JP5584075B2 - Medical pump system and medical pump mounting rack - Google Patents

Description

  The present invention relates to a medical pump system in which a plurality of medical pumps are mounted on a rack, and a medical pump mounting rack.

  In hospitals, etc., in order to deliver medicinal solutions etc. into the patient's body, infusion pumps that inject the medicinal solution in the infusion bag into the patient via the infusion tube at the set infusion rate and infusion volume, and syringe drugs A syringe pump is used that delivers liquid to the patient at a set injection rate and injection volume. In general, these infusion pumps and syringe pumps (which are collectively referred to as medical pumps in the present specification) require one medical pump to send one kind of chemical liquid. Therefore, when it is going to administer a several chemical | medical solution to a patient simultaneously in an operating room, an intensive care unit, etc., several medical pumps according to the number of chemical | medical solutions are needed. If you place multiple medical pumps on a desk or place them on the floor, it takes up space and it is not easy to move them.There is a rack for mounting multiple medical pumps side by side. Used.

  When a plurality of medical pumps are mounted on a rack and used, operations for performing various settings or monitoring by individually operating the medical pumps are complicated. Therefore, a configuration in which a central control device that communicates with each medical pump mounted on the rack is provided so that the connection state of the medical pump and the infusion state of each medical pump can be monitored in the central control device is disclosed in Patent Document 1. It is described in.

Japanese Patent Laid-Open No. 11-347118

  The medical pump has a function of generating an alarm and prompting the user to take a countermeasure when occurrence of any malfunction is detected during liquid feeding or when a sign of occurrence of any malfunction is detected. However, if a sound alarm is generated from one medical pump while a plurality of medical pumps are mounted on the rack and liquid feeding is performed, for example, a sound alarm is generated from which medical pump is used by the user. It is difficult to grasp whether or not this has occurred. Alternatively, even if a display indicating that the medical pump is generating an alarm using the display is performed, if the display is not significantly different from the normal display, an alarm is being generated from a plurality of medical pumps. It is difficult to identify things immediately.

  When the central controller is provided separately from the rack in which the medical pump is mounted as in Patent Document 1, an alarm is generated in any of the medical pumps mounted in the rack on the display screen of the central controller. Can be displayed. However, this display is merely a display on the screen of the central control unit. The user must first confirm the layout on the screen, and then replace the layout on the screen with the layout on the actual rack. The medical pump generating the alarm will be identified. That is, the central control device described in Patent Document 1 does not allow direct access to the medical pump that is actually generating the alarm.

  The present invention has been made in view of the above-described problems. When a plurality of medical pumps are mounted on a rack and used, the user can immediately and easily visually recognize the medical pump that is generating an alarm. The purpose is to.

In order to achieve the above object, a medical pump system according to an aspect of the present invention has the following arrangement. That is,
A medical pump system in which a plurality of medical pumps are mounted on a rack,
The rack is
Communication means for communicating with a plurality of medical pumps mounted;
When an alarm notification is received from any of the plurality of medical pumps via the communication unit, a determination unit that determines a mounting position of the medical pump that has transmitted the alarm notification in the rack;
The direction display to be displayed on each of the other medical pumps is determined so as to indicate the mounting position determined by the determination unit from each of the medical pumps other than the medical pump that has generated the alarm notification. A decision means to
Transmitting means for transmitting an instruction for displaying the direction display determined by the determining means to each of the other medical pumps via the communication means.

  According to the present invention, since a display indicating the medical pump generating an alarm is performed using the display screens of the plurality of medical pumps mounted on the rack, the user can immediately and easily rack the rack. It becomes possible to identify the medical pump that is generating the above alarm.

(A) is a figure which shows the example of whole structure of the medical pump system by 1st Embodiment, (b) is a figure explaining the medical pump mounting rack by 1st Embodiment. It is a block diagram which shows the control structure of the medical pump mounting rack and medical pump by 1st Embodiment. It is a flowchart which shows the control procedure in the medical pump of 1st Embodiment. It is a flowchart which shows the control procedure by the medical pump mounting rack of 1st Embodiment. (A) and (b) are the figures which show the example of the instruction | indication display of the medical pump in which alarm generation | occurrence | production in the medical pump system of 1st Embodiment. It is a figure which shows the example which made it possible to arrange | position a medical pump two-dimensionally in the medical pump system of 1st Embodiment. (A) and (b) are figures which show the example of whole structure of the medical pump system of 2nd Embodiment. It is a block diagram explaining the control structure of the medical pump mounting rack by 2nd Embodiment. It is a figure which shows the example which enabled the two-dimensional arrangement | positioning of the medical pump mounting rack by 2nd Embodiment.

  Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

[First Embodiment]
Fig.1 (a) is a figure which shows an example of the external appearance structure of the medical pump system by 1st Embodiment. As shown in FIG. 1A, in this embodiment, a medical pump system having a configuration in which a plurality of medical pumps (six in this example) are mounted on a dedicated rack will be described. In FIG. 1A, reference numeral 101 denotes a medical pump mounting rack (hereinafter referred to as rack 101). In this example, up to six medical pumps 201 can be mounted in a line in the vertical direction. In the illustrated example, an infusion pump is shown as an example of the medical pump 201. Each pump includes a tube 211a for transporting a medical solution from an infusion bag (not shown) to each medical pump 201, A state in which a tube 211b for transporting a medical solution from the medical pump 201 to the patient is attached is shown. However, the number of medical pumps attached is not limited to this, and the medical pump is not limited to an infusion pump, and various medical pumps such as a syringe pump can be attached.

  FIG. 1B is a front view of the rack 101 with the medical pump 201 not attached. In the rack 101, a plurality (six in this example) of ports 102 are arranged corresponding to a plurality of pump mounting positions. Each of the plurality of ports 102 is formed by a connector that can be connected to the medical pump 201, and the medical pump 201 communicates with the rack 101 via the port 102. The ports 102 are assigned numbers # 1, # 2,..., # 6 in order from the top of the pump mounting positions arranged vertically.

  FIG. 2 is a block diagram illustrating a control configuration example of the rack 101 and the medical pump 201 according to the first embodiment. Each of the six ports 102 of the rack 101 is connected to the communication module 111. When the communication module 111 receives a signal (data) from the medical pump 201 via the port 102, the communication module 111 controls the received data and the received port number (any one of # 1 to # 6). 121 is notified. Further, when a pair of port number and data (command or the like) is received from the control unit 121, the data received from the control unit 121 is output to the port 102 corresponding to the port number. Thus, the control unit 121 of the rack 101 can individually communicate with each of the plurality of medical pumps 201 attached. The control unit 121 temporarily stores measurement data and various data as a CPU (not shown) such as a microcomputer, a ROM (not shown) that stores a control program for the entire apparatus executed by the CPU and various data, and a work area. A RAM (not shown) or the like that stores data is executed, and various processes including the process shown in the flowchart of FIG. 4 are executed while making decisions in each process step (step).

  In the medical pump 201, the display unit 202 includes, for example, a liquid crystal panel, and performs various displays under the control of the pump control unit 205. The connector 203 is connected to the port 102 and realizes electrical connection (communication) with the medical pump 201. Note that the connector 203 and the port 102 are connected via a cable. Alternatively, the connector 203 and the port 102 may be directly connected (for example, the connect 203 and the port 102 are connected by attaching the medical pump 201 to the rack 101). The pump control unit 205 controls the liquid feeding mechanism 206 to control the liquid feeding amount. In the case where the medical pump 201 is an infusion pump, the liquid feeding mechanism 206 includes, for example, a plurality of fingers for liquid feeding, and the plurality of fingers sequentially push the liquid transfusing tube to deliver the drug solution in the tube. Further, if the medical pump 201 is a syringe pump, the liquid feeding mechanism 206 is configured to attach a syringe and press the pusher.

  In the medical pump 201 having the above-described configuration, the pump control unit 205 generates an alarm when the medical pump 201 that it controls detects a state to notify the user of an alarm. The pump control unit 205 notifies the occurrence of an alarm using the screen of the display unit 202 and also notifies the rack 101 via the communication module 204. The pump control unit 205 has a function of displaying the type of arrow indicated on the display unit 202 when receiving an arrow display instruction from the rack 101 via the communication module 204. Hereinafter, this operation will be described with reference to the flowchart of FIG.

