JP6179213B2 - Blood purification system control program, blood purification system control device, blood purification system control method, and blood purification system - Google Patents

Description

  The present disclosure relates to control of a blood purification system including a plurality of blood purification devices for blood purification treatment.

  Conventionally, a blood purification system including a plurality of blood purification apparatuses has been proposed. Such a blood purification system, for example, as disclosed in Japanese Patent Application Laid-Open No. 2009-56271 (Patent Document 1), supplies A stock solution tank and B stock solution tank for supplying dialysate, and clean water. RO (Reverse Osmosis) device. The A stock solution tank is a tank for storing A stock solution containing sodium chloride, potassium chloride, calcium chloride, magnesium chloride, anhydrous sodium acetate, glucose and the like. The B stock solution tank is a tank for storing the B stock solution containing sodium hydrogencarbonate and the like. Each blood purification device supplies and generates dialysate by diluting the solutions stored in the A stock solution tank and the B stock solution tank with clean water supplied from the RO device.

  In Patent Document 1, a method for cleaning various tanks of the system and a line through which a solution passes is examined. For example, as an example of a cleaning method for the line, a method has been proposed in which the A stock solution tank and the B stock solution tank are emptied, and clean water is directly supplied to these to clean the line together with both tanks.

JP 2009-56271 A

  For reasons such as avoiding the accumulation of components in the dialysate, cleaning of each blood purification device needs to be started as soon as possible after the blood purification treatment is completed. On the other hand, the start timing of cleaning of tanks and lines commonly used by a plurality of blood purification devices cannot be determined only by the end timing of blood purification treatment in each blood purification device. However, no specific control content has been proposed in the case where the cleaning of the entire blood purification system is started at an early stage so as to be completed at an early stage.

  The present disclosure has been devised in view of such circumstances, and an object thereof is to enable early cleaning of the entire blood purification system including a plurality of blood purification apparatuses.

  According to an aspect of the present disclosure, a control program for a blood purification system is provided that is executed by a computer for controlling the blood purification system. The blood purification system includes a plurality of blood purification devices for blood purification treatment, a clean water supply device for supplying clean water to each blood purification device, and a solution supply for supplying dialysate to each blood purification device The apparatus includes a first pipe connecting the clean water supply apparatus and each blood purification apparatus, and a second pipe connecting the solution supply apparatus and each blood purification apparatus. The control program detects completion of all cleaning of the plurality of blood purification devices based on a signal indicating completion of cleaning transmitted from each blood purification device to the computer, and all of the plurality of blood purification devices. In response to detecting the completion of the cleaning, a process for cleaning the blood purification system for cleaning the clean water supply device, the solution supply device, the first tube and the second tube is executed.

  Preferably, in the processing for cleaning the blood purification system, an instruction for cleaning the solution supply device is transmitted to the solution supply device in response to detecting the completion of all the cleaning of the plurality of blood purification devices. Receiving a notification of completion of cleaning of the solution supply device transmitted from the solution supply device, and in response to receiving the notification, the solution supply device, the first pipe, and the clean water supply device Sending an instruction to supply a solution for cleaning to the second tube.

  Preferably, in the cleaning of the blood purification system, the control program causes the computer to detect the completion of all the cleaning of the plurality of blood purification devices, and to supply the solution supply device, the first And instructing the second and second tubes to supply a solution for washing.

  Preferably, the control program further causes the computer to detect an operation on the clean water supply device or the solution supply device, and causes the blood purification system to be washed on condition that the operation is detected.

  According to another aspect of the present disclosure, a control device for a blood purification system is provided. The blood purification system includes a plurality of blood purification devices for blood purification treatment, a clean water supply device for supplying clean water to each blood purification device, and a solution supply for supplying dialysate to each blood purification device The apparatus includes a first pipe connecting the clean water supply apparatus and each blood purification apparatus, and a second pipe connecting the solution supply apparatus and each blood purification apparatus. The control device indicates completion of the cleaning transmitted from each blood purification device and a control unit configured to control cleaning of the clean water supply device, the solution supply device, the first tube and the second tube. And a detection unit configured to detect completion of all washing of the plurality of blood purification devices based on the signal. The control unit starts cleaning the clean water supply device, the solution supply device, the first tube, and the second tube in response to the detection unit detecting completion of all of the plurality of blood purification devices. It is configured.

  According to still another aspect of the present disclosure, a plurality of blood purification devices for blood purification treatment, a clean water supply device for supplying clean water to each blood purification device, and a dialysate being supplied to each blood purification device A solution supply device, a first tube connecting the clean water supply device and each blood purification device, a second tube connecting the solution supply device and each blood purification device, and a control device. A method for controlling a blood purification system is provided. In the control method, each blood purification device transmits a signal indicating completion of cleaning of the blood purification device to the control device, and the control device receives a signal from all of the plurality of blood purification devices. In response, performing cleaning of the blood purification system to clean the clean water supply device, the solution supply device, the first tube and the second tube.

