JP2021007609A - Dialysis coupler connector and dialysis drug solution supply apparatus - Google Patents

Abstract

To provide a dialysis coupler connector capable of cleaning and disinfecting flow channels through which clean water and dialysate pass in a dialysate supply device and a dialysis monitoring device, without having to transfer a drug solution into a tank, thus eliminating the need for installing the tank.SOLUTION: The dialysis coupler connector includes: a dialysis coupler connector main body 50; a first connection portion 51 connectable to a pouring port 32 of a bag-in box 3 provided at one end of the dialysis coupler connector main body 50; and a second connection portion 52 connectable to a dialysis coupler 4 provided at the other end of the dialysis coupler connector main body 50.SELECTED DRAWING: Figure 2

Description

The present invention relates to a dialysis coupler connector and a dialysis drug solution supply device.

In general, in the central dialysate supply system, a dialysate supply device is installed in a machine room in a medical field such as a hospital, and a dialysis monitoring device is installed in a dialysis room (treatment room), which is a different location. , These dialysate supply devices and dialysis monitoring devices are connected by pipes. The dialysate supply device is for preparing a dialysate having a predetermined concentration by supplying clean water, and the dialysis monitoring device corresponds to the number of blood purifiers (dialyzers) for performing dialysis treatment on the patient. A plurality of dialysates installed and prepared by a dialysate supply device are introduced through a pipe and supplied to a blood purifier.

That is, it is configured to distribute the dialysate from one dialysate supply device installed in the machine room to a plurality of dialysis monitoring devices installed in the dialysis room, send the dialysate, and supply the dialysate to the dialyzer in each of them. Is what you are doing. The system that distributes the dialysate prepared in the center to each dialysis monitoring device is usually referred to as a "central dialysate supply system". Incidentally, a device capable of preparing and supplying dialysate for each blood purifier (that is, each dialysis treatment patient) is called a personal dialysis device.

By the way, it is necessary to clean and disinfect the flow path through which clean water and dialysate flow in the dialysate supply device and the dialysis monitoring device from the viewpoint of maintaining hygiene. As a chemical solution, for example, sodium hypochlorite. And cleaning agents such as acetic acid are used. Then, in order to disinfect after washing with washing water, a chemical solution is supplied to the dialysate supply device, and the solution is allowed to flow from the dialysate supply device to the dialysis monitoring device via a pipe (). For example, see Patent Document 1).

That is, by distributing the chemical solution along the distribution path of clean water or dialysate in the dialysate supply device, the monitoring device for dialysis, and the piping connecting them, the distribution path of the dialysate or the like is disinfected in the distribution process. Therefore, it is disinfected over the entire flow path of clean water and dialysate.

Japanese Unexamined Patent Publication No. 2003-260131

By the way, in order to supply the above-mentioned chemical solution to the dialysate supply device, it is necessary to supply the chemical solution into the tank provided in the dialysate supply device. That is, it is necessary to manually transfer the chemical solution from the back-in box in which the chemical solution such as sodium hypochlorite or acetic acid is stored into the tank to supply the chemical solution into the tank.

However, there are the following problems in carrying out such transfer work.

That is, most of the back-in boxes containing chemicals such as sodium hypochlorite and acetic acid weigh 10 kg or more, and there is a problem that the transfer work requires a great deal of labor and labor.

Further, there is a problem that the chemical solution may jump and adhere to the worker during the transfer work.

On the other hand, since the tank provided in the dialysate supply device is made of a resin material such as polypropylene, it deteriorates when it is exposed to an oxidizing chemical solution such as sodium hypochlorite for a long time, and therefore, the tank is regularly inspected. And there was a problem that regular replacement was necessary.

In addition, if the transfer work into the tank is mistakenly performed, there is a problem that sodium hypochlorite and acetic acid are mixed to generate toxic chlorine gas. In addition, although the name of the chemical solution to be transferred is written on the tank, mistakes often occur because it is a human work, and cases are reported several times a year.

On the other hand, since the tank is not sealed and has gaps such as air holes, there is a problem that the odor of acetic acid fills the room and creates an unpleasant environment in the tank to which acetic acid is supplied.