  FIG. 3 is a flowchart for explaining the operation of the medical pump 201. In step S <b> 301, the pump control unit 205 monitors an abnormality that has occurred in the medical pump 201, a sign of the occurrence of the abnormality, and the occurrence of an alarm factor (prompts the user to cancel the alarm factor by an operation or a countermeasure). To do. Here, for example, the abnormality is, for example, the blockage of the tube 211b, the sign of the occurrence of the abnormality, for example, the alarm at the maintenance time, the occurrence of the alarm factor, for example, forgetting to start, the tubes 211a, 211b or the syringe (not shown) Is a case where the medical pump 201 is not set correctly. When the occurrence of an alarm factor is detected (for example, when all settings / inputs are completed and the infusion start button operation is not performed in a state where preparation for infusion is ready), the pump control unit 205 Then, an alarm is displayed using the display unit 202, and an alarm notification is output to the rack 101 via the communication module 204 (YES in step S302 → step S303, step S304). Thereafter, in step S305, the pump control unit 205 waits for the alarm factor to be canceled. When the cause of the alarm is canceled, the process proceeds from step S305 to S306. In step S306, the pump control unit 205 stops outputting the alarm notification performed in step S304, and returns to the normal display from the alarm display performed in step S303.

  If an alarm factor has not occurred, the process proceeds from step S302 to step S307. In step S <b> 307, the pump control unit 205 determines whether an arrow display instruction has been received from the port 102 of the rack 101 via the communication module 204. If an instruction to display an arrow is received, the process proceeds from step S307 to step S308, and the pump control unit 205 displays the instructed arrow on the display unit 202. If an instruction to end the arrow display is received, the process proceeds from step S309 to step S310, and the pump control unit 205 returns the display on the display unit 202 to the normal state. The above is the display processing related to the alarm notification in the medical pump 201 of the present embodiment.

  Next, control by the rack 101 of this embodiment will be described. In the present embodiment, when an alarm is generated in the medical pump 201 mounted on the rack 101, it is mounted on the rack 101 in order to clearly indicate to the user which medical pump is generating the alarm. The display unit 202 of another medical pump is used. Such display control is executed by the control unit 121 of the rack 101, and will be described in detail with reference to the flowchart of FIG. 4 and FIGS. 5 (a) and 5 (b).

In step S <b> 401, the control unit 121 confirms the port through which the alarm notification from the medical pump 201 is received via the communication module 111 and the ports 102 of # 1 to # 6. As described above, since the communication module 111 notifies the control unit 121 of the port number and the alarm notification as a pair, the control unit 121 knows which port of # 1 to # 6 is receiving the alarm notification. Can do. Next, in step S402, the control unit 121 determines whether or not the alarm notification reception state at each port has changed from the immediately preceding state. For example,
-When the number of ports 102 receiving the alarm notification changes (change from a state where there is no port receiving the alarm notification (0) to a certain state or a port receiving the alarm notification Including a change from present to absent)
・ The number of ports that receive alarm notifications does not change, but the ports that are receiving change (for example, the port that receives alarm notifications switches from # 1 to # 2) ),
Etc.

  If it is determined in step S402 that there is no change in the alarm notification reception state, the process returns to step S401. On the other hand, if it is determined that there is a change in the reception state of the alarm notification, the process proceeds to step S403. In step S <b> 403, the control unit 121 determines whether any port 102 has received an alarm notification. When the alarm notification is not received in all the ports 102, it means that there is a medical pump 201 whose alarm is canceled. Therefore, the process proceeds to step S404, and the control unit 121 outputs an arrow display end instruction to all the ports 102 of # 1 to # 6. As described above, the pump control unit 205 of the medical pump 201 that has received an instruction to end the arrow display from the port 102 ends the display if an arrow is being displayed by the display instruction from the rack 101 and is The display is returned (S309, S310).

  On the other hand, if it is determined in step S403 that an alarm notification has been received at any of the ports 102, the process proceeds to step S405. In step S405, the control unit 121 sets the maximum value of the port number of the port 102 that has received the alarm notification to the variable M and the minimum value to the variable L. In the case of the present embodiment, the medical pumps are arranged in a vertical row and assigned so that the port numbers increase in order from the top. Therefore, the medical pump that generates an alarm by setting the variables L and M is attached. The position can be determined. Note that M = L when there is one port receiving the alarm. For example, in the case of FIG. 5A, only the medical pump 201 connected to the port # 3 generates an alarm, and in this case, M = L = 3. In the case of FIG. 5B, an alarm is generated by the medical pumps 201 of # 3 and # 5, and M = 5 and L = 3. In step S406, the control unit 121 sets “1”, which is the top port number (the number of the port located at the top in this example), as the port number to be processed in the variable P. Thereafter, the processing of steps S407 to S412 is repeated until the variable P reaches the maximum number of ports (6 in this example), whereby the processing is performed for all the ports.