  According to another aspect of the present disclosure, a plurality of blood purification devices for blood purification treatment, a clean water supply device for supplying clean water to the blood purification device, and a dialysate being supplied to each blood purification device Solution supply apparatus, a first pipe connecting the clean water supply apparatus and each blood purification apparatus, a second pipe connecting the solution supply apparatus and each blood purification apparatus, and the blood purification system described above A blood purification system comprising a control device is provided.

It is a figure which shows the structure of a blood purification system roughly. It is a figure which shows the washing | cleaning sequence of each apparatus of a blood purification system. It is a figure which shows roughly the hardware constitutions of a blood purification apparatus. It is a figure which shows roughly the hardware constitutions of RO apparatus. It is a figure for demonstrating an example of the data stored in RO apparatus. It is a figure which shows roughly the hardware constitutions of A stock solution supply apparatus. It is a figure which shows roughly the hardware constitutions of B stock solution supply apparatus. It is a flowchart of the process for wash | cleaning the whole blood purification system. It is a sequence diagram for washing | cleaning of the whole blood purification system in 3rd Embodiment. It is a figure which shows schematically the hardware constitutions of A stock solution supply apparatus in 3rd Embodiment. It is a figure which shows schematically the hardware constitutions of B stock solution supply apparatus in 3rd Embodiment. It is a sequence diagram for washing | cleaning of the whole blood purification system in the blood purification system of 4th Embodiment. It is a figure which shows schematically the structure of the blood purification system of 5th Embodiment. It is a figure which shows the hardware constitutions of the computer for control in 5th Embodiment. It is a sequence diagram for washing | cleaning of the whole blood purification system in 5th Embodiment.

  Hereinafter, embodiments of the present disclosure will be described with reference to the drawings. In the following description, the same parts and components are denoted by the same reference numerals. Their names and functions are also the same. Therefore, these descriptions will not be repeated.

[First Embodiment]
<Configuration of blood purification system>
FIG. 1 is a diagram schematically showing a configuration of a blood purification system. The blood purification system according to the first embodiment is a system for blood purification treatment of a plurality of patients in a facility 100 such as a hospital, for example, and includes a plurality of blood purification devices. In the blood purification system, a blood purification apparatus is used for each patient to perform blood purification treatment. In FIG. 1, a plurality of blood purification apparatuses are shown as a blood purification apparatus 1A and a blood purification apparatus 1B. In each figure, the blood purification apparatus may be indicated as “DI”. In FIG. 1, solid arrows indicate the flow of the solution, and broken arrows indicate the flow of information. The number of blood purification devices included in the blood purification system is not limited to “2” shown as blood purification devices 1A and 1B in FIG. In this specification, blood purification devices 1A and 1B may be referred to as blood purification device 1 as a general term for a plurality of blood purification devices.

  The blood purification system further includes an RO device 2 for providing clean water to each of the blood purification devices 1A and 1B, and an A stock solution supply device for supplying the above-described A stock solution to each of the blood purification devices 1A and 1B. 3 and a B stock solution supply device 4 for supplying the B stock solution described above to each of the blood purification apparatuses 1A and 1B.

  The blood purification system also includes a clean water pipe 5 for supplying clean water from the RO device 2 to each blood purification device 1 and an A for supplying A stock solution from the A stock solution supply device 3 to each blood purification device 1. A stock solution pipe 6 and a B stock solution pipe 7 for supplying the B stock solution from the B stock solution supply device 4 to each blood purification device 1 are included. The clean water pipe 5 includes a branch pipe 51 connected to the A stock solution supply apparatus 3, a branch pipe 52 connected to the B stock solution supply apparatus 4, and branch pipes 5A, 5B connected to each blood purification apparatus 1. including. The A stock solution pipe 6 includes branch pipes 6A, 6B... Connected to each blood purification apparatus 1. The B stock solution pipe 7 includes branch pipes 7A, 7B... Connected to each blood purification apparatus 1.

  In the blood purification system of the first embodiment, at the time of blood purification treatment, each blood purification device 1 is supplied with clean water from the RO device 2, supplied with A stock solution from the A stock solution supply device 3, and The B stock solution is supplied from the B stock solution supply device 4. Each blood purification apparatus 1 mixes clean water, A stock solution, and B stock solution in proportions suitable for the patient undergoing blood purification treatment, thereby generating a dialysate suitable for the patient and utilizing it for blood purification treatment. .

  In the blood purification system, each blood purification apparatus 1 includes a unit (cleaning unit 16 in FIG. 3 described later) for cleaning the blood purification apparatus 1. The A stock solution supply device 3 and the B stock solution supply device 4 include units (cleaning unit 36 in FIG. 6 and cleaning unit 46 in FIG. 7 described later) for cleaning the respective devices.