Furthermore, the tank has no countermeasures against an earthquake, and there is a problem that the tank may collapse and the chemical solution in the tank may leak out when an earthquake occurs. If the chemical solution in the tank leaks out, there is a problem that sodium hypochlorite and acetic acid are mixed to generate toxic chlorine gas.

On the other hand, in recent years, since the dilution ratio on the dialysate supply device side can be set arbitrarily, the original role of the tank has disappeared. Therefore, there is a problem that the tank itself is becoming unnecessary. That is, as a background to the transfer work to the tank as described above, since the dilution ratio setting of the dialysate supply system was fixed at a low concentration, in order to supply the dialysate at the target concentration. Had to mix RO water and chemicals in a tank for primary dilution. For example, if the dialysate supply system was fixed at a 30-fold dilution, and the dialysis line wanted to be 300-fold, RO water and the drug solution had to be diluted 10-fold in the tank. However, in recent years, since the dilution ratio on the dialysate supply device side can be arbitrarily set, it is no longer necessary to perform the primary dilution as described above, and thus the tank itself is no longer necessary. There was a problem.

Therefore, in view of the above problems, the present invention is a flow path through which clean water and dialysate flow in the dialysate supply device and the dialysis monitoring device without the need for a tank and without performing the work of transferring the chemical solution into the tank. It is an object of the present invention to provide a dialysis coupler connector and a dialysis drug solution supply device capable of cleaning and disinfecting.

The above object of the present invention is achieved by the following means. The reference numerals of the embodiments described later are added in parentheses, but the present invention is not limited thereto.

According to the dialysis coupler connector of claim 1, the dialysis coupler connector main body (50) and
A first connection portion (51) that can be connected to an inlet (32) of a box body (back-in box 3, tough tener) provided at one end of the dialysis coupler connector main body (50).
It is characterized by having a second connection portion (52) that can be connected to the dialysis coupler (4) provided at the other end of the dialysis coupler connector main body (50).

Further, according to the dialysis drug solution supply device of claim 2, the rack (2,2A, 2B) having shelves (21, upper shelves 24A1, 24C, lower shelves 24A2, 25C) provided in multiple stages in the vertical direction is used. ,
Box bodies (back-in box 3, tough tenor) placed on the shelves (21, upper shelves 24A1, 24C, lower shelves 24A2, 25C) of the racks (2,2A, 2B), respectively.
The dialysis coupler connector according to claim 1, wherein the first connection portion (51) according to claim 1 is connected to an inlet (32) of the box body (back-in box 3, tough tenor). (5) and
The dialysis coupler (4) connected to the second connection portion (52) of the dialysis coupler connector (5),
It has a tube (6a, 6b) connected to the dialysis coupler (4), and has.
The tubes (6a, 6b) are characterized in that they are coupled and connected to a dialysate supply device.

Next, the effects of the present invention will be described with reference to the drawings. The reference numerals of the embodiments described later are added in parentheses, but the present invention is not limited thereto.

According to the invention of claim 1, the spout (32) of the box body (back-in box 3, tough tenor) and the dialysis coupler (4) are connected by using the dialysis coupler connector (5). As a result, clean water and dialysis in the dialysate supply device and the dialysis monitoring device do not require the work of transferring the chemical solution stored in the box body (back-in box 3, tough tenor) into the tank as in the conventional case. It is possible to perform cleaning and disinfection of the flow path through which the liquid flows. Further, by using the box body (back-in box 3, tough tenor), the tank becomes unnecessary.

Further, according to the configuration as in the invention of claim 2, the chemical solution stored in the box body (back-in box 3, tough tenor) is supplied to the dialysate supply device through the tubes (6a, 6b). Therefore, it is necessary to clean and disinfect the flow path through which clean water and dialysate flow in the dialysate supply device and the dialysis monitoring device without performing the work of transferring them into the tank as in the past. You will be able to do it. Further, by using the box body (back-in box 3, tough tenor), the tank becomes unnecessary.

