DE4013402A1 - METHOD AND DEVICE FOR DETECTING GAS BUBBLES IN LINES FILLED WITH LIQUID, IN PARTICULAR FLEXIBLE, TUBULAR-LIKE LINES OR CONTAINERS - Google Patents

Abstract

A process and device (1) are disclosed to detect gas bubbles in flexible ducts (2) filled with liquid. Emitters/receivers (3, 4) are arranged on both sides of the duct (2) and emit individual pulses having a particular height and shape which are awaited within a particular time as reception pulses having a particular height and shape by the corresponding receivers (11, 12).

Description

The invention relates to a method and a device for the detection of gas bubbles in liquid filled Lines, such as in particular flexible lines or tubular containers such as those in the Find medical technology.

In many areas of technology as well as in medical The occurrence of gas bubbles is problematic because they are rich for example, significantly affect the flow conditions can flow, and since they penetrate human or animal vascular systems cause serious complications could be.

To counter these complications, for example with pressure infusion devices or also with devices from son Other areas provided air detection facilities that work on a photoelectric basis.

The disadvantage of photoelectric systems, however, is that to see that with opaque liquids such as blood or lipi it cannot be distinguished whether the liquid leading lines completely or only with liquid foam are filled, or if only one on the inside Adhesive residual film of liquid adhering to walls is present, while the hose itself is only gas is filling.

It is therefore an object of the present invention to provide a method ren and a device for detecting gas bubbles in to create lines filled with liquid that a sure distinction between actually with liquid or only partially or partially filled with gas bubbles enable.  

This task is solved by the characteristics of the contractor award 1 or claim 11.

According to the principles of the method according to the invention a transmission pulse of certain height and duration triggered and on Receive pulse of a certain height and within a certain expected time. This dynamic process enables the Differentiate whether the line is filled with liquid or not, or whether only the outer walls of the pipe are damp are what may be the same level of receive pulse causes a later onset response time. Here a gas bubble is principally recognized by that the transmission pulse in the presence of a gas bubble more ge is weakened than in a completely liquid filled line.

In other words, according to the ver drive a single pulse of high energy and more defined Form sent from one side of the line and during the Duration of a certain window, which corresponds to the duration of the Sen deimpulses is tuned on the other side of the line receive. By determining the ratio impulse length / window duration can be excluded that liquid accumulations around the hose because the Runtime of the defined, preferably extremely short pulse essential in the direct way from the sender to the receiver Lich is less than the transit time of a pulse that at for example run around the hose via a bypass got to.

The particular advantages of the method according to the invention counts that it offers the possibility of different gas bubbles to distinguish a size so that gas bubbles from harmless size can happen while gas bubbles from for the respective application of relevant size, for example trigger an alarm or the line to Un interruption of the liquid flow.  

The subclaims 2-10 have advantageous developments the content of the method according to the invention.

Will the line at the respective measuring point or a certain dimension, depending on the type of cable and application if predeterminable, compressed, results partly further improvement of the previously be written differentiation, because by the Together Squeeze or squeeze the hose between the transmitter side and receiver side the way of direct transmission wrestler, and also the adhesion of the line by the Contact pressure of the hose against the active surfaces of the Sender and receiver is supported.

Are two in the longitudinal direction of the line apart stood measuring points or measuring sections provided, each Generate and expect transmission signals and evaluate, results the advantage that bubble length and number of the measuring stretch passing bubbles determined with high accuracy can be.

Here, the frequency of the broadcast should expediently pulses of the delivery rate are adjusted, which the detection of Bubble length without mechanical stress in the Line guided medium simplified.

To determine the bubble length, one is preferred Embodiment of the method according to the invention response time to the transmitted impulses with the respective Flow rate of the liquid to be examined in Relation set.

If two spaced measuring sections are provided, the Be mood of the bubble length causes that first for a certain period of time the simultaneous response of both Measuring sections must be determined, in other words means that there is a bubble of length at least that corresponds to the distance between the two measuring sections. Therefore  depending on the application, the distance of the two measuring sections to the respective conditions and loading needs to be adjusted so that a critical minimum sheet length can be set by the distance between the measuring sections can, for example, trigger an alarm if they are present or the line is blocked. But also beyond this minimum size, according to a preferred Embodiment of the method according to the absolute te bubble length can be determined by two time periods be averaged, the first of which indicates the time during which respond to both measuring sections for the presence of a bubble, and the second period of time indicates the time ver strokes after the first seen in the direction of flow Measuring section is deactivated until the time at which the gas bubble leaves the second measuring section so that it no longer emits display signals. From the sum of the first and second period of time can then be related to that averaged flow rate, which in many cases is a represents known size, the absolute bubble length determined will.