  In each blood purification apparatus 1, when the blood purification treatment is completed, the blood purification apparatus 1 starts cleaning. In the blood purification system, when the cleaning of the blood purification apparatus 1 is completed in all the blood purification apparatuses 1, the process for cleaning the blood purification system is started. The process for cleaning the blood purification system includes cleaning of the A raw solution supply device 3 and the B raw solution supply device 4 and supply of clean water from the RO device 2 to the entire blood purification system.

<Cleaning sequence in blood purification system>
Next, with reference to FIG. 2, a sequence for cleaning in the blood purification system will be described. FIG. 2 is a diagram illustrating a cleaning sequence of each device of the blood purification system.

  As shown in FIG. 2, in the blood purification system, an instruction to start cleaning the blood purification apparatus 1 is input to the blood purification apparatus 1 that has completed the blood purification treatment (arrow A00). The instruction is input to the blood purification apparatus 1 by, for example, an operator (for example, a medical worker) recognizing completion of blood purification treatment performing a predetermined operation (for example, pressing a predetermined button). . In response to the input of the instruction, each blood purification device 1 starts cleaning the blood purification device 1. When each blood purification apparatus 1 completes cleaning of the blood purification apparatus 1, the blood purification apparatus 1 transmits a signal indicating that to the RO apparatus 2 that is a control apparatus of the blood purification system (arrow A01).

  The RO device 2 determines whether or not the cleaning of all the blood purification devices 1 has been completed based on the signal transmitted from each blood purification device 1. And RO device 2 will start washing of a blood purification system, if it detects that washing of all blood purification devices 1 was completed.

  In the cleaning of the blood purification system, the RO device 2 instructs the A stock solution supply device 3 to clean the A stock solution supply device 3 (arrow A02), and the B stock solution supply device 4 cleans the B stock solution supply device 4. Is indicated (arrow A03). While sending instructions to the A stock solution supply device 3 and the B stock solution supply device 4, the RO device 2 was used for washing in each of the blood purification devices 1 in the A stock solution supply device 3 and the B stock solution supply device 4. An instruction to suck the cleaning solution is output.

  In response to an instruction from the RO device 2, the A stock solution supply device 3 starts cleaning the A stock solution supply device 3, and the B stock solution supply device 4 starts cleaning the B stock solution supply device 4. The cleaning liquid used for cleaning the A stock solution supply device 3 is guided to each blood purification device 1 via the A stock solution pipe 6 and the branch pipes 6A and 6B. The cleaning liquid used for cleaning the B stock solution supply device 4 is guided to each blood purification device 1 via the B stock solution pipe 7 and the branch pipes 7A and 7B.

  When the A stock solution supply device 3 is completely cleaned, the A stock solution supply device 3 notifies the RO device 2 to that effect (arrow A04). When the washing of the B stock solution supply device 4 is completed, the B stock solution supply device 4 notifies the RO device 2 to that effect (arrow A05).

  When the RO device 2 serving as the control device of the blood purification system receives a notification that the cleaning has been completed from the A stock solution supply device 3 and the B stock solution supply device 4, the RO device 2 serves as a device that supplies clean water to the blood purification system. Then, supply clean water to the entire blood purification system. Thus, the RO device 2 supplies clean water to the A stock solution supply device 3 via the branch pipe 51, supplies clean water to the B stock solution supply device 4 via the branch pipe 52, and connects the branch pipes 5A and 5B. Then, clean water is supplied to each blood purification device 1. The clean water supplied to the A stock solution supply device 3 and the B stock solution supply device 4 is sucked into each blood purification device 1 via the branch pipes 6A, 6B, 7A, 7B. In each blood purification device 1, the suctioned clean water and the clean water supplied from the RO device 2 are appropriately discharged.

  Each blood purification apparatus 1 uses a cleaning unit 16 described later to perform the cleaning of the blood purification apparatus 1 after completion of the blood purification treatment as described above. Such cleaning of the blood purification apparatus 1 alone is performed separately from the “cleaning of the entire blood purification system” in this specification, and is performed before the cleaning of the entire blood purification system.

<Hardware configuration of blood purification apparatus 1>
FIG. 3 is a diagram schematically showing a hardware configuration of the blood purification apparatus 1. With reference to FIG. 3, the hardware configuration of the blood purification apparatus 1 will be described.

  As shown in FIG. 3, the blood purification apparatus 1 includes a controller 10 that controls the operation of the blood purification apparatus 1 and a storage device 11. The controller 10 includes a processor such as a CPU (Central Processing Unit). The storage device 11 includes a program storage area 111 for storing a program executed by the processor of the controller 10 and a data storage area 112 for storing various data used for executing the program.