It is a perspective view of the dialysis drug solution supply device which concerns on one Embodiment of this invention. It is an exploded perspective view which shows the state which tries to connect the spout of a back-in box, and the dialysis coupler by using the dialysis coupler connector which concerns on this embodiment. It is sectional drawing which shows the state which it is connected to the spout of a back-in box, and the dialysis coupler by using the dialysis coupler connector which concerns on this embodiment. A rack different from the rack according to the same embodiment is shown, (a) is a perspective view, (b) is a front view, and (c) is a side view. The rack according to the same embodiment and a rack different from the rack shown in FIG. 4 are shown, (a) is a perspective view, (b) is a front view, and (c) is a side view. The rack according to the same embodiment and a rack different from the racks shown in FIGS. 4 and 5 are shown, (a) is a perspective view, (b) is a front view, and (c) is a side view.

Hereinafter, an embodiment of the dialysis coupler connector and the dialysis drug solution supply device according to the present invention will be specifically described with reference to the drawings. In the following description, when the directions of up, down, left, and right are shown, it means the up, down, left, and right when viewed from the front of the illustration.

As shown in FIG. 1, the dialysis drug solution supply device 1 includes a rack 2, a back-in box 3, a dialysis coupler 4, and a dialysis coupler connector 5 for connecting the back-in box 3 and the dialysis coupler 4. , Is mainly composed of.

The rack 2 is made of metal, and as shown in FIG. 1, a pair of front and rear columns 20, a substantially rectangular shelf 21 that connects the pair of front and rear columns 20 to each other, and an upper side provided at four corners of the shelf 21. It is mainly composed of a cylindrical fitting portion 22 whose diameter is reduced toward the end. As shown in FIG. 1, the pair of front and rear columns 20 are formed of a cylindrical metal pipe and are erected so as to be located at the four corners of the shelf 21. The columns 20 are set to external dimensions so that the fitting portions 22 provided at the four corners of the shelf 21 can be loosely fitted.

On the other hand, as shown in FIG. 1, the shelf 21 includes a shelf surface portion 21a formed by assembling a plurality of metal wires in a grid pattern, and the shelf surface portion 21a is formed in a horizontally long rectangular shape. On the four sides of the shelf surface portion 21a, side surface portions 21b are formed by metal wires to reinforce the shelf 21.

On the other hand, as shown in FIG. 1, fitting portions 22 formed of metal cylindrical members are provided at the four corners of the shelf 21 formed as described above, and the fitting portions 22 are provided on the side surfaces. It is fixed to the portion 21b by welding or the like.

Thus, the shelf 21 formed as described above can be fixed at a predetermined position of the support column 20 by inserting the fitting portion 22 into the pair of front and rear columns 20. As a result, as shown in FIG. 1, shelves 21 are predeterminedly arranged at the lower and intermediate portions of the pair of front and rear columns 20, and the rack has shelves 21 provided in multiple stages (two stages in the drawing) in the vertical direction. 2 will be formed.

The back-in box 3 contains a chemical solution such as sodium hypochlorite or acetic acid, and is composed of a rectangular parallelepiped or cubic box 30 as shown in FIG. The box 30 has the rigidity required for transportation and storage, and is usually made of inexpensive corrugated cardboard.

Further, in the box 30, a bag 31 (see FIG. 3) containing a chemical solution such as sodium hypochlorite or acetic acid is stored. The bag 31 maintains the quality of chemicals such as sodium hypochlorite and acetic acid, and at the same time, has water resistance, chemical resistance, gas barrier property, etc. so that the bag itself is not deteriorated by chemicals such as sodium hypochlorite and acetic acid. It is a bag of plastic film having a capacity of about 20 liters. Thus, such a bag 31 is provided with a spout 32 as shown in FIGS. 2 and 3. As shown in FIGS. 2 and 3, the pouring outlet 32 is a cylindrical pouring cylinder 32a capable of pouring a chemical solution such as sodium hypochlorite or acetic acid to the outside, and a pouring cylinder 32a. A circular first flange portion 32b protruding integrally from the lower portion, a circular second flange portion 32c having a diameter larger than the inner diameter of the first flange portion 32b and having the same outer diameter, and a first flange portion 32b. It is composed of a rib 32d that communicates with the second flange portion 32c. A screw portion 32a1 is provided on the outer circumference of the dispensing cylinder 32a, and a bag 31 is heat-welded to the second flange portion 32c. Then, the box 30 is attached in contact with the lower surface of the first flange portion 32b so that the dispensing cylinder 32a and the first flange portion 32b protrude from the box 30. The dialysis coupler connector 5 is connected to the screw portion 32a1. This point will be described later.

