SU1138169A1 - Blood microfilter - Google Patents

Abstract

BLOOD MICROFILTER, consisting of a filter element located in the housing with an inlet and outlet for blood, characterized in that, in order to reduce the initial filling volume while maintaining the filtration area, the filtering element is a set of parallel filtering partitions between which separator plates are installed, each filter partition has a sealing frame around the perimeter, in which in places of interface with diametrically located inlet and outlet Each pipe has recesses, and each separator plate has - on both sides of the collar with a recess similar in shape and size to the recesses of the frame, with the recesses of the ribs of different sides of the plate located diametrically and two diametrically placed recesses on different sides of the plate (L length and equal to the length of the grooves, with each plate having hemispherical protrusions uniformly distributed on both sides, the centers of which are spaced one from another at a distance greater than the diameter of the protrusions 2-5 times. oe 00 O) f

Description

The invention relates to medical and medical technology, in particular to perfusion and transfusion, and can be used for microfiltration of blood in the artificial blood circulation apparatus and in blood transfusion systems. Blood microfilters are known, which are based on the use of filter material or a set of several types of filter materials placed in a casing that allows blood to pass through filter material P, However, these microfilters do not meet the following requirements: filtering blood from particles of various sizes during filtration. blood cells, the absence of an increase in the hydraulic resistance of the filter during prolonged operation is a small primary volume of blood. Closest to the invention is a blood microflator consisting of a filter element disposed in a housing with blood inlet and outlet 2j. The disadvantage of the known microfilter is the large volume of primary blood filling (150 ml with a filter surface area of 95 cm) required to evenly distribute blood flow across the filtering surface. The purpose of the invention is to reduce the primary filling volume while maintaining the filtration area. This goal is achieved by the fact that in a blood microfilter consisting of a filtering element located in a housing with blood inlet and outlet nozzles, the filtering element is a set parallel to the filtering walls, between which are separating plates, each filter partition has a sealing frame by the perimeter, in which in the places of interface with diametrically located inlet and outlet nozzles the grooves are made, and each separator plate and EET. on both sides of the collar with a notch similar in shape and size to the notches of the frame, with the notch of the shoulders of the different sides of the plate arranged diametrically, and two diametrically placed recesses on different sides of the plate with a length equal to the length of the notches, each. This plate has a hemispherical-shaped protrusions uniformly distributed on both sides, the centers of which are spaced apart from one another at a distance greater than c. 2-5 times the diameter of the protrusions .. Figure 1 shows the microfilter, general view; Fig. 2 shows a section A-A in Fig. 1 (arrows indicate the directions of blood flow); in FIG. 3, a microfilter with a clear key; Fig. 4 is a filter septum, general view; in Fig.5 a section in Fig.4; 6 is a separation plate, top view; figure 7 is a section bb-6. Fig. 8 is a separator plate, bottom view. The case 1 of the microfilter with the cover 2 has an inlet 3 and an outlet 4 for the blood tube. Filter walls are filter material 5, enclosed around the perimeter in the sealing frame 6 of a polymeric material. The filter partitions 5 are located in the housing 1 in parallel and are separated from each other by separation plates 7. Each filter partition has in the sealing frame 6 notches 8 and 9 in conjunction with the inlet 3 and the outlet 4 with blood nozzles, respectively. Um1: both 8 and 9 are made to the full thickness of the partition. And have a width h not exceeding the width of the sealing frame 6, and a length t smaller than half the circumference of the sealing frame 6, Separating plates 7 have a collar 0 on both sides with notches II or 12 ,, The grooves 8 and 9 are similar in shape and size, with the grooves 11 and I2 being located diametrically. Plates 7 also have diametrically spaced out grooves 13 and 14 with a length - that coincides. with a notch length of 8, 9, 11 and 12. A notch serves to form inlet 15 and outlet 16 blood collectors. Each dividing plate 7 has a hemispherical protrusion 17 uniformly distributed on both sides, the centers of which are one tons of another at a distance exceeding the diameter of the protrusions 2-15 times. The range of the distance between the protrusions 17 is selected from the conditions for ensuring optimal filter operation. If the distances are too small, the jaws of the j (less than 2 diameters of the protrusion) significantly increase the hydraulic resistance of the filter. At the same time, as the distance between the protrusions increases, the positive effect achieved due to their presence decreases, i.e. the volume of filling the filter with blood increases. In addition, when the distance between the centers of the protrusions is 5-6 times larger than the diameter of the protrusion, the protrusion function of the filtering material 5 becomes another inefficient function (the deflection of the material between the protrusions increases, which leads to disruption of the device’s normal operation) . The protrusions 17 provide for the conjugation of the filters and the partitions and separation plates 7 and the formation of cavities 18 and 19 between them for the output 25 and the filtered blood, respectively. The cavities 18 are connected through the recesses 14 to the collector 15 and the inlet 4 by the blood outlet 3. The cavities 19 communicate via recesses 13 to the collector 16 and the outlet A for blood.

The bottom surfaces of the housing 1 and the cover 2 glued into it are made according to

the configurations are similar to the separation plates 7 and mate with the extreme filter plates to form logical cavities for the passage of blood.

The proposed blood microfilter works as follows.

The blood to be filtered flows through the line through the inlet 3 to the collector 15 formed by the recesses 8 and 11. in the filter partitions and separation plates. From the collector 15, through the recesses 14, the blood enters the cavities 18 and, after passing through the filtering material 5 of the filter partitions, enters the cavities 19 located on the other side of the filter partitions, from where it collects in the outlet collector 16 formed by the notches 9 and 12 in the filter partitions and separators plates, and then through the outlet 4 is led out of the device into the outer line.

The arrangement in the body of the filter element, which is a set of parallel filter walls, provides a uniform distribution of blood on the filtering surface with a small filter filling volume, almost three times smaller than a lime microfilter with the same filter surface area.

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Claims (1)

BLOOD MICROFILTER, consisting of a filter element located in the housing, with blood inlet and outlet nozzles, characterized in that, in order to reduce the initial filling volume while maintaining the filtration area, the filter element is a set of parallel filtering partitions, between which are installed dividing plates, each filter baffle has a sealing frame around the perimeter, in which at the interface with the inlet and outlet nozzles diametrically located the recesses are made, and each dividing plate has a flange on both sides with a recess similar in shape and size to the recesses of the frame, the recesses of the flanges of different sides of the plate are diametrically, and two diametrically placed recesses on different sides of the plate with a length equal to the length of the recesses, In this case, each plate has hemispherical protrusions evenly distributed on both sides, the centers of which are spaced one from the other at a distance exceeding the diameter of the protrusions 2–5 times. SU .... 1138169 1 1138169