  The blood purification apparatus 1 further includes a communication device 12, an operating device 13, a display device 14, a blood purification processing unit 15, and the above-described cleaning unit 16. The communication device 12 is provided for the blood purification device 1 to communicate with other devices, and includes, for example, a wireless transmission / reception device. The operation device 13 is provided for the blood purification apparatus 1 to accept an operation from the outside, and includes, for example, an operation button and / or a touch panel. The display device 14 is provided for the blood purification apparatus 1 to display information, and includes a display device such as a liquid crystal display device or a plasma display. The blood purification processing unit 15 is provided for the blood purification apparatus 1 to perform blood purification treatment on a patient, and is a pump for supplying dialysate to a blood purification apparatus such as a hollow fiber dialyzer attached to the blood purification apparatus 1. In order to mix the clean water supplied from the RO device 2, the A stock solution supplied from the A stock solution supply device 3, and the B stock solution supplied from the B stock solution supply device 4 at a ratio suitable for the patient, It includes a member for controlling the degree of opening and closing of a valve for introducing the solution into a given container. The cleaning unit 16 is provided for cleaning the blood purification apparatus 1 and includes, for example, a tank that stores the cleaning liquid, a member that is driven to supply the cleaning liquid from the tank to the inside of the blood purification apparatus 1, and the like.

<Hardware configuration of RO device 2>
FIG. 4 is a diagram schematically showing a hardware configuration of the RO device 2. The hardware configuration of the RO device 2 will be described with reference to FIG.

  As shown in FIG. 4, the RO device 2 includes a controller 20 that controls the operation of the RO device 2 and a storage device 21. The controller 20 includes a processor such as a CPU. The storage device 21 includes a program storage area 211 for storing a program executed by the processor of the controller 20 and a data storage area 212 for storing various data used for executing the program.

  In the first embodiment, the RO device 2 also has a function as a control device for the entire blood purification system. More specifically, the controller 20 functions as the control unit 201 and the detection unit 202 when the processor executes a program in the program storage area 211. The control unit 201 instructs the A stock solution supply device 3 and the B stock solution supply device 4 to perform cleaning (arrows A02 and A03) and clean water for the entire blood purification system by the RO device 2 as described with reference to FIG. To control the supply. The detection unit 202 detects that the cleaning of all the blood purification apparatuses 1 has been completed.

  The detection unit 202 refers to data representing the cleaning state of each blood purification device 1 stored in the data storage area 212, for example, and detects that the cleaning of all blood purification devices 1 has been completed. An example of the contents of the data is shown in FIG.

  In the data shown in FIG. 5, each device ID corresponds to each blood purification device 1. In the data, the cleaning state is represented by a value 1 or a value 0 for each device ID. In the initial state of the data, the cleaning state of each blood purification apparatus 1 is set to a value of 0. When the controller 20 receives a signal indicating that the cleaning is completed from each blood purification device 1, the controller 20 updates the value of the cleaning state of the blood purification device 1 to a value 1. And the controller 20 detects that the washing | cleaning of all the blood purification apparatuses 1 was completed when the washing | cleaning state of all the blood purification apparatuses 1 became the value 1. FIG.

  In the blood purification system, the manner of detecting that all the blood purification apparatuses 1 have been cleaned is not limited to this. A relay device is provided between each blood purification device 1 and the RO device 2, and each blood purification device 1 transmits a signal indicating the completion of cleaning to the relay device, and the relay device is connected to all blood purification devices 1. A specific signal may be transmitted to the RO device 2 when the completion of cleaning is detected. In this case, the controller 20 detects that the cleaning of all the blood purification apparatuses 1 has been completed when the specific signal is received.

  Returning to FIG. 4, the RO device 2 further includes a communication device 22, an operation device 23, a display device 24, and a clean water supply unit 25. The communication device 22 is composed of a wireless transmission / reception device, for example. The operation device 23 includes, for example, an operation button and / or a touch panel. The display device 24 includes a display device such as a liquid crystal display device or a plasma display. The clean water supply unit 25 is a unit for supplying clean water to the blood purification device 1, the A stock solution supply device 3, and the B stock solution supply device 4, for example, an apparatus that generates clean water by reverse osmosis or the like, A valve for sending water to the clean water pipe 5 and a circuit for controlling opening and closing of the valve are included.

<Hardware configuration of A stock solution supply device 3>
FIG. 6 is a diagram schematically showing a hardware configuration of the A stock solution supply device 3. With reference to FIG. 6, the hardware configuration of the A stock solution supply device 3 will be described.

  As shown in FIG. 6, the A stock solution supply device 3 includes a controller 30 that controls the operation of the A stock solution supply device 3 and a storage device 31. The controller 30 includes a processor such as a CPU. The storage device 31 includes a program storage area 311 for storing a program executed by the processor and a data storage area 312 for storing various data used for executing the program.

