring 55 is attached to the opposite channel wall. This spring is brought into contact with the pipe wall by means of a threaded finger screw 56 which forms contact with the middle part of the spring body in order to move its free end towards the pipe.

Yet another embodiment of the flow limiting station is shown in fig. 9. In this embodiment, a pressure block 57 is arranged with a central channel 58 in which another pressure block 59 is displaceably inserted. The tube 14 is inserted between the stationary block 57 and the displaceable block 59, and the two blocks are brought together by means of a spring 60 which is biased against a plug 61, which can be regulated by the user and which is screwed into a bore 62 in block 57.

Fig. 10 shows a modification of this arrangement. In this embodiment, the displaceably mounted pressure block 59 is forced against the pipe 14 by means of a thumb screw 63 which is screwed into the stationary block 57 and which is inserted into a bore 64 in the block 59. A set screw 65 connects the thumb screw 63 to the block 59 for axial movements, but not for turning movements.

Although the flow limiting station does not need to comprise a fixed pressure block, against which the plunger piston is brought into contact, significant advantages can be achieved by spring loading the plunger piston. Such a spring load relieves

the need to set the flow limiting station to

to accommodate different flow rates and different pipe sizes. The arrangement of a spring-loaded plunger also provides the ability to completely block the pipe if the pump pressure drops, so that in the event of the pump failing or being accidentally removed, the plunger will cause a complete pinching of the pipe and thus prevent an uncontrolled, gravity-induced flow into the the patient. Also, the spring loads help to maintain an upstream pressure in the pipe when a roller comes out of engagement with the pipe.

Because peristaltic pumps can produce relatively large pressures, a relatively large force can be exerted by the plunger piston in the flow restricting station on the pipe 14 to ensure that the pipeline will be completely clamped

and shut off if or when the pressure from the pump ceases. IN

a particularly suitable embodiment of the invention with a peristaltic pump of rotary type, a pipe made of vinyl plastic with a wall thickness of 0.56 mm and a light opening diameter of 2.54 mm has been exposed to a pressure of 45.4 kp.

Before use, the peristaltic pump is opened, and the administration set's tube or hose is passed from the reservoir through the pump and the flow limiting station to the patient. The pump is then started until the pipe 14 is filled with fluid. The needle or cannula is then inserted into a vein or artery, and the pump is restarted to begin a controlled infusion of the fluid into the patient. The infusion flow is set using the control devices arranged on the pump structure. The administration set can also be filled from the reservoir using gravity, before the tube is inserted into the pump, whereby connection to the patient takes place after or immediately before the tube is inserted into the pump.

In any case, it will cross-sectional reduction

which is formed in the pipe by the flow-limiting station downstream of the pump station, produce a back pressure against which the pump must work. This prevents the release of gases dissolved in the fluid when the fluid's temperature and/or pressure changes as a result of the pump's impact. The cross-sectional reduction also serves to prevent a free, gravity-induced fluid flow through the system if the system pressure drops.

The flow limiting station can be used with the greatest advantage when the pump rotor has a smaller number of pressure rollers, such as in the one in fig. 11-15 showed an embodiment with four rollers.

In this embodiment, it comprises a peristaltic pump

a rotor 70 with four pressure rollers 71 arranged with the same mutual distance along the circumference of the rotor. Each roller is mounted on a shaft 72 for free rotation about it, and the shafts are carried by a slide 73 (Fig. 14) and are limited to radial movement by an associated radial slot 74. Each slide 73 is mounted so that it can be moved back and forth in a radial bushing 75, and the slide is spring-loaded in a radially outward direction by a coil spring 76 which is inserted in the bushing. One end of the spring forms contact with a groove 77 in the slide, while the other spring end is inserted in a groove 78 in the hub of the rotor.

The pump also includes a pressure or counterholder plate 80

with a curved working surface 81 whose shape largely corresponds to the circumference of the pump rotor 70, and this working surface is placed so that the pipe 14 is brought into compressive contact with a part of the rollers 71 about at least the part of the rotor's circumference that is located between successive rollers. In the embodiment shown with four rollers, the tube 14 must run around the rotor at least along 90° of its circumference.

The pressure plate 80 can move towards and away from the rotor 70 to facilitate the insertion and removal of the tube 14 by moving an arm 82 which is held in a vertical slot 83 in the pump stand. This movement is translated into a transverse movement of the pressure plate 80 by a cam on the arm 82 which engages with a transverse, increasing slot 84 on the pressure plate. When the arm 82

is in its bottom position as shown in fig. 14, the pressure plate is moved inwards towards the rotor 70, the surface 81 of the pressure plate being sufficiently close to the rotor periphery to cause the pipe 14 to be completely closed by the rollers 71. In this position, the pressure plate will be locked in position and held stationary in relation to the rotor. Since each roller 71 is individually biased in engagement with the pipe section, the applied pressure is independent of the position of the roller and of the number of rollers that are in engagement with the pipe section.

As in the above-described embodiments, the tube 14, after passing through the peristaltic pump, runs between a light source 20 and a photodetector 21, which together form a gas or bubble detector, and on to a flow limiting station. This station comprises a pressure or counterholder block 86 and a displaceable limiting plunger piston 87. According to another aspect of the invention, the end of the plunger piston 87, which engages the tube 14, comprises a generally L-shaped head 88 having a wedge-shaped working surface 90 and a planar guide surface 91. The plunger 87 has a shaft part 92 which is displaceably inserted in a mounting block 93 and which runs through the middle part of a helical pressure spring 94, which is adapted to bias the head 88 into engagement with the tube 14.