Furthermore, it is with the inventive method according to the advantageous development of claim 7 possible Bladder counting, taking sequential arousal of both measuring sections indicates that the respective bubble or Bubbles have actually passed both measurement points gen a bubble that in the line section between the meas score or commutes, not right when counting is registered.

According to the invention it can further be provided that in depend the maximum permissible values for bubble length and Bubble count either triggers alarm or the line is blocked off, or that a combination of these is formed becomes.

As a particularly preferred type of generation for the broadcast and Acoustic signals should be emphasized,  whereby the special pulse generation The advantage is that the mechanical stress on the examining liquid is avoided, as they would otherwise for example through permanent sound reinforcement re would be expected at low flow rates. In addition, the acoustic individual pulse generator results supply the advantage that the measuring sections are very stable, what helps prevent false alarms from being triggered.

With the front according to the invention specified in claim 11 direction it is advantageous due to the arrangement the transmitter and the receiver face each other the pages of the management and the conditions of the broadcast reception can be installed on the outer surface of the pipe, Individual pulses of the type described above send and for the duration of a predeterminable To receive and evaluate the reception window. Hence it results the device according to the invention the same before parts like the inventive method.

By choosing the distance between transmitter and receiver it is also possible with the device according to the invention the line, which preferably squeezes out of flexible ed material exists to verfor such at the measuring points men that the distance between the transmitter and receiver is smaller is than the dimension of the line in the relaxed state. This will reduce the walking distance for the Sen designal brings about the advantages described above the detection and evaluation of the existing conditions enables. The deformation of the line results in advantageously a pair of opposing ones Lichen parallel and flat contact surfaces, their width is preferably greater than the width of the transmitter and Recipient. This can advantageously result in an error source eliminates herds at the sender and receiver at the would be wider than the contact surfaces would be that it could not be ruled out that an over the edge areas of current transmission impulses received and removed  would be rated as if he had the management and the liquid inside the pipe This source of error would exist above all if the Outside surface of the pipe would be damp, so that a passing run of a transmission pulse when the transmitter is ready and Receiver over this outer liquid film not out could be closed.

In contrast to this, the correct one according to the invention Width setting of the transmitter and receiver relative to Cable ensures that the surface of the cable is damp a bypass is created, the path of which is clearly longer is longer than the route through the line interior, so that an appropriately received signal, u. U. same signal height and shape, but only after a significantly longer approach speaking time is received.

In a particularly preferred embodiment, the De tection device of the device according to the invention two Have transmitting / receiving devices, their distance along the longitudinal axis of the line depending on the application and boundary conditions can be set. Here it is also conceivable in a device in which the invention Device for gas bubble detection is used, a fle xible adjustability of the distance of the send / receive on to provide directions.

In claims 14-17 additional devices of De tection device specified that the determination of Bla length, the number of bubbles, a barrier and an alarm enable triggering.

The device according to the invention preferably has one acoustic detection device with acoustic transmission / Receiving units on the outside of individual acoustic signals the whose signal shape and level according to the principles of the he inventive method can be set. Here at is also the signal reception and evaluation  the principles explained above.

Further details, features and advantages of the invention result from the following description of an embodiment Example based on the drawing.

It shows:

A longitudinal section through a conduit with an inventive device Bubble Erkennungsvor is provided Fig. 1 shows a schematically simplified representation,

Fig. 2 shows one of Fig. 1 representation corresponding to a section through a transmission-reception means of the apparatus according to Fig. 1,

Fig. 3 is an illustration of a transmission pulse,

Fig. 4 shows a receive pulse when the line is empty, and

Fig. 5 shows a receive pulse when the line is filled.

In Fig. 1, an inventive device 1 for detecting gas bubbles in a liquid is shown, which is guided in a line 2 . The line 2 can in principle be part of a device or device from all the technical or medical fields in which gas bubbles can occur in flowing liquids, and in which the occurrence of such gas bubbles can lead to complications, so that detection is required . The occurrence of gas bubbles in the medical field is particularly problematic, for example in the case of arterial or venous infusion, since even the smallest amounts can lead to considerable damage to the patient and even death. However, it should be emphasized again that the use of the device according to the invention is not restricted to the medical field, so that the line 2 can in principle be any type of preferably flexible and tubular line or container. The device 1 according to the invention has a detection device arranged outside the line 2 , which in the case of example has two transmitting / receiving devices 3 and 4 , which are arranged along the longitudinal axis L of the line 2 at a preselectable distance from one another. On the basis of the illustration of the flow direction F selected in FIG. 1, the transmitting / receiving device 3 det a first measuring section, while the transmitting / receiving device 4 represents a second measuring section.

