JP4496232B2 - Transducer filter - Google Patents

Description

  The present invention relates to an improvement in a transducer filter disposed between an extracorporeal circuit used in artificial dialysis, plasma exchange, ascites treatment, and a pressure gauge (pressure regulator) such as a dialysis machine.

  For example, in the transducer filter described in Patent Document 1, an invention is described in which a plurality of protective plates are arranged in a housing collar (support) on the dialyzer side to suppress swelling of the filter. However, in these structures, when a fluid pressure such as air pressure or blood is applied from the extracorporeal circuit side, the filter is excessively loaded, and there is a concern about damage or the like.

  Patent Documents 2 and 3 also describe a filter having a shape similar to that of a transducer filter, but these are liquid filtration filters, in which air pressure flowing from the extracorporeal circuit is directly applied to the filter. There is no mention of protection. Further, since the filter has a structure in which the filter is sandwiched between two housings, a load is applied to the filter, and there is a problem that quality stability is lacking when the structure is used in a transducer filter.

JP 2001-129079 A (FIG. 1, [0004], [0005]) Japanese Patent Laid-Open No. 6-7648 (FIG. 1, summary) Special table hei 9-509361 (Fig. 1)

  The problem to be solved by the present invention is that the inventions of Patent Document 2 and Patent Document 3 have a structure in which a filter is sandwiched between two housings, so that a load is applied to the filter. When used in a filter, quality stability is lacking.

Therefore, as a result of intensive studies to solve the above problems, the present inventor has reached the following invention.
[1] The present invention has a housing (2) on the extracorporeal circuit side and a housing (12) on the dialyzer side,
The extracorporeal circuit side housing (2) and the dialyzer side housing (12) each have a substantially cylindrical support member (2b, 12b) and a connecting portion (2a, 12a),
The support member (2b, 12b) has a longitudinal direction and a side circumferential direction that intersects the longitudinal direction substantially perpendicularly, and the longitudinal direction has a top surface portion and a bottom surface portion,
The connection portion (2a, 12a) has a longitudinal direction and a side circumferential direction that intersects the longitudinal direction substantially perpendicularly, and the longitudinal direction has a top surface portion and a bottom surface portion,
The connecting portions (2a, 12a) project from the bottom surface of the support member (2b, 12b),
An annular protrusion (3) is formed on the top surface of the support part (2b) of the housing (2) on the extracorporeal circuit side, and a welded part (7) is formed on the outer periphery of the protrusion (3). , Forming a protrusion (6) on the top surface of the welded portion (7),
An annular weld portion (17) is formed on the outer edge of the top surface portion of the support portion (12b) of the housing (12) on the dialyzer side, and an annular protrusion (13) is formed on the inner edge of the weld portion (17). Forming an annular small protrusion (8) on the top surface of the protrusion (13),
Place the hydrophobic filter (10) inside the small protrusion (8),
The hydrophobic filter (10) is welded to the inner wall surface of the small protrusion (8) and the portion in contact with the top surface of the protrusion (13),
The top surface portion of the welded portion (17) of the support portion (12b) of the housing (12) on the dialyzer side and the welded portion (7) of the support portion (2b) of the housing (2) on the extracorporeal circuit side are fitted. Together
The protrusion (6) of the welded part (7) of the support part (2b) on the extracorporeal circuit side is melted by ultrasonic waves,
Provided is a transducer filter (1) welded to a welded portion (17) of a housing (12) on the dialyzer side .
[2] In the present invention, the extracorporeal circuit side housing (2) is used as a dialyzer side housing,
The dialysis device side housing (12) provides the transducer filter (1) according to [1], which is used as a housing on the extracorporeal circuit side .

The transducer filter 1 of the present invention is
(1) Since the hydrophobic filter 10 is welded and fixed to one (dialyzer side) housing 12, the load on the hydrophobic filter 10 can be reduced, and the quality (performance) of the hydrophobic filter 10 can be reduced. Can be stabilized.
(2) According to (1), the hydrophobic filter 10 is fixed in a stable shape between the housings 2 and 12, and thus has excellent durability.