The working surface 90 forms an abutment against the wall of the pipe 14 largely perpendicular to the direction of flow in the pipe when it is held in position against the pressure block 86. As a result, the light opening of the pipe is closed at the contact point, and a downstream pipe section 95 is formed between the contact point of the roller 71a (fig 14) in the pump and the point of contact for the working surface 90. As mentioned above, the closing of the pipe increases the pressure of the fluid in the section 95, thereby preventing the excretion of dissolved gases therein. Since the four rollers 71 have a mutual distance along the circumference of the rotor 70, which corresponds somewhat less than the part of the circumference that is in contact with the pipe section 14, according to another aspect of the invention, almost the entire pipe section will be downstream of the flow-controlling roller. 71a (fig. 14) be exposed to back pressure. This produces an optimal pumping effect, as back pressure exists over the entire pipe length where the pump rollers act, thereby preventing gas separation in the isolated pipe sections, which would otherwise exist if a larger part of the rotor circumference and a correspondingly larger number of rollers were to be brought into engagement with the tube. This also eliminates measuring inaccuracies, which could be due to parts of the pipe section, which are affected, but do not receive a restoring force after the rolling action, as such isolated pipe sections will not return to the uncompressed shape over a certain period of time due to cold flow and other fatigue -, time- and temperature-dependent phenomena.

The guide surface 91 of the plunger piston 87 runs mostly. parallel to the flow direction of the fluid, and the control surface has a significantly larger area than the working surface 90. The relatively large area of the working surface 90 makes the plunger piston more sensitive to pressure in the interior of the pipe when the pump is working, and thereby higher pressure forces can be exerted by the spring 94, whereby the pipe can - is blocked more effectively when the pump is not working, without damaging the ability to open the pipe, even at low working pressures. As a result of this, the pump device according to the invention produces a very good function and efficiency with pipes made of vinyl plastic and other thermoplastic materials.

As an example of the very good efficiency that can be achieved by using the control surface 91, it can be stated that with a typical vinyl plastic pipe with a light opening of 2.54 mm and with a wall thickness of 0.51 mm, a fluid pressure of up to 17 .5 kp/cm 2 with the pump to open the pipe, if this is closed by means of a plunger piston with a spring force of

1.6 kp and with an effective working surface area of 9.0 mm 2 . By using a control surface such as surface 91 with an effective area of 28.1 mm 2 , however, only a pressure of . 5.8 kp/cm<2 >to open the tube or plunger.

The plunger piston 87 can be brought into the open position to

facilitate insertion or removal of the tube section 14 by means of an arm 96 which is adapted to be actuated by the user and which is rotatably attached to the free end of the shaft member or spindle '92. In the open position of the plunger, the arm is 96

as shown in fig. 11 placed above the center in relation to the spindle 92, whereby the plunger piston is locked in the open position. In the closed position, the arm 96 as shown in fig. 14

repositioned so that the free movements of the spindle are enabled.

A cam surface 9 7 on the arm 96 cooperates with a cam surface 98 on the pressure plate 80 for automatic closing of the plunger piston 87

when closing the pressure plate.

In the closed position, the pressure exerted by the spring 94 is sufficient to close the pipe 14 completely when there is no pressure from the pump, as shown in fig. 12a. During operation, however, sufficient pressure develops in the interior of the pipe to open it, at least partially, as shown in fig. 12. This pressure exists in the interior of the entire pipe section 81, and the pressure serves to prevent sudden changes in the fluid pressure that would otherwise occur in the section when the downstream roller (71b in Fig. 14) is brought out of engagement with the pipe.

As can be seen best from fig. 13, the head 88 of the plunger piston 87 preferably has a guide member 99 which prevents the tube 14

in going out<v>of intervention.

Claims (3)

1. Dosing pump device for use in a flow system for infusing a fluid from a reservoir to the human body through a tube (14), the pump device comprising a peristaltic type pump (16,40) with a number of movable pressure means (31,42, 71) which presses against the side wall of the pipe to compress its cross-sectional opening which repeatedly and progressively compresses and resumes its shape along a portion of the pipe so that fluid is forced through the pipe, and a flow restricting device (17) for continuous, at least partial restriction of the cross-sectional opening downstream of said pipe part, characterized in that the number and arrangement of the pressure means (31,42,71) is such that the pipe part is constantly engaged with at least one of the pressure means (31,42,71) and thereby closes the pipe part completely to form a continuous back pressure of significant magnitude in a pipe section (14c, 14g, 95) between the flow-limiting device (17) and the relevant pressure device. 2. Pump device in accordance with claim 1, where the peristaltic pump comprises a number of pressure means (71) which are arranged at the same distance from each other on a rotor (70) and project radially outwards from this, and a support device for the pipe in the form of a pressure plate (80) which has a working or support surface (81) of roughly the same shape as the rotor (70), characterized in that the pressure plate (80) is arranged to bring the pipe into engagement with the pressure means (71) only over a part of the pipe corresponding to the space between the pressure means on the circumference of the rotor (70). 3. Pump device in accordance with claim 2, characterized in that the pressure plate (80) is slidably connected to a housing and has an open position at a distance from the circumference of the rotor (70), and a closed position at the circumference of the rotor, that a device for locking a plunger body (87) is an arm (96) which is rotatably connected to the plunger body and has an opening position for the plunger body (fig. 11) where this is locked in the open position, and a closed position for the plunger body (fig. 14) which enables free movement of the plunger body, and that a cam surface (97) on the arm (96) cooperates with a corresponding surface (98) on the pressure plate (80) for automatic closing of the plunger body (87) when the pressure plate is closed.