  The A stock solution supply device 3 further includes a communication device 32, an operation device 33, a display device 34, an A stock solution supply unit 35, and the above-described cleaning unit 36. The communication device 32 is composed of, for example, a wireless transmission / reception device. The operation device 33 includes, for example, an operation button and / or a touch panel. The display device 34 includes a display device such as a liquid crystal display device or a plasma display. The A stock solution supply unit 35 is provided for supplying the A stock solution to the blood purification apparatus 1, and controls opening and closing of a tank for storing the A stock solution and a valve for supplying the A stock solution from the tank to the A stock solution pipe 6. Including circuits. The cleaning unit 36 is provided for cleaning the A stock solution supply device 3, and includes, for example, a tank that stores the cleaning solution, a member that is driven to supply the cleaning solution from the tank to the inside of the A stock solution supply device 3, and the like. .

<Hardware Configuration of B Stock Solution Supply Device 4>
FIG. 7 is a diagram schematically showing a hardware configuration of the B stock solution supply device 4. With reference to FIG. 7, the hardware configuration of the B stock solution supply device 4 will be described.

  As shown in FIG. 7, the B stock solution supply device 4 includes a controller 40 that controls the operation of the B stock solution supply device 4 and a storage device 41. The controller 40 includes a processor such as a CPU. The storage device 41 includes a program storage area 411 for storing a program executed by the processor, and a data storage area 412 for storing various data used for executing the program.

  The B stock solution supply device 4 further includes a communication device 42, an operation device 43, a display device 44, a B stock solution supply unit 45, and the above-described cleaning unit 46. The communication device 42 is composed of, for example, a wireless transmission / reception device. The operation device 43 includes, for example, operation buttons and / or a touch panel. The display device 44 includes a display device such as a liquid crystal display device or a plasma display. The B stock solution supply unit 45 is provided to supply the B stock solution to the blood purification apparatus 1 and controls opening and closing of a tank that stores the B stock solution and a valve that feeds the B stock solution from the tank to the B stock solution pipe 7. Including circuits. The cleaning unit 46 is provided for cleaning the B stock solution supply device 4, and includes, for example, a tank that stores the cleaning solution, a member that is driven to supply the cleaning solution from the tank to the inside of the B stock solution supply device 4, and the like. .

<Flow of control executed by control device>
FIG. 8 is a flowchart of processing for washing the entire blood purification system, which is executed by the controller 20 as a control device of the blood purification system. The contents of the process will be described with reference to FIG.

  As shown in FIG. 8, in step S <b> 10, the controller 20 receives a signal indicating completion of washing from each blood purification device 1. Further, in the data as shown in FIG. 5, the controller 20 updates the cleaning state of the blood purification apparatus 1 that has received the cleaning completion signal from the value 0 to the value 1. Then, the controller 20 advances the control to step S20.

  In step S20, the controller 20 determines whether or not all blood purification apparatuses 1 have been cleaned. This determination is realized, for example, by referring to the data shown in FIG. When it is determined that the cleaning of all blood purification apparatuses 1 has been completed, the controller 20 advances the control to step S30, and when it is determined that the cleaning of all blood purification apparatuses 1 has not yet been completed, the control returns to step S10.

  In step S30, the controller 20 resets the cleaning states of all blood purification apparatuses 1 by setting the values of the cleaning states of all blood purification apparatuses 1 to “0” in the data shown in FIG. (Updating to value 0), the control proceeds to step S40.

  In step S40, the controller 20 instructs the A stock solution supply device 3 and the B stock solution supply device 4 to perform cleaning, as indicated by arrows A02 and A03 in FIG. 2, and advances the control to step S50.

  In step S50, the controller 20 determines whether or not the cleaning of both the A stock solution supply device 3 and the B stock solution supply device 4 has been completed. This determination is made based on, for example, whether or not notification of completion of cleaning has been received from both the A stock solution supply device 3 and the B stock solution supply device 4. The controller 20 continues the determination in step S50 until it is determined that the cleaning of both of the A stock solution supply device 3 and the B stock solution supply device 4 is completed, and if it is determined that both cleaning is completed, the control proceeds to step S60. Proceed.

  In step S60, the controller 20 causes the RO device 2 to supply clean water to the entire blood purification system and ends the control. The clean water supplied here is an example of a cleaning liquid supplied to the A stock solution supply device 3, the B stock solution supply device 4, the clean water pipe 5, the A stock solution pipe 6, and the B stock solution pipe 7. The RO device 2 may supply a dedicated solution instead of clean water as the cleaning liquid.

<Summary of First Embodiment>
In the first embodiment described above, the solution supply device for supplying dialysate to each blood purification device is constituted by:

  The controller 20 that operates as a control device of the blood purification system detects completion of cleaning of all the blood purification devices 1 in the system based on a signal indicating completion of cleaning from each blood purification device 1. In addition, when each blood purification apparatus 1 transmits a signal indicating the completion of the cleaning to a given relay apparatus instead of the controller 20, the controller 20 uses all signals in the system based on the signal from the relay apparatus. Completion of washing of blood purification apparatus 1 is detected.

