KR100863628B1 - Re-certification system for a flow control apparatus - Google Patents

Abstract

A flow control device 10 configured to load a recertification feed set 14 is disclosed. The flow control device 10 includes a sensor 30 for sensing the loading of the recertification feed set 14 into the flow control device 10 and at least one component of the flow control device 10 is within a predetermined operating range. It includes a software subsystem 36 that includes a recertification procedure to verify that it operates at and is operatively connected to the sensor 30. Also disclosed is a method of verifying that at least one component of the flow control device 10 operates within a predetermined operating range.

Sensor, flow control unit, software subsystem, recertification supply set, no identification

Description

 RE-CERTIFICATION SYSTEM FOR A FLOW CONTROL APPARATUS}

The present invention relates to a flow control device suitable for loading in a re-certification feeding set.

Administration of fluids containing drugs or foods to patients is generally known in the art. Typically, the fluid is delivered to the patient by a recertified supply set loaded on a flow control device such as a pump connected to a source of fluid that delivers the fluid to the patient at a controlled delivery rate. However, there is a need in the art for an improved flow control device having a recertification procedure that verifies that at least one component of the flow control device operates within a given operating range.

The present invention includes a flow control device configured to load with a recertification feed set, a sensor for sensing loading of the recertification feed set into the flow control device, and a software subsystem operatively connected to the sensor, wherein The software subsystem relates to a flow control device comprising a recertification procedure capable of verifying that at least one component of the flow control device operates within a predetermined operating range.

The invention also includes a flow control device configured to load with a recertification feed set, a sensor for sensing loading of the recertification feed set into the flow control device, and a software subsystem operatively connected to the sensor, The software subsystem relates to a flow control device that initiates a recertification procedure when the sensor detects that the recertification supply set is loaded into the flow control device.

The invention also relates to a method of verifying that at least one component of a flow control device operates within a predetermined operating range, the method comprising loading a recertification feed set into the flow control device, the recertification Detecting that the supply set is loaded into the flow control device and initiating a recertification procedure verifying that at least one component of the flow control device operates within a predetermined operating range.

1 is a perspective view of an exemplary flow control device in accordance with the present invention.

2 is a side view of a flow control device loaded with a recertification feed set according to the present invention.

3 is a schematic block diagram illustrating elements of a flow control device according to the present invention.

4 is a flowchart of a recertification procedure according to the present invention.

4A is a subroutine of the flowchart shown in FIG. 4 in accordance with the present invention.

4B is another subroutine of the flowchart shown in FIG. 4 in accordance with the present invention.

Figures 5A-5I show a sequence of screens shown to a user by a flow control device that activates a recertification process according to the present invention.

Referring to the drawings, an embodiment of a flow control device according to the present invention is shown, which is indicated generally at 10 in FIGS. The flow control device 10 can verify that at least one component of the flow control device 10 operates within a predetermined operating range when the recertification feed set 14 is loaded into the flow control device 10. Include recertification procedures in place. The recertification feed set 14 includes a mounting member 74 and a valve mechanism for loading the recertification feed set 14 into the flow control device 10 for driving fluid through the tube 56 for delivery to a patient. And tube 56 coupled to 28. As used herein, the term loading refers to the valve mechanism 28 and the mounting member 74 coupled to the flow control device 10 and the tube 56 between the valve mechanism 28 and the mounting member 74. In the extended state, it means that the recertification feed set 14 is ready for operation with the flow control device 10.

1 and 2, an exemplary flow control device 10 according to the present invention includes a housing 20 configured to load a recertified feed set 14 into the flow control device 10. The flow control device 10 comprises a main recess 21 covered by the main door 136 and for providing a site configured to load the recertified feed set 14 into the flow control device 10. First and second recesses 58, 60. Preferably, the fluid drive means, such as the rotor 26, is rotatably coupled through the housing 20 and the first and the first when the valve mechanism 28 and the mounting member 74 are coupled to the flow control device 10. It is configured to engage the tube 56 such that the tube 56 is in an extended state between the two recesses 58, 60.

As used herein, a portion of the tube 56 of the recertification feed set 14 leading to the rotor 26 is referred to as upstream, and a portion of the tube 56 leading away from the rotor 26 is downstream. Is referred to. Thus, rotation of the rotor 26 provides a means to compress the tube 56 and drive fluid from upstream to downstream of the recertification feed set 14 for delivery to the patient. It is contemplated that the present invention can be used with any flow control device having fluid drive means such as linear peristaltic pumps, bellows pumps, turbine pumps, rotary peristaltic pumps and displacement pumps.

Referring to FIG. 1, the flow control device 10 further includes a user interface 40 that assists the user in operatively interface to the flow control device 10. Display 70 operatively connected with a plurality of buttons 138 positioned along overlay 66 provides the user with means to interact with microprocessor 62 to perform the recertification procedure of the present invention.

According to another aspect of the invention, the software subsystem 36 is configured to operate at least one component of the flow control device once the recertification feed set 14 (FIG. 3) is mounted to the flow control device 10. Perform recertification procedures to verify that they work within range.