  First, in step S407, the control unit 121 determines whether the port with the number P is a port that receives an alarm (hereinafter also referred to as an alarm port). If it is an alarm port, since the medical pump 201 connected to the port has generated an alarm, the instruction to display an arrow is not given and the process is skipped to step S413. For example, in the situation shown in FIG. 5A, the port # 3 (P = 3) is determined as an alarm port in step S407.

  If the port of number P is not the port receiving the alarm, the process proceeds to step S408. In step S408, the control unit 121 compares the values of the variables M, L, and P. As a result, if M (maximum value)> P (port number)> L (minimum value), the display of the up / down arrow is instructed to the port of number P. As a result, for example, in the display section of the medical pump connected to the port # 4 in FIG. 5B, an up / down arrow as shown in the figure is displayed, and an alarm is issued in the upward and downward directions of the medical pump. It can be shown to the user that there is a medical pump that is generating.

  If NO is determined in step S408, either the port number P is smaller than the minimum value L or the port number P is larger than the maximum value M. Therefore, in step S410, the control unit 121 determines whether or not L> P. If L> P (YES), the process proceeds to step S411. Otherwise (NO), the process proceeds to step S412. To proceed.

  When the port number P is smaller than the minimum value L (in the case of YES at step S410), the medical pump generating the alarm exists below the medical pump connected to the port number P. . This is because in this example, the port numbers are assigned so as to increase from top to bottom as shown in FIG. Therefore, in step S411, the control unit 121 instructs the port with the number P to display a downward arrow. As a result, in the example of FIGS. 5A and 5B, an instruction to display a down arrow is transmitted to the medical pump attached to the ports # 1 and # 2, The display as shown is realized.

  On the other hand, when the process proceeds from step S410 to step S412 (NO in S410), the port number P is greater than the maximum value M. In this case, the medical pump connected to the port having the port number P exists below the medical pump generating the alarm. Therefore, in step S412, the control unit 121 outputs an instruction to display an upward arrow with respect to the port with the number P. As a result, in the case of FIG. 5A, an instruction to display an up arrow is sent to the ports # 4 to # 6, and the medical pump attached to these ports displays an up arrow on the screen. become. Similarly, in the case of FIG. 5B, an instruction to display an up arrow is sent to the port # 6, and the medical pump attached to the port # 6 displays an upward arrow on the screen. In this way, an arrow is displayed in a direction from each of the medical pumps that have not issued an alarm to the medical pump (the mounting position) that has issued the alarm. Note that the method of assigning port numbers is not limited to this example, and various modifications are possible, and the processing contents described above are also changed according to the assignment method. It is clear to the contractor.

  In step S413, the control unit 121 determines whether or not the above processing has been performed for all ports depending on whether or not the variable P has reached the maximum port number (6 in this example). If the variable P is not the maximum port number, P is incremented by 1 in step S414, the process returns to step S407, and the processes in steps S407 to S412 are performed for the next port. On the other hand, when the variable P reaches the maximum port number, the process returns to step S401.

  Through the processing as described above, in the medical pump system of the present embodiment, as shown in FIGS. 5A and 5B, when there is a medical pump that has generated an alarm, the display of other medical pumps A display is made to indicate the medical pump that generated the alarm. Therefore, the user can immediately visually recognize which medical pump is generating the alarm only by looking at the rack 101.

  As described above, in the first embodiment, the configuration in which the medical pumps are arranged in a vertical row as illustrated in FIG. 1 has been described, but the configuration is not limited thereto. For example, it is obvious that a medical pump system using a rack in which medical pumps are arranged in a horizontal row may be used. In this case, the arrow display will point to the left and right.

  Further, as shown in FIG. 6, the present invention can be applied to a configuration in which a plurality of rows of medical pumps can be arranged vertically and horizontally. In this case, in order to specify which number port in which column, the port number is two digits, the upper digit indicates the column, and the lower digit indicates what number. For example, in FIG. 6, the right column is 1, the left column is 2, # 11 to # 16 are the 6 port numbers in the right column, and # 21 to # 26 are the 6 port numbers in the left column. Yes. In this way, the relative two-dimensional positional relationship between the alarm port and other ports can be determined. Therefore, the control unit 121 can select an arrow in a direction closest to the direction toward the alarm port position from among a plurality of types of arrows, and displays each selected medical pump (each port 102 so as to display the selected arrow. If a display instruction is issued to), a display as shown in FIG. 6 can be realized. For example, eight arrows in the up / down / left / right and diagonal directions are prepared, and the arrow in the direction closest to the direction from a certain port to the alarm port is selected. In the case of FIG. 6, the port # 23 is an alarm port, and in the case of the medical pumps # 11 and # 12, the diagonally lower right direction which is the arrow closest to the direction of the port # 23 from the ports # 11 and # 12 The arrow is selected and displayed. Such display control can also be applied to the case of three or more columns, and an arrow to be displayed on each medical pump can be determined. Note that the fineness of the arrow is not limited to this. Alternatively, the direction of the arrow may be indicated by an angle from the rack 101, and the arrow having the angle indicated by the medical pump 201 may be drawn and displayed.

  As described above, according to the medical pump system of the first embodiment, when the alarm notification is received, the control unit 121 sets the mounting position in the rack 101 of the medical pump generating the alarm notification to the port. (S305). The control unit 121 determines the display contents so as to indicate the mounting position of the medical pump generating the alarm on each display unit of the medical pump other than the medical pump generating the alarm. (S307 to S312). And the control part 121 instruct | indicates to display the determined display content with respect to each of other pumps of medical pumps other than the medical pump which has generated the alarm about the determined display content. (S309, S311, S312). As a result, as shown in FIG. 5 and FIG. 6, a display that indicates the position of the medical pump performing the alarm notification by another medical pump is realized. Therefore, the user can easily identify the medical pump in which the alarm has occurred from the display of the medical pump mounted on the rack, and can quickly respond to the alarm.

  In addition, when a plurality of alarm ports are detected, the up / down arrows are used, but a configuration in which two types of arrows, a down arrow and an up arrow, are alternately displayed may be employed. In this case, the medical pump that has received the up / down arrow display instruction from the rack 101 may alternately display the down arrow and the up arrow, or may display the up arrow / down arrow display instruction from the rack 101 at an appropriate time. You may make it give to a medical pump alternately by blinking at intervals. By appropriately controlling the blinking time interval, it may be visible to the user as an arrow of animation from the bottom to the top or from the top to the bottom. Moreover, although the arrow is used as the direction display for indicating the mounting position of the medical pump generating the alarm, the present invention is not limited to this. Further, an orange arrow may be used in the case of a forgetting start alarm or a remaining amount alarm, a red arrow may be used in the case of an infusion completion alarm, and the color of the arrow may be changed according to the content of the alarm. Further, any display may be used as long as it has a direction attribute such as a display using some figure that can indicate the direction.

  In the above embodiment, the mounting position of the medical pump generating the alarm is determined from the port number that received the alarm notification. However, each medical pump 201 adds information indicating the mounting position to the alarm notification. May be. However, in this case, a configuration for registering the mounting position in each medical pump is required. For example, the medical pump 201 is provided with a digital switch so that a number corresponding to the above-described port number can be set. When an alarm is generated, the pump control unit 205 reads the set value of the digital switch and alerts this. In addition to the notification, the rack 101 is notified. According to such a configuration, the communication module 111 can omit the function of adding a port number, but each medical pump needs to have a function of setting a number.

[Second Embodiment]
In the first embodiment, the configuration in which a plurality of medical pumps 201 are mounted on a single rack 101 has been described. In the second embodiment, an embodiment will be described in which a plurality of racks each capable of mounting a plurality of medical pumps 201 can be connected to form a medical pump system, and the system can be configured flexibly. 7A and 7B are views showing an example of the appearance of the medical pump system according to the second embodiment. FIG. 7A shows a configuration in which two subordinate racks 701 are connected to the main rack 601 in the vertical direction, and the medical pumps are arranged in a row in the vertical direction. Each of the main rack 601 and the subordinate rack 701 can be equipped with three medical pumps 201. FIG. 7A shows a state in which nine medical pumps are arranged in a vertical line.

  FIG. 8 is a block diagram illustrating a control function in the rack configuration shown in FIG. The main rack 601 includes a plurality of ports 602, a control unit 611, and a communication module 621, similar to the rack 101 of the first embodiment. The main rack 601 further includes connectors 605, 606, and 607 for connecting subordinate racks. The subordinate rack 701 has a plurality of ports 702 for communication connection with medical pumps, and a connector 703 for connection with any of the connectors 605, 606, 607 of the main rack 601. In the subordinate rack 701, each signal line of the plurality of ports 702 is connected to one connector 703.