  Then, when the controller 20 detects completion of cleaning of all the blood purification apparatuses 1 in the blood purification system, the controller 20 starts cleaning the entire blood purification system.

[Second Embodiment]
The blood purification system of the second embodiment includes a plurality of blood purification devices 1, an RO device 2, an A stock solution supply device 3, and a B stock solution supply device 4 as in the first embodiment. Since these hardware configurations can be the same as those in the first embodiment, detailed description will not be repeated.

  In the second embodiment, the controller 20, which is a control device of the blood purification system, in response to a specific operation performed on the RO device 2, the A stock solution supply device 3 or the B stock solution supply device 4, The processing described with reference to FIG. 8 is started. The process shown in FIG. 8 is started on the condition that such an operation has been performed, so that a person who operates the RO apparatus 2, the A stock solution supply apparatus 3, or the B stock solution supply apparatus 4 (for example, a medical worker). Only when it is determined that the entire blood purification system needs to be cleaned, the entire blood purification system is cleaned. That is, it is possible to prevent the entire blood purification system from being washed when it is unnecessary.

[Third Embodiment]
In the third embodiment, the controller 20 of the blood purification system is configured by the controller 20 of the RO device 2, the controller 30 of the A stock solution supply device 3, and the controller 40 of the B stock solution supply device 4. FIG. 9 is a sequence diagram for cleaning the entire blood purification system in the third embodiment. With reference to FIG. 9, the operation | movement sequence of each apparatus in the washing | cleaning of the whole blood purification system in 3rd Embodiment is demonstrated.

  As shown in FIG. 9, in the blood purification system according to the third embodiment, a washing instruction is input in each blood purification apparatus 1 (arrow B00), and washing is executed in each blood purification apparatus 1. When cleaning of the blood purification device 1 is completed, each blood purification device 1 transmits a signal indicating the completion to the A stock solution supply device 3 and the B stock solution supply device 4 (arrows B01 and B02).

  When the A stock solution supply device 3 determines that the cleaning of all the blood purification devices 1 has been completed, the A stock solution supply device 3 performs the cleaning of the A stock solution supply device 3. When the cleaning of the A stock solution supply device 3 is completed, this is notified to the RO device 2 (arrow B03). Further, when it is determined that the cleaning of all the blood purification devices 1 has been completed, the B stock solution supply device 4 executes the cleaning of the B stock solution supply device 4. Then, when the cleaning of the B stock solution supply device 4 is completed, this is notified to the RO device 2 (arrow B04).

  The RO device 2 supplies the cleaning solution to the entire blood purification system on condition that the notification of the completion of cleaning is received from both the A stock solution supply device 3 and the B stock solution supply device 4.

  FIG. 10 shows an example of the hardware configuration of the A stock solution supply device 3 according to the third embodiment. FIG. 11 shows an example of the hardware configuration of the B stock solution supply device 4 of the third exemplary embodiment.

  As shown in FIG. 10, the controller 30 of the A stock solution supply device 3 functions as a control unit 301 and a detection unit 302 by executing a program stored in the program storage area 311. The detection unit 302 detects that the cleaning of all the blood purification devices 1 has been completed based on the signal transmitted from each blood purification device 1. The control unit 301 causes the cleaning unit 36 to clean the A stock solution supply device 3 in response to the completion of cleaning of all the blood purification devices 1. Then, when the cleaning of the A stock solution supply device 3 is completed, the control unit 301 notifies the RO device 2 of that.

  As shown in FIG. 11, the controller 40 of the B stock solution supply device 4 functions as a control unit 401 and a detection unit 402 by executing a program stored in the program storage area 411. Based on the signal transmitted from each blood purification device 1, the detection unit 402 detects that cleaning has been completed in all the blood purification devices 1. The control unit 401 causes the cleaning unit 46 to clean the B stock solution supply device 4 in response to the completion of cleaning of all the blood purification devices 1. When the cleaning of the B stock solution supply device 4 is completed, the control unit 401 notifies the RO device 2 accordingly.

  The hardware configuration of the RO device 2 of the third embodiment is the same as the hardware configuration of FIG. 4, for example. In the RO device 2 of the third embodiment, the detection unit 202 detects that the cleaning process has been completed in both the A stock solution supply device 3 and the B stock solution supply device 4. In response to the detection unit 202 detecting that the cleaning process has been completed in both the A stock solution supply device 3 and the B stock solution supply device 4, the control unit 201 cleans the entire blood purification system in the clean water supply unit 25. Supply water.

  In the third embodiment, the hardware configuration of blood purification apparatus 1 can be the same as that of the first embodiment, and thus detailed description thereof will not be repeated here.

[Fourth Embodiment]
In the fourth embodiment, the controller 20 of the RO device 2, the controller 30 of the A stock solution supply device 3, and the controller 40 of the B stock solution supply device 4 constitute a control device of the blood purification system. In the “cleaning of the entire purification system”, cleaning of the A stock solution supply device 3 and the B stock solution supply device 4 and supply of clean water to the entire blood purification system by the RO device 2 are started simultaneously.