1 is a sectional view showing an example of a transducer filter 1 of the present invention, FIG. 2 (a) is a top view of a housing 2, (b) is a side view, (c) is a rear view, and FIG. FIG. 4 is a partially enlarged view of a), FIG. 4 is a partially enlarged sectional view of AOA in FIG. 3, FIG. 5 (a) is a top view of the housing 12, and (b) is a side view. c) is a rear view, FIG. 6 is a partially enlarged view of FIG. 5A, and FIG. 7 is a partially enlarged sectional view of A-O-A of FIG.
The transducer filter 1 of the present invention is composed of two housings 2 and 12 on the extracorporeal circuit side and the dialyzer side, and the housings 2 and 12 include substantially cylindrical support portions 2b and 12b and connection portions 2a and 12a. It is integrally formed.
The support members (2b, 12b) have a longitudinal direction and a side circumferential direction that intersects the longitudinal direction substantially perpendicularly, and the longitudinal direction has a top surface portion and a bottom surface portion.
The connecting portions (2a, 12a) have a longitudinal direction and a side circumferential direction that intersects the longitudinal direction substantially perpendicularly, and the longitudinal direction has a top surface portion and a bottom surface portion.
Connection portions (2a, 12a) project from the bottom surface of the support members (2b, 12b). Connection portions (2a, 12a) are formed on the top surface of the connection portions (2a, 12a).
As illustrated in FIG. 1, a hydrophobic filter 10 is disposed between the two support portions 2 b and 12 of the housing 2 and 12 on the extracorporeal circuit side and the dialyzer side, and FIGS. 2 to 3 and FIGS. As illustrated, the first air pressure buffer members 5 and 15 are formed on the support portions 2b and 12b, and the second air pressure buffer members 5a and 15a are formed on the outer periphery of the first air pressure buffer members 5 and 15. Forming.
In the present invention, the first air pressure buffering member 5 and the second air pressure buffering member 5a may be formed at least on the support portion 2b of the extracorporeal circuit side housing 2.
In the description of the present invention, for convenience, the housing 2 is on the extracorporeal circuit side and the housing 12 is on the dialyzer side, but the housing 2 can also be used as the dialyzer side, and the housing 12 can be used as the extracorporeal circuit side housing.

In the housings 2 and 12, connecting portions 2a and 12a formed in a tapered taper are integrally projected at the bottom center of the supporting portions 2b and 12b. Flow paths 4 and 14 for fluid (air, blood, etc.) are formed from the connection portions 2a and 12a to the inside of the support portions 2b and 12b.
As illustrated in FIGS. 4 and 7, a concave portion 9 is formed on the top surface of the support portions 2b and 12b, and the first pneumatic cushioning members 5 and 15 and the second pneumatic cushioning member 5a are formed in the concave portions 9 and 19 space. , 15a are arranged.
As illustrated in FIGS. 2, 3, 5, and 6, the first pneumatic shock absorbing members 5 and 15 are disposed at substantially the center of the support portions 2 b and 12 b, and the second pneumatic shock absorbing members 5 a and 15 a are It arrange | positions on the outer periphery (it is also called an outer side) so that the 1st pneumatic shock-absorbing members 5 and 15 may be surrounded.

In the illustrations of FIGS. 3, 4, 6, and 7, the first pneumatic cushioning members 5 and 15 are formed in a plate shape (rectangular shape) in a longitudinal section, and are substantially viewed from the top surface direction of the support portions 2 b and 12 b. The four pieces are combined to form a cross shape, but any shape can be used as long as the air pressure can be prevented from directly colliding with the hydrophobic filter 10 and buffered. When viewed from the top surface direction of the support portions 2b and 12b, for example, a circular shape, an annular shape, or a lattice shape may be used.
Further, in the illustration of FIGS. 3, 4, 6, and 7, the second pneumatic shock-absorbing members 5 a and 15 a are formed in a plate shape (rectangular shape) in the longitudinal section, and viewed from the top surface direction of the support portions 2 b and 12 b, The four pieces are arranged radially in the direction of the center O of the support portions 2b and 12b, but any shape can be used as long as the air pressure buffered by the first air pressure buffer members 5 and 15 can be further buffered. For example, it may be annular when viewed from the top surface direction of the support portions 2b and 12b.
In the illustrations of FIGS. 2 to 7, the pieces of the second air pressure buffer members 5a and 15a are alternately arranged between the pieces of the cross-shaped first air pressure buffer members 5 and 15 so as not to overlap each other. Has been.

The air pressure flowing from the extracorporeal circuit side through the flow path 4 directly collides with the surface of the first air pressure buffer member 5 and is dispersed, and the air pressure applied to the hydrophobic filter 10 is weakened. Can reduce the damage.
Even if a liquid such as blood flows from the extracorporeal circuit through the flow path 4, it is directly collided with the surface of the first air pressure buffer member 5 and dispersed, and is applied to the hydrophobic filter 10. Since the applied fluid pressure is weakened, the load on the hydrophobic filter 10 can be lightened to suppress damage.

  Further, the fluid such as air pressure or blood collides directly with the surfaces of the first air pressure buffer members 5 and 15 and then disperses and collides with the second air pressure buffer members 5a and 15a to further weaken it. Therefore, the load on the hydrophobic filter 10 can be further reduced.