The detection device of the device 1 according to the invention has, in addition to the transmitting / receiving devices, the usually required energy sources, a pulse generator, an alarm device and evaluation and display units, which are symbolized schematically in FIG. 1 by block 5 . Furthermore, a schematically simplified shut-off device 6 , which is arranged behind the second measuring section 4 in the flow direction F, is provided, which can comprise, for example, two shut-off swords 7 and 8 which, if necessary, completely close the line 2 . From the locking device 6 can be part of the Detektionsein direction and controlled depending on the detection of Luftbla sen in line 2 and thus operated to shut off line 2 .

As illustrated in FIG. 1, each transmitting / receiving device 3 , 4 has a transmitter 9 or 10 and a receiver 11 or 12 arranged opposite it. In the preferred embodiment shown in FIG. 1, the transmitting / receiving devices 3 and 4 are acoustic measuring sections which emit individual pulses of a defined shape and height and, with their receivers 11 and 12, these due to the presence or absence of gas bubbles receive more or less weakened signals according to a pre-tunable reception window.

The transmitters 9 , 10 and receivers 11 , 12 are each arranged on opposite sides of the line 2 , as can be seen from FIG. 1 and from the individual illustration of FIG. 2. Here are transmitter 9 , 10 and receiver 11 , 12 on the outer surface of the line 2 and press them to the measuring points in the manner shown in FIGS. 1 and 2 together. As a result, support wall areas 13 and 14 ( FIG. 2) are formed which are essentially planar and are aligned parallel to one another. From Fig. 2, which can be seen representative of both transmit / receive devices 3 , 4 , it is clear that this results in a compression of line 2 , which results in the distance between the transmitter and receiver of the respective transmit / receive device 3 , 4 reduced in size compared to the dimension of the line when not compressed.

Fig. 2 further illustrates that the width of the transmitter and receiver is less than the width of the support wall rich 13 , 14th This ensures that when the outer wall of line 2 is wet, a pulse must run through a bypass that speaks to the curved edge regions 15 and 16 , which is considerably longer than the direct path between the transmitter and receiver perpendicular to the support walls 13 and 14 .

A possible construction of a transmitting / receiving device of the device 1 according to the invention, which is designed as an acoustic air sensor, is described below by way of example with reference to FIG. 2. Reference is made here by way of example to the transmitter 9 , since in principle it is constructed in exactly the same way as the receiver 11 . The transmitter 9 has a membrane 17 and a piezo disk 18 which is connected to the membrane 17 . This arrangement can e.g. B. positioned by means of a suitable body on the line 2 who the. The transmitter 9 can be connected to a high-voltage pulse generator not shown in FIG. 2.

The receiver 11 is constructed in a corresponding manner.

With this type of structure, two acoustic transmit / receive devices 3 and 4 are thus formed, which can be operated according to the principles of the inventive method explained at the outset.

The type of generation of the transmit / receive pulses is illustrated in FIGS . 3-5, where FIG. 4 illustrates a receive pulse when the line is empty, while FIG. 5 shows the receive pulse when the line is full.

The embodiment shown in Fig. 1 allows due to the provision of two measuring sections 3 and 4, both a determination of the absolute bubble length and a bubble counting. Therefore, in a particularly preferred embodiment, the detection device of the device 1 according to the invention also has a bubble counting device and a determination device for the bubble length, which are also symbolized by block 5 .

If, for example, the length of a bubble passing the line 2 in the direction of the arrow F is to be determined, a determination is first made through the first measuring section 3 and, after the bubble has reached the measuring section 4 , so that both measuring sections 3 and 4 on the Address the presence of a blister. The time during which both measuring sections 3 and 4 respond is registered as the first time period. As soon as the first measuring section 3 is deactivated, that is to say the Bla has left the measuring section 3 , there is a time count which determines a second period of time during which the second measuring section 4 still indicates the presence of the bubble. The absolute bubble length can then be determined from the sum of the first and second time periods determined in this way and the usually known flow speed. The prerequisite here is that the bladder has a certain minimum length which corresponds to the distance between the measuring distances 3 and 4 . Accordingly, by selecting the distance between the measuring sections 3 and 4, for example, a critical minimum size can be set, when detected, for example, an alarm in block 5 or a blockage of the line can be triggered by the shut-off device 6 . This alarm and shutdown is particularly important in the medical field, for example, when an infusion is carried out and the air is detected shortly before the entry of line 2 in the patient, so that an immediate shutdown can take place if a critical bubble size or number has been determined.