The recertification feed set 14 is attached with one or more identification members 76 that indicate to the microprocessor 62 that the recertification feed set 14 has a recertification configuration when sensed by the flow control device 10. Mounting member 74. Once the user loads the recertification feed set 14 into the flow control device 10, the sensor 30 is moved to the second recess due to the position of the one or more identification members 76 attached to the mounting member 74. The software subsystem 36 detects the presence of a mounting member 74 coupled to 60 to initiate a recertification procedure that verifies that at least one component of the flow control device 10 operates within a predetermined operating range. Signal). Preferably, the identification member 76 is a magnetic component or alternatively a magnetic sensitive metal component that can be sensed by the sensor 30 without direct physical contact with the sensor 30. The sensor 30 is preferably configured so that the sensor 30 can detect the presence of one or more identification members 76 when the Hall effect sensor or the mounting member 74 is coupled to the second recess 60. Another type of adjacent sensor located near the recess 60.

Referring to FIG. 3, the software subsystem 36 may perform various manual and automatic tests related to verifying that at least one component of the flow control device 10 operates within a predetermined operating range. Let) perform. For example, components of the flow control device 10 that can be tested during the recertification procedure include LED light source 86, which is a component of the visual system, user interface 40, sensor 30, which is a component of the electronic system, It may be a rotor 26, a valve mechanism 28, a single motor source 44 and a gear arrangement 34, which are parts of a mechanical system. In operation, the user loads the recertification feed set 14 into the flow control device 10 in the manner as shown in FIG. 2 and described above to initiate the recertification procedure.

Once the mounting member 74 is coupled to the second recess 60 and the presence of the mounting member 74 is detected by the sensor 30, the software subsystem 36 is at least one of the flow control device 10. A recertification procedure is disclosed that causes the microprocessor 62 to verify that a component of U is operating within a predetermined operating range.

As shown in Figures 5A-5I, the user is instructed to follow a sequence of screens displayed on the user interface 40 that controls the recertification procedure. Moreover, the software subsystem 36 may be equipped with a recertified supply set to evaluate the performance of the components of the flow control device 10 that are related to the ability to drive fluid through the supply set 14 by the flow control device 10. 14) an automatic test to operate the rotor 26 to drive a volume of fluid and a manual test to verify that any component is operating properly. After this test has been successfully performed, the user interface 40 is provided with a determination as to whether the component tested by the flow control device 10 operates within a predetermined operating range.

The software subsystem 36 operably connected with the microprocessor 62 determines through a series of decision points and steps as to whether at least one component of the flow control device 10 operates within a predetermined operating range. .

4, 4A, and 4B, various decision points and steps executed by the software subsystem 36 under recertification processing are shown. The software subsystem 36 causes the flow control device 10 to initiate the recertification procedure when the recertification supply set 14 is loaded into the flow control device 10.

In step 302, the software subsystem 36 is configured to determine whether a preliminary automatic and manual test has been recently performed on the flow control device 10 to determine whether the component is operating within a predetermined operating range. 134). After this determination is made, the software subsystem 36 determines that the recertification feed set 14 is loaded into the flow control device 10 and the mounting member 74 is connected to the second recess 60 at the determination time 304. It determines whether it is sensed by the sensor 30 when combined. If the recertification feed set 14 is not detected, then at step 306 the software subsystem again determines whether manual and automated tests have been performed.

In step 308, if no manual and automatic tests were performed, the user interface 40 displays a screen 400 that instructs the user to load the recertification supply set 14 into the flow control device 10. (Figure 5a). In step 310, the user loads the recertification supply set 14 in the same manner as described above for the recertification supply set 14. If both automatic and manual tests are performed as determined at decision point 306, then software subsystem 36 instructs flow control device 10 to enter normal operation at step 312.

If at decision time 304 it is determined that the recertification supply set 14 is loaded, at decision time 316 the software subsystem 36 determines that the recertification supply set 14 is connected to the flow control device 10. Double check that it is actually loaded. If the recertification feed set 14 is not loaded, the screen 400 (FIG. 5A) again instructs the user to load the recertification feed set 14 into the flow control device 10 at step 318. Is displayed. In step 320 the user loads the recertification supply set 14 as indicated. Once step 320 is complete, at step 322 a screen 402 (FIG. 5B) is displayed to the user displaying the main screen to perform a manual test according to the present invention.

At decision time 324, software subsystem 36 determines whether manual testing has been performed. Otherwise, in step 326 the button 510 for initiating the automatic test is hidden and unavailable and the software subsystem 36 proceeds to step 328. If a manual test was performed, then in step 328 a repetition processing subroutine B is executed in step 331, where the user executes buttons 500, 502, 506, 508 on screen 402. It is instructed to perform various manual tests to verify that the tested components of the flow control device 10 operate within a predetermined operating range. This manual test verifies that the battery, LED light display, acoustic system, which is an acoustic system, and the sensor operate within a predetermined operating range, as described in detail below.

Referring to FIG. 4B, the user interface 40 is presented to the user in order to perform the same test as well as the various decision points and steps executed by the software subsystem 36 when performing various manual tests under subroutine B. The various screens and buttons provided are shown. In step 600, a user may have a buzzer test screen 404 that provides a means for verifying