  When the communication module 621 receives a signal from the subordinate rack 701 connected to the connectors 605 to 607 of the main rack 601, a value obtained by adding a predetermined number to the port number in the subordinate rack 701 is set as a port number, and this is controlled together with the signal. Part 611. The predetermined number to be added is preset for each connector. For example, 10 is set for the connector 605, 20 is set for the connector 606, and 30 is set for the connector 607. When adding a subordinate rack, a subordinate rack 701 arranged immediately below the main rack 601 is connected to the connector 605, a subordinate rack arranged below the subordinate rack is connected to the connector 606, and further arranged below the subordinate rack. Assume that the subordinate rack is connected to the connector 607. For example, when the communication module 621 receives an alarm notification from the port # 2 of the subordinate rack 701 connected to the connector 605, the communication module 621 adds a predetermined number of 10 and receives the alarm notification from the port # 12. This is notified to the control unit 611. Similarly, when an alarm is received from the port # 3 of the subordinate rack 701 connected to the connector 606, the communication module 621 adds 20 which is a predetermined number set in the connector 606, and alarms from the port # 23. This is notified to the control unit 611 as having been received. In addition, you may comprise so that a user can set the predetermined number allocated to each of the connectors 605-607. For example, a digital switch may be provided in the vicinity of each of the connectors 605 to 607 so that the user can make settings.

  According to the above configuration, the ports 602 of the main rack 601 are # 1, # 2, and # 3 in order from the top, and the ports 702 of the subordinate rack 701 connected to the connector 605 are # 11 and # 12 in order from the top. , # 13. Further, the ports 702 of the subordinate rack 701 connected to the connector 606 are # 21, # 22, and # 23 in order from the top. Therefore, by connecting the subordinate rack 701 arranged immediately below the main rack 601 to the connector 605 and connecting the subordinate rack arranged below it to the connector 606, the port numbers can be increased in order from the top. . As a result, by applying the processing described in the first embodiment (the flowchart in FIG. 4), the medical pump in which the alarm has occurred can be configured to be indicated by the display unit of another medical pump. In FIG. 7A, the state of the direction display in each medical pump when the alarm notification is output from the medical pump of the fifth port from the top (port number is treated as # 13 in this example) is shown. It is shown.

The medical pump system in which the main rack 601 and the subordinate rack 701 are arranged in the vertical direction has been described above. However, by devising a predetermined number to be assigned to the connectors 606 to 607, it becomes possible to deal with a two-dimensional rack arrangement as shown in FIG. FIG. 9 is a diagram for explaining a configuration in which the main rack 601 and the subordinate rack 701 can be connected vertically and horizontally. For example, 3 is assigned to the connector 605 as a predetermined value to be added, 10 is assigned to the connector 606, and 13 is assigned to the connector 607. And as shown in FIG.
The subordinate rack 701 connected to the connector 605 is directly below the main rack 601
A slave rack 701 connected to the connector 606 is located on the right side of the main rack 601
The slave rack 701 connected to the connector 607 is placed diagonally to the lower right of the main rack 601.
Place each one.

  With this configuration, the port numbers in the right column in FIG. 7B are # 1 to # 6 from the top, and the port numbers in the left column are # 11 to # 16 from the top. And the number indicating the left digit and column of the port number to which the predetermined value is added in this way (if the port number is 1 digit, the left digit is treated as 0), the right digit from the top in the column If it is set as a port position, the two-dimensional arrangement | positioning of a medical pump as shown in FIG. 6 and the allocation of a port number are implement | achieved. Although the column number starts from 1 in FIG. 6 and starts from column number 0 in the example of FIG. 9, this difference does not cause any trouble in determining the positional relationship by port number. Will be apparent to those skilled in the art.

  The arrangement of the main rack and the subordinate rack described above is merely an example, and the main rack may be arranged below, for example. In addition, the number of pumps mounted in each rack is limited to three, but is not limited to this. However, if the added values assigned to the connectors 605 to 607 are 10, 20, and 30 as described above, the maximum number of pumps installed in each subordinate rack is 10. As shown in FIG. 9, when the predetermined number to be added is 3, 10, and 13, up to three racks can be connected.

  In the second embodiment, the main rack 601 is connected to the subordinate rack 701 that does not have the control unit 611 or the like. However, the present invention is not limited to this. If the main rack 601 can be switched between master and slave, a plurality of the same racks 601 can be linked. For example, if the main rack 601 is provided with a main / slave selector switch and the control unit 611 controls the communication module 621 so that the main rack 601 functions as the main rack 601 when the main is selected and the sub rack 701 when the sub is selected. Good. When functioning as a subordinate rack, for example, the connector 605 is used instead of the connector 703. In this way, since the intelligent main rack 601 can function as a master and a slave, the medical pump system can be changed more flexibly.

  As described above, according to the second embodiment, similarly to the first embodiment, it is possible to indicate the mounting position of the medical pump generating the alarm from another medical pump. Therefore, the user can easily identify the medical pump in which the alarm has occurred from the display of the medical pump mounted on the rack, and can quickly respond to the alarm. Moreover, since it was set as the structure which can connect several racks, the number of racks can be changed according to the scale of a system, and a medical pump system can be constructed | assembled flexibly.

101: Medical pump mounting rack, 102 to 107: Port, 201: Medical pump, 202: Display unit, 111, 204: Communication module, 121: Control unit, 203: Connector, 205: Pump control unit, 206: Sending Liquid mechanism

Claims (8)

A medical pump system in which a plurality of medical pumps are mounted on a rack,
The rack is
Communication means for communicating with a plurality of medical pumps mounted;
When an alarm notification is received from any of the plurality of medical pumps via the communication unit, a determination unit that determines a mounting position of the medical pump that has transmitted the alarm notification in the rack;
The direction display to be displayed on each of the other medical pumps is determined so as to indicate the mounting position determined by the determination unit from each of the medical pumps other than the medical pump that has generated the alarm notification. A decision means to
A medical pump comprising: a transmission unit that transmits an instruction for displaying the direction display determined by the determination unit to each of the other medical pumps via the communication unit. system. The communication means has a plurality of ports provided corresponding to each of a plurality of pump mounting positions in the rack,
The said determination means determines the mounting position in the said rack of the pump which has generate | occur | produced the said alarm based on from which of the some ports the said alarm notification was received. Medical pump system.   The determining means sets an arrow in a direction from the mounting position of each of the other medical pumps in the rack to the mounting position of the medical pump generating the alarm notification, for each of the other medical pumps. The medical pump system according to claim 1, wherein the medical pump system is determined as a direction indication.   The determination means has an arrow closest to a direction from a mounting position of each of the other pumps to a mounting position of the medical pump generating the alarm notification, from among a plurality of arrows corresponding to different directions. The medical pump system according to claim 3, wherein a direction indication to be displayed by each of the other pumps is determined.   When the determination unit determines a plurality of mounting positions and it is necessary to indicate a plurality of directions corresponding to the plurality of mounting positions from one medical pump, the determination unit determines the one medical pump. The medical pump system according to claim 1, wherein the direction display to be displayed is determined to be a direction display indicating the plurality of directions.   The direction indication indicating the plurality of directions is an alternate display of a plurality of direction indications corresponding to the plurality of directions on the one medical pump, or a direction indication capable of simultaneously indicating the plurality of directions. The medical pump system according to claim 5. Each of the racks has a configuration in which a main rack and a subordinate rack each capable of mounting a predetermined number of pumps are connected,
The determination means, the determination means, and the transmission means are provided in the main rack,
The communication means includes
A plurality of ports provided in the main rack for communicating with a medical pump;
A plurality of ports provided in the slave rack for communicating with a medical pump;
The medical pump system according to claim 1, further comprising connection means for connecting each signal line of the plurality of ports of the subordinate rack to the main rack. A medical pump mounting rack capable of mounting a plurality of medical pumps,
Communication means for communicating with a plurality of medical pumps mounted;
When an alarm notification is received from any of the plurality of medical pumps via the communication unit, a determination unit that determines a mounting position of the medical pump that has transmitted the alarm notification in the rack;
The direction display to be displayed on each of the other medical pumps is determined so as to indicate the mounting position determined by the determination unit from each of the medical pumps other than the medical pump that has generated the alarm notification. A decision means to
A medical pump comprising: a transmission unit that transmits an instruction for displaying the direction display determined by the determination unit to each of the other medical pumps via the communication unit. Mounting rack.

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