The device according to the invention thus has the advantage that both quantitative and qualitative recognition of gas bubbles in lines filled with liquid possible is.

Claims (20)

1. A method for the detection of gas bubbles in liquid-filled lines ( 2 ), in particular flexible lines or containers, in which at least one single transmission pulse of a certain height, shape and duration is triggered on one side of the line and a reception pulse of a certain height and shape and is expected on the other diametrically opposite side of the line within a certain time. 2. The method according to claim 1, characterized in that a high energy transmit pulse is generated. 3. The method according to claim 1 or 2, characterized net that the line at the measuring point by a predetermined dimension is compressed. 4. The method according to any one of claims 1-3, characterized ge indicates that at two in the longitudinal direction of the line spaced measuring points transmit pulses he be witnessed and expected. 5. The method according to any one of claims 1-4, characterized ge indicates that to determine the absolute bubbles the response time with the respective flow velocity liquidity of the liquid under investigation becomes. 6. The method according to claim 4 and 5, characterized in that the determination of the absolute bubble length thereby he follows that it is determined whether for a period of time both measuring points with the presence of a bubble It is stated that this time is used as a first time period  is stored that the time is determined from which at the first measuring point seen in the direction of flow there is no more bubble that the Bladder present only on the second measurement is determined as a second period of time, and that from the sum of the first and second periods and the Bla determined the determined value of the flow rate length is derived. 7. The method according to any one of claims 4-6, characterized ge indicates that to count individual bubbles one Size that is smaller than the distance between the measurements score, it is determined whether both measuring points are sequential detect the presence of a bubble and that the Bla Represent the transmission passage through the second measuring point the signals are counted. 8. The method according to any one of claims 1-7, characterized ge indicates that depending on the adjustable maximum values for bubble number and bubble size when exceeded at least one of these maximum values triggered an alarm becomes. 9. The method according to claim 8, characterized in that if the maximum values are exceeded, the line also is cordoned off. 10. The method according to any one of claims 1-9, characterized ge indicates that acousti as transmit and receive pulses cal signals are generated or received. 11. Device ( 1 ) for detecting gas bubbles in lines filled with liquid ( 2 ), in particular flexible, tubular lines or containers,

• - With a detection device arranged outside the line ( 2 ) with at least one transmitting / receiving device ( 3 , 4 ) which has a transmitter ( 9 or 10 ) and a receiver ( 11 or 12 ), as characterized by
• - That the transmitter ( 9 , 10 ) on one side of the line ( 2 ) and the receiver ( 11 , 12 ) on the other diametrically opposite side of the line ( 2 ) is arranged, and
• - That the transmitter ( 9 , 10 ) and the receiver ( 11 , 12 ) rest on the outer surface of the line ( 2 ).

12. The apparatus according to claim 11, characterized in that the distance of the transmitter ( 9 , 10 ) to the receiver ( 11 , 12 ) perpendicular to the longitudinal axis (L) of the line ( 2 ) is smaller than the outer dimension of the line ( 2 ), and that thereby create two support wall areas ( 13 , 14 ) of the line ( 2 ) ge, which are arranged substantially parallel to each other. 13. The apparatus according to claim 12, characterized in that the width of the transmitter ( 9 , 10 ) and receiver ( 11 , 12 ) is less than the width of the support wall areas ( 13 , 14 ). 14. Device according to one of claims 11-13, characterized in that the detection device has two Sen de / receiving devices ( 3 , 4 ) which are arranged along the longitudinal axis (L) of the line ( 2 ) at a selectable distance from each other. 15. The device according to any one of claims 11-14, characterized in that the detection device has a counting device ( 5 ), which he averages the number of bubbles, the transmitting / receiving devices ( 3 , 4 ) pass. 16. The device according to any one of claims 11-15, characterized characterized in that the detection device further  a device for determining the absolute bubble length has the response time with the flow velocity fluidity (F) of the fluid in the line in Re lation sets. 17. The device according to any one of claims 11-16, characterized characterized in that the detection device further has an alarm device. 18. Device according to one of claims 11-17, characterized in that a shut-off device ( 6 ) is provided, the line ( 2 ) for blocking the fluid flow in the shortest possible time in alarm cases depending on the detection of bubbles of critical size or number locks. 19. Device according to one of claims 11-18, characterized in that the transmitting / receiving device ( 3 , 4 ) are designed as acoustic air detectors. 20. The apparatus according to claim 19, characterized in that the transmitter ( 9 , 10 ) and receiver ( 11 , 12 ) with piezo elements for generating the transmit pulses or receive pulses are provided.