In addition, as shown in FIG. 4, the cyclic | annular protrusion 3 is formed in the top | upper surface part (outer edge of 2nd pneumatic shock absorbing member 5a, 15a) of the support part 2b of the housing 2. As shown in FIG. A weld 7 is formed on the outer periphery of the protrusion 3, and a protrusion 6 is formed on the surface (top surface) of the weld 7.
The support portion 12b top surface edge of the housing 12 as illustrated in the other 7, an annular weld portion 17 is formed, on the inner edge of the welded portion 17 (outside of the second pneumatic cushioning member 15a) is An annular protrusion 13 is formed.
Further, an annular small protrusion 8 is formed on the top surface of the protrusion 13. A hydrophobic filter 10 is disposed inside the small protrusion 8. In more detail, the hydrophobic filter 10 to a portion in contact with the top surface portion of the inner wall surface and projections 13 of small projection 8, for example, ultrasonic, contact heater, is welded by a laser or the like.
The above housing 12 is fitted to the protrusion 3 of the support portion 2b on the housing 2 side, and ultrasonically oscillates and welds from the bottom side of the support portion 2b.
The triangular protrusion 6 formed on the welded portion 7 is melted and welded (absorbed) to the welded portion 17 when the support portion 2b and the support portion 12b are fitted and ultrasonically welded.
Since the hydrophobic filter 10 is not sandwiched and fixed between the two housings 2 and 12 but is welded and fixed to one of the housings 12 (dialyzer side), the hydrophobic filter 10 is applied. The load can be reduced, and the quality (performance) of the hydrophobic filter 10 can be stabilized.

The transducer filter 1 of the present invention is preferably formed of a material that can withstand high pressure steam sterilization. For example, the housings 2 and 12 can be made of polypropylene, polycarbonate, or the like, and the hydrophobic filter 10 can be made of polytetrafluoroethylene. Etc. can be adopted.
The hydrophobic filter 10 is formed in the form of a sheet in FIG. 1, but has a structure and material that does not pass liquids (body fluids, blood), microorganisms, suspended dust, etc. of at least 0.2 μm and does not pass gas. Anything is fine.

The transducer filter 1 of the present invention can be attached in advance to the monitor line of the drip chamber of the extracorporeal circuit used in hemodialysis.
When assembling the extracorporeal circuit, the transducer filter 1 is attached and sterilized with high-pressure steam, so that it is not necessary to newly install the transducer filter 1.

Sectional view of the transducer filter 1 of the present invention (A) Top view of housing 2 constituting transducer filter 1, (b) Side view of housing 2, (c) Rear view of housing 2 A partially enlarged view of FIG. Partial cross-sectional enlarged view of A-O-A in FIG. (A) Top view of housing 12 constituting transducer filter 1, (b) side view, (c) rear view of housing 12 A partially enlarged view of FIG. Partial cross-sectional enlarged view of A-O-A in FIG.

Explanation of symbols

1 Transducer filter 2 Housing (external circulation circuit side)
12 Housing (dialysis machine side)
2a, 12a Connecting portion 2b, 12b Support portion 3, 13 Protruding portion 4, 14 Flow path 5, 15 First pneumatic shock absorbing member 5a, 15a Second pneumatic shock absorbing member 6 Protrusion 7, 17 Welding portion 8 Small protrusion 9, 19 Recess 10 Hydrophobic filter O Center

Claims (2)

A housing (2) on the extracorporeal circuit side, and a housing (12) on the dialyzer side,
The extracorporeal circuit side housing (2) and the dialyzer side housing (12) each have a substantially cylindrical support member (2b, 12b) and a connecting portion (2a, 12a),
The support member (2b, 12b) has a longitudinal direction and a side circumferential direction that intersects the longitudinal direction substantially perpendicularly, and the longitudinal direction has a top surface portion and a bottom surface portion,
The connection portion (2a, 12a) has a longitudinal direction and a side circumferential direction that intersects the longitudinal direction substantially perpendicularly, and the longitudinal direction has a top surface portion and a bottom surface portion,
The connecting portions (2a, 12a) project from the bottom surface of the support member (2b, 12b),
An annular protrusion (3) is formed on the top surface of the support part (2b) of the housing (2) on the extracorporeal circuit side, and a welded part (7) is formed on the outer periphery of the protrusion (3). , Forming a protrusion (6) on the top surface of the welded portion (7),
An annular welded portion (17) is formed on the outer edge of the top surface of the support portion (12b) of the housing (12) on the dialyzer side, and an annular protrusion (13) is formed on the inner edge of the welded portion (17). Forming an annular small protrusion (8) on the top surface of the protrusion (13),
Place the hydrophobic filter (10) inside the small protrusion (8),
The hydrophobic filter (10) is welded to the inner wall surface of the small protrusion (8) and the portion in contact with the top surface of the protrusion (13),
The top surface portion of the welded portion (17) of the support portion (12b) of the housing (12) on the dialyzer side and the welded portion (7) of the support portion (2b) of the housing (2) on the extracorporeal circuit side are fitted. Together
The protrusion (6) of the welded part (7) of the support part (2b) on the extracorporeal circuit side is melted by ultrasonic waves,
A transducer filter (1), which is welded to a welded portion (17) of a housing (12) on the dialyzer side. The extracorporeal circuit side housing (2) is used as a dialyzer side housing,
The transducer filter (1) according to claim 1, wherein the housing (12) on the dialyzer side is used as a housing on the extracorporeal circuit side.

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