  In the fourth embodiment, the hardware configuration of the blood purification apparatus 1 may be as shown in FIG. The hardware configuration of the RO device 2 can be the one shown in FIG. The hardware configuration of the A stock solution supply device 3 can be the one shown in FIG. The B stock solution supply device 4 can be the one shown in FIG.

  FIG. 12 is a sequence diagram for cleaning the entire blood purification system in the blood purification system of the fourth embodiment. As shown in FIG. 12, when an instruction for cleaning is input to each blood purification apparatus 1 (arrow C00), the blood purification apparatus 1 executes the cleaning. When each blood purification apparatus 1 completes the cleaning of the blood purification apparatus 1, the blood purification apparatus 1 transmits a signal indicating the completion of the cleaning to the RO apparatus 2, the A stock solution supply apparatus 3, and the B stock solution supply apparatus 4 (arrows). C01, C02, C03). When the signals indicating the completion of cleaning are received from all the blood purification apparatuses 1, the A stock solution supply device 3 starts cleaning the A stock solution supply device 3, and the B stock solution supply device 4 cleans the B stock solution supply device 4. The RO device 2 starts supplying clean water to the entire blood purification system.

[Fifth Embodiment]
In the fifth embodiment, a control device for controlling the blood purification system is provided separately from the RO device 2, the A stock solution supply device 3, and the B stock solution supply device 4. FIG. 13 is a diagram schematically showing the configuration of the blood purification system according to the fifth embodiment. As shown in FIG. 13, the blood purification system of the fifth embodiment is for control as a control device in addition to blood purification device 1, RO device 2, A stock solution supply device 3, and B stock solution supply device 4. A computer 9 is included.

  FIG. 14 is a diagram illustrating a hardware configuration of the control computer 9. The hardware configuration of the control computer 9 will be described with reference to FIG.

  As shown in FIG. 14, the control computer 9 includes a controller 90 that controls the operation of the control computer 9 and a storage device 91. The controller 90 includes a processor such as a CPU. The storage device 91 includes a program storage area 911 for storing a program executed by the processor, and a data storage area 912 for storing various data used for executing the program.

  The control computer 9 further includes a communication device 92, an operating device 93, and a display device 94. The communication device 92 is provided for the control computer 9 to communicate with the blood purification device 1, the RO device 2, the A stock solution supply device 3, and the B stock solution supply device 4, and is composed of, for example, a wireless transmission / reception device. The operation device 93 includes, for example, an operation button and / or a touch panel. The display device 94 includes a display device such as a liquid crystal display device or a plasma display.

  The controller 90 functions as a control unit 901 and a detection unit 902 when the processor executes a program in the program storage area 911. The control unit 901 controls the cleaning instruction to the A stock solution supply device 3 and the B stock solution supply device 4 and the supply of clean water to the entire blood purification system to the RO device 2. The detection unit 902 detects that the cleaning of all the blood purification devices 1 has been completed based on the signal transmitted from each blood purification device 1.

  FIG. 15 is a sequence diagram for cleaning the entire blood purification system according to the fifth embodiment. With reference to FIG. 15, the operation sequence of each device in the cleaning of the entire blood purification system in the fifth embodiment will be described.

  As shown in FIG. 15, in the blood purification system of the fifth embodiment, when an instruction for washing is input in each blood purification apparatus 1 (arrow D00), each blood purification apparatus 1 starts its washing. . When each blood purification apparatus 1 completes the cleaning of the blood purification apparatus 1, it transmits a signal indicating the completion to the control computer 9 (arrow D01).

  When the control computer 9 detects that the cleaning of all the blood purification apparatuses 1 has been completed, the control computer 9 instructs the A stock solution supply device 3 to clean the A stock solution supply device 3 (arrow D02), and supplies the B stock solution. The apparatus 4 is instructed to clean the B stock solution supply apparatus 4 (arrow D03). In response to this, the A stock solution supply device 3 starts cleaning the A stock solution supply device 3. Further, the B stock solution supply device 4 starts cleaning the B stock solution supply device 4. When the cleaning of the A stock solution supply device 3 is completed, the A stock solution supply device 3 notifies the control computer 9 of this (arrow D04). When the cleaning of the B stock solution supply device 4 is completed, the B stock solution supply device 4 notifies the control computer 9 of this (arrow D05).

  When receiving the notification of the completion of washing from both the A stock solution supply device 3 and the B stock solution supply device 4, the control computer 9 instructs the RO device 2 to supply clean water to the entire blood purification system (arrow D06). ). In response to this, the RO device 2 supplies clean water to the entire blood purification system.