Thus, in this way, the bag 31 (see FIG. 3) containing the chemicals such as sodium hypochlorite and acetic acid is stored in the box 30, and the back-in box 3 is next. It will be able to store chemicals such as sodium hypochlorite and acetic acid.

The dialysis coupler 4 has a dialysis coupler body 40 as shown in FIGS. 2 and 3. A fitting portion 41 into which the dialysis coupler connector 5 can be fitted is integrally formed at one end (left side in the drawing) of the dialysis coupler main body 40. Then, as shown in FIG. 3, the dialysis coupler main body 40 is formed with a hollow portion 42 communicating with the inside of the dialysis coupler connector 5, and the dialysis coupler main body 40 is formed with a tubular tube connecting portion 43. Is integrally formed in a laterally protruding shape, and the inside thereof communicates with the cavity 42. Further, in the dialysis coupler main body 40, an O-ring 44 for fitting the dialysis coupler connector 5 and the fitting portion 41 in a liquid-tight state is provided, and the dialysis coupler connector 5 is fitted with the dialysis coupler. A fixing mechanism 45 for releasably fixing to the main body 40 is provided. As shown in FIG. 3, the fixing mechanism 45 includes a plurality of locking balls 45a, a sleeve 45b for locking the locking balls 45a, a coil spring 45c for elastically holding the sleeve 45b, and a sleeve 45b. It is composed of a stopper 45d for locking the stopper in a predetermined position.

The dialysis coupler connector 5, which is a feature of the present invention, is made of a fluorine-based resin such as polypropylene, polyethylene, Teflon (registered trademark), which is resistant to oxidizing agents, and the like, and FIG. As shown in the above, the convex dialysis coupler connector body 50 is provided. A circular first connecting portion 51 is provided at one end (left side in the drawing) of the dialysis coupler connector main body 50, and a substantially cylindrical second connecting portion 52 is provided at the other end (right side in the drawing). It is provided. As shown in FIG. 3, the first connecting portion 51 is formed in a tubular shape in which the upper surface 51a is closed and the bottom surface 51b is open, so that the inner diameter is the same as the outer diameter of the dispensing cylinder 32a. Is formed in. Further, on the inner wall of the first connecting portion 51 on the bottom surface 51b side, a female screw portion 51c that can be screwed with the screw portion 32a1 provided on the outer circumference of the dispensing cylinder 32a is provided. As a result, as shown in FIG. 3, the female threaded portion 51c of the first connecting portion 51 is screwed into the threaded portion 32a1 provided on the outer circumference of the pouring cylinder 32a, and thus the spout 32 of the back-in box 3 The first connection portion 51 of the dialysis coupler connector 5 is connected to the dialysis coupler connector 5. As shown in FIG. 2, a plurality of first connecting portions 51 are provided on the outer periphery of the first connecting portion 51 from the upper surface 51a to the bottom surface 51b at predetermined intervals in a direction orthogonal to the circumferential direction. Grooves 51d are arranged in parallel. The plurality of grooves 51d are non-slip, and the first connection portion 51 can be easily connected to the spout 32 of the back-in box 3.

When the first connection portion 51 of the dialysis coupler connector 5 is connected to the injection port 32 of the back-in box 3, the first connection is made as shown in FIG. 3 so that the connection can be made in a liquid-tight state. An O-ring 51e is provided on the inner wall of the upper surface 51a of the portion 51.

On the other hand, as shown in FIGS. 2 and 3, the second connecting portion 52 is formed in a tubular shape in which the upper surface 52a and the bottom surface 52b integrally project from the center of the upper surface 51a of the first connecting portion 51 are opened. The outer diameter is formed to be the same as the inner diameter of the fitting portion 41 of the dialysis coupler 4. Further, a first concave step portion 52c that is closely fitted to the O-ring 44 is formed on the outer peripheral upper surface 51a side of the second connecting portion 52, and a lock is formed on the outer peripheral central side of the second connecting portion 52. A second concave step portion 52d that is closely fitted with the ball 45a is formed. However, when fitting the second connecting portion 52 to the fitting portion 41 of the dialysis coupler 4, the sleeve 45b is retracted against the elasticity of the coil spring 45c (see the broken line shown in FIG. 3). As a result, the locked state of the locking ball 45a is released (see the broken line shown in FIG. 3), and the second connecting portion 52 is allowed to be inserted. Then, in this state, if the second connecting portion 52 is fitted and inserted into the fitting portion 41 of the dialysis coupler 4, as shown in FIG. 3, the second connecting portion 52 is inserted into the end surface 41a of the fitting portion 41 of the dialysis coupler 4. The upper surface 52a of the two connecting portions 52 is brought into close contact with each other, and the O-ring 44 is closely fitted to the first concave step portion 52c of the second connecting portion 52. Then, when the sleeve 45b is released in this state, the sleeve 45b moves to the position of the stopper 45d due to the elasticity of the coil spring 45c, so that the locking ball 45a is closely fitted to the second concave step portion 52d of the second connecting portion 52. If so, it will return to the locked state. As a result, the second connecting portion 52 of the dialysis coupler connector 5 is fitted to the fitting portion 41 of the dialysis coupler 4.

By using such a dialysis coupler connector 5, the spout 32 of the back-in box 3 and the dialysis coupler 4 can be easily and easily connected to each other via the dialysis coupler connector 5. As a result, as shown in FIG. 3, the inside of the inlet 32 of the back-in box 3, the inside of the dialysis coupler connector 5, and the inside of the dialysis coupler 4 can communicate with each other.

Thus, the dialysis drug solution supply device 1 configured as described above is used as follows.

That is, as shown in FIG. 1, the back-in box 3 is placed on each of the shelves 21 of the rack 2. The inlet 32 of the back-in box 3 and the dialysis coupler 4 are connected to each other via the dialysis coupler connector 5. Further, tubular tubes 6a and 6b made of silicon resin or the like are connected to the tube connection portion 43 of the dialysis coupler 4, respectively, and the tubes 6a and 6b are formed of polyethylene resin or the like. It is connected by a T-shaped tube 7a. A tubular tube 6c made of silicon resin or the like is connected to the T-shaped tube 7a, and the tube 6c is made of silicon resin or the like via a T-shaped tube 7b made of polyethylene resin or the like. It is connected to a tubular tube 6d to be formed. The tube 6d is connected to a dialysate supply device (not shown). The back-in box 3 contains chemicals such as sodium hypochlorite and acetic acid, and the chemicals containing the back-in boxes 3 placed on the shelves 21 of the rack 2 are stored. The same chemical solution is stored as. This is because if different chemical solutions are stored, the tube 6a and the tube 6b are connected by the T-shaped tube 7a, so that toxic chlorine gas may be generated.

By doing so, since the spout 32 of the back-in box 3 and the dialysis coupler 4 are connected via the dialysis coupler connector 5, the back-in box is as shown in FIG. The inside of the spout 32 of No. 3, the inside of the dialysis coupler connector 5, and the inside of the dialysis coupler 4 communicate with each other, and as shown in FIG. 1, the chemical solution passes through the tube 6a with the arrow Y1. It is supplied in the direction, and the chemical solution is supplied in the direction of arrow Y2 through the tube 6b. Further, this chemical solution is supplied in the direction of arrow Y3 through the tube 6c and the tube 6d, and is therefore supplied to a dialysate supply device (not shown). As a result, the chemical solution used for cleaning and disinfecting can be supplied to a dialysate supply device (not shown).

Therefore, according to the configuration of the present embodiment described above, the dialysate supply device and the dialysate can be used without the work of transferring the chemical solution stored in the back-in box 3 into the tank as in the conventional case. It is possible to clean and disinfect the flow path through which clean water and dialysate flow in the monitoring device. That is, by connecting the spout 32 of the back-in box 3 and the dialysis coupler 4 using the dialysis coupler connector 5, the chemical solution stored in the back-in box 3 can be removed as in the conventional case. It is possible to clean and disinfect the flow path through which the clean water and the dialysate flow in the dialysate supply device and the dialysis monitoring device without performing the work of transferring them into the tank. Further, by using the back-in box 3, the tank becomes unnecessary. The amount of the chemical solution is reduced from the amount of the chemical solution stored in the back-in box 3 placed on the upper shelf 21 due to the influence of its own weight. Then, when the chemical solution stored in the back-in box 3 placed on the upper shelf 21 runs out, the chemical solution stored in the back-in box 3 placed on the lower shelf 21 is supplied. It will be. Therefore, the back-in box 3 placed on the lower shelf 21 serves as a reserve.

By the way, as shown in FIG. 1, a tubular tube 6e made of silicon resin or the like is connected to the T-shaped tube 7b, and the tube 6e is erected along a support column 20 located on the left side in front of the drawing. , A pair of holes are attached to the support column 20 by a thick plate circular fixing tool 8 penetrating in the vertical direction. The tube 6e serves as a fuel gauge for knowing the remaining amount of the chemical solution stored in the back-in box 3. That is, when the drug solution is supplied to a dialysate supply device (not shown), the drug solution is supplied in the direction of arrow Y3 through the tubes 6c and 6d, but the drug solution is supplied to the dialysate supply device (not shown). If is not supplied, the chemical solution is not supplied in the direction of arrow Y3, so that the chemical solution that has lost its place moves through the tube 6e in the direction of arrow Y4. Therefore, as the remaining amount of the chemical solution stored in the back-in box 3 decreases, the amount of the chemical solution moving in the direction of arrow Y4 also decreases when the chemical solution is not supplied to the dialysate supply device (not shown). Although it is not accurate, it is possible to know the remaining amount of the chemical solution stored in the back-in box 3 to some extent. Therefore, as shown in FIG. 1, if the line 6e1 is drawn at a predetermined position on the tube 6e, and the chemical solution does not move to a position beyond the line 6e1, it is time to replace the back-in box 3. It will be easy to understand.

The shape and the like shown in the present embodiment are merely examples, and various modifications and changes can be made within the scope of the gist of the present invention described in the claims. For example, the dialysis coupler 4 has shown an example in which there are an O-ring 44 and a plurality of locking balls 45a, but the present invention is not limited to this, and a dialysis coupler without an O-ring 44 or a plurality of locking balls 45a may be used. .. If the shape of the dialysis coupler without the O-ring 44 or the plurality of locking balls 45a is different from the shape of the dialysis coupler 4, the dialysis coupler without the O-ring 44 or the plurality of locking balls 45a is used for dialysis. The shape of the second connection portion 52 of the dialysis coupler connector 5 may be appropriately changed so that the second connection portion 52 of the coupler connector 5 can be connected. The shape of the second connection portion 52 of the dialysis coupler connector 5 preferably conforms to the dialysis JIS standard 3250: 2013 so as to match the dialysis coupler provided by each dialysis maker.

Further, the shape of the rack 2 is not limited to the rack as shown in FIG. 1, and may be a rack as shown in FIGS. 4 to 6.

That is, the rack 2A as shown in FIG. 4 is made of metal, and as shown in FIG. 4A, a pair of front and rear columns 20A are erected and fixed. As shown in FIG. 4A, a U-shaped frame body 21A is attached to the upper portion of the pair of front and rear columns 20A. A thick rectangular mounting plate 22A on which a weight scale H made of a health meter or the like can be mounted is attached to the lower portion of the pair of front and rear columns 20A. Legs 23A are attached to the lower ends of the pair of front and rear columns 20A.

On the other hand, as shown in FIG. 4, the pair of front and rear columns 20A are provided with a shelf body 24A that is slidably connected in the vertical direction. The shelf body 24A is formed of a plurality of metal wires, and is composed of an upper shelf 24A1, a lower shelf 24A2, and a connecting portion 24A3 that connects the upper shelf 24A1 and the lower shelf 24A2. As shown in FIGS. 4A and 4C, the upper shelf 24A1 has a shelf surface portion 24A1a formed in a grid pattern inclined to the front side and the shelf surface portion 24A1a as shown in FIG. 4A. A side surface portion 24A1b formed so as to surround three sides excluding the rear surface, and a front view M-shaped mounting shelf surface portion 24A1c provided on the upper portion of the shelf surface portion 24A1a as shown in FIG. 4 (b). And, it is composed of. Then, as shown in FIG. 4, the back-in box 3 is mounted on the mounting shelf surface portion 24A1c. As a result, the back-in box 3 is placed so as to be inclined forward, so that the chemical solution can be smoothly supplied.

On the other hand, the lower shelf 24A2 has a shelf surface portion 24A2a in which a plurality of mounting portions 24A2a1 formed in a horizontally long elliptical shape are formed, and as shown in FIG. 4A, three sides excluding the front surface of the shelf surface portion 24A2a. It is composed of a side surface portion 24A2b formed so as to surround the surface portion 24A2b. Then, as shown in FIG. 4, the back-in box 3 is placed on the shelf surface portion 24A2a.

Thus, the upper shelf 24A1 and the lower shelf 24A2 formed in this way are formed of a linear metal wire on the left and right side portions of the side surface portion 24A1b of the upper shelf 24A1 and the left and right side portions of the side surface portion 24A2b of the lower shelf 24A2. It will be connected by the connecting portion 24A3. As a result, the shelf body 24A is formed.

Therefore, even with such a rack 2A shape, the back-in box 3 can be placed in multiple stages, so that the chemical solution stored in the back-in box 3 can be tanked as in the conventional case. It is possible to clean and disinfect the flow path through which the clean water and the dialysate flow in the dialysate supply device and the dialysis monitoring device without performing the work of transferring the solution to the inside. Further, by using the back-in box 3, the tank becomes unnecessary.

By the way, the reason why the shelf body 24A is slidably connected to the pair of front and rear columns 20A in the vertical direction is as follows. That is, when the shelf body 24A is connected to the pair of front and rear columns 20A and the back-in box 3 is placed on the upper shelf 24A1 and the lower shelf 24A2, the weight of the shelf body 24A and the mounting on the upper shelf 24A1 and the lower shelf 24A2 are placed. The weight of the back-in box 3 is applied to the weight scale H mounted on the mounting plate 22A. Therefore, the weight before the chemical solution is supplied can be measured with the weigh scale H. Then, as the chemical solution is supplied, the weight is reduced by the amount of the chemical solution supplied. Therefore, if the difference between the weight before the chemical solution is supplied and the weight after the chemical solution is supplied is taken, the chemical solution is obtained. Will know the weight supplied. However, in this way, the remaining amount of the chemical solution can be accurately known. Therefore, the shelf body 24A is connected to the pair of front and rear columns 20A so as to be slidable in the vertical direction.

On the other hand, the rack 2B as shown in FIG. 5 is the same as the rack 2A shown in FIG. 4 except that the mounting shelf surface portion 24A1c of the rack 2A shown in FIG. 4 is not provided. Therefore, the same reference numerals are given to FIG. 5, and the description thereof will be omitted. The back-in box 3 is mounted on the shelf surface portion 24A1a on the upper shelf 24A1 of the rack 2B as shown in FIG.

Therefore, even with such a rack 2B shape, the back-in box 3 can be placed in multiple stages, so that the chemical solution stored in the back-in box 3 can be tanked as in the conventional case. It is possible to clean and disinfect the flow path through which the clean water and the dialysate flow in the dialysate supply device and the dialysis monitoring device without performing the work of transferring the solution to the inside. Further, by using the back-in box 3, the tank becomes unnecessary.

On the other hand, the rack 2C as shown in FIG. 6 is made of metal, and as shown in FIG. 6A, a pair of front and rear columns 20C are erected and fixed. As shown in FIG. 6A, a U-shaped frame body 21C is attached to the intermediate portion of the pair of front and rear columns 20C. Legs 23C are attached to the lower ends of the pair of front and rear columns 20C.

On the other hand, as shown in FIG. 6, the pair of front and rear columns 20C are provided with upper shelves 24C that are slidably connected in the vertical direction. As shown in FIGS. 6A and 6C, the upper shelf 24C has a shelf surface portion 24Ca formed in a grid pattern inclined to the front side and the shelf surface portion 24Ca as shown in FIG. 6A. It is composed of a side surface portion 24Cb formed upright in front of and behind the surface, and a connecting portion 24Cc connecting the side surface portions 24Cb (see also FIG. 6C). Then, as shown in FIG. 6, the back-in box 3 is placed on the shelf surface portion 24Ca. As a result, the back-in box 3 is placed so as to be inclined forward, so that the chemical solution can be smoothly supplied.

On the other hand, as shown in FIG. 6, a lower shelf 25C is provided below the pair of front and rear columns 20C. The lower shelf 25C has a thick plate rectangular mounting plate 25Ca, caster portions 25Cb provided at the lower corners of the mounting plate 25Ca, and a U-shape provided at the front portion of the mounting plate 25Ca. It is composed of a handle portion of 25 Cc. Thus, the lower shelf 25C formed in this way can be moved in the front-rear direction (see the arrow Y10 direction, the solid line portion and the broken line portion) by using the handle portion 25Cc. The back-in box 3 will be mounted on the mounting plate 25Ca.

Thus, when the rack 2C as described above is used and the chemical solution stored in the back-in box 3 placed on the upper shelf 24C runs out, the lower shelf 25C on which the back-in box 3 is placed is placed in front. The back-in box 3 is placed on the upper shelf 24C by moving in the direction. After that, if a new back-in box 3 is placed on the lower shelf 25C and returned to its original state, the state as shown in FIG. 6 is obtained. As a result, the back-in box 3 can be easily and easily replaced.

Therefore, even with such a rack 2C shape, the back-in box 3 can be placed in multiple stages, so that the chemical solution stored in the back-in box 3 can be tanked as in the conventional case. It is possible to clean and disinfect the flow path through which the clean water and the dialysate flow in the dialysate supply device and the dialysis monitoring device without performing the work of transferring the solution to the inside. Further, by using the back-in box 3, the tank becomes unnecessary.

By the way, using such racks 2, 2A, 2B, and 2C, one unit mounts the back-in box 3 in which the acid-based chemical solution is stored, and the other unit stores the alkaline-based chemical solution. When the back-in box 3 is placed, if both back-in boxes 3 are used, there is a possibility that the connection to the dialysate supply device (not shown) is erroneously made. Therefore, one unit stores the acid-based chemical solution in a tough tener having a larger discharge diameter than the back-in box 3, and the other unit stores the alkaline-based chemical solution in the back-in box 3. , It may be possible to prevent a connection error to a dialysate supply device (not shown). On the other hand, the colors of the dialysis coupler 4 may be different. For example, a red dialysis coupler 4 is used for the back-in box 3 containing an acid-based chemical solution, and a blue dialysis coupler 4 is used for the back-in box 3 containing an alkaline chemical solution. It may be possible to prevent an error in connection to a dialysate supply device (not shown).

On the other hand, the dialysate supply device (not shown) may have a height limitation such that the liquid level of the chemical solution must be set to 80 cm or less from the floor. Therefore, it is preferable to design the racks 2, 2A, 2B, and 2C described above in order to cope with such height restrictions.

In this embodiment, an example in which the back-in box 3 is placed on the racks 2, 2A, 2B, and 2C is shown, but the present invention is not limited to this, and if the rack itself is unnecessary, the back-in box 3 can be arranged in multiple stages. You can just stack them up. However, considering the replacement work of the back-in box 3, it is preferable to mount the back-in box 3 on the racks 2, 2A, 2B, and 2C.

1 Dialysis chemical supply device 2, 2A, 2B, 2C Rack 3 Back-in box 4 Dialysis coupler 5 Dialysis coupler connector 6a, 6b, 6c, 6d, 6e Tube 21 Shelf 24A 1,24C Upper shelf (shelf)
24A2,25C Lower shelf (shelf)
32 Outlet 50 Dialysis coupler connector body 51 1st connection 52 2nd connection

Claims (2)

The main body of the coupler connector for dialysis and
A first connection portion that can be connected to a spout of a box body provided at one end of the dialysis coupler connector body, and a first connection portion.
A dialysis coupler connector comprising a second connection portion that can be connected to a dialysis coupler provided at the other end of the dialysis coupler connector body. A rack with shelves provided in multiple stages in the vertical direction,
The boxes placed on the shelves of the rack and the boxes
The dialysis coupler connector according to claim 1, wherein the first connection portion according to claim 1 is connected to the spout of the box body.
A dialysis coupler connected to the second connection portion of the dialysis coupler connector,
With a tube connected to the dialysis coupler,
The tube is a dialysis drug solution supply device that is coupled and connected to the dialysate supply device.

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