  Each embodiment disclosed this time must be considered as illustrative in all points and not restrictive. The scope of the present invention is defined by the terms of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the terms of the claims. In addition, the invention described in the embodiment and each modification is intended to be carried out independently or in combination as much as possible.

  DESCRIPTION OF SYMBOLS 1 Blood purification apparatus, 2 RO apparatus, 3 A undiluted solution supply apparatus, 4 B undiluted solution supply apparatus, 5 Clean water piping, 6 A undiluted solution piping, 7 B undiluted solution piping, 9 Control computer 10, 20, 30, 40, 90 Controller 11, 21, 31, 41, 91 Storage device.

Claims (9)

A control program for a blood purification system, executed by a computer for controlling the blood purification system,
The blood purification system includes a plurality of blood purification devices for blood purification treatment, a clean water supply device for supplying clean water to each of the blood purification devices, and a dialysate for supplying each of the blood purification devices. A first tube connecting the clean water supply device and each blood purification device, and a second tube connecting the solution supply device and each blood purification device,
The control program is stored in the computer.
Detecting completion of all of the plurality of blood purification devices based on a signal indicating completion of washing transmitted from each of the blood purification devices;
In response to the detection of the completion of all cleaning of the plurality of the blood purification device, before Symbol solution supply device, for cleaning the first tube and the second tube, the cleaning of the blood purification system A control program for a blood purification system that executes processing for The process for cleaning the blood purification system includes:
In response to detecting completion of all of the plurality of blood purification devices, sending an instruction to wash the solution supply device to the solution supply device;
Receiving notification of completion of cleaning of the solution supply apparatus transmitted from the solution supply apparatus;
In response to receiving the notification, transmitting an instruction to supply liquid for cleaning to the solution supply device, the first tube, and the second tube to the clean water supply device. The blood purification system control program according to claim 1.   The processing for cleaning the blood purification system is performed by detecting the completion of all the cleaning of the plurality of blood purification devices, the solution supply device, the first The blood purification system control program according to claim 1, comprising instructing the supply of a liquid for cleaning to the tube and the second tube. The control program is stored in the computer.
Furthermore, the operation on the clean water supply device or the solution supply device is detected,
The control program for a blood purification system according to any one of claims 1 to 3, wherein a process for cleaning the blood purification system is executed on condition that the operation is detected. A control device for a blood purification system,
The blood purification system includes a plurality of blood purification devices for blood purification treatment, a clean water supply device for supplying clean water to each of the blood purification devices, and a dialysate for supplying each of the blood purification devices. A first tube connecting the clean water supply device and each blood purification device, and a second tube connecting the solution supply device and each blood purification device,
The controller is
A controller configured to control cleaning of the clean water supply device, the solution supply device, the first pipe and the second pipe;
A detection unit configured to detect completion of cleaning of all of the plurality of blood purification devices based on a signal output from each of the blood purification devices and indicating completion of cleaning of the blood purification device. ,
Wherein, in response to the detection section detects completion of all cleaning of the plurality of the blood purification device, before Symbol solution supply device, starting the cleaning of the first tube and the second tube A control device for a blood purification system configured to: Cleaning the solution supply device, the first tube, and the second tube,
Sending an instruction for cleaning the solution supply device to the solution supply device;
Receiving notification of completion of cleaning of the solution supply apparatus transmitted from the solution supply apparatus;
In response to receiving the notification, transmitting an instruction to supply liquid for cleaning to the solution supply device, the first tube, and the second tube to the clean water supply device. The control apparatus of the blood purification system of Claim 5. A plurality of blood purification devices for blood purification treatment, a clean water supply device for supplying clean water to each of the blood purification devices, a solution supply device for supplying dialysate to each of the blood purification devices, A control device for a blood purification system, comprising: a first tube connecting the clean water supply device and each blood purification device; and a second tube connecting the solution supply device and each blood purification device is executed. A method for controlling the blood purification system,
The control device receives a signal indicating completion of washing of the blood purification device from each of the blood purification devices;
Wherein the controller includes a possible in response to receiving said signals from all of the plurality of the blood purification device, before Symbol solution supply device, to execute the cleaning of the first tube and the second tube , Control method of blood purification system. Cleaning the solution supply device, the first tube, and the second tube,
Sending an instruction for cleaning the solution supply device to the solution supply device;
Receiving notification of completion of cleaning of the solution supply apparatus transmitted from the solution supply apparatus;
In response to receiving the notification, transmitting an instruction to supply liquid for cleaning to the solution supply device, the first tube, and the second tube to the clean water supply device. The control method of the blood purification system of Claim 7. A plurality of blood purification devices for blood purification treatment;
A clean water supply device for supplying clean water to the blood purification device;
A solution supply device for supplying dialysate to each of the blood purification devices;
A first pipe connecting the clean water supply device and each of the blood purification devices;
A second tube connecting the solution supply device and each of the blood purification devices;
A blood purification system comprising the blood purification system control device according to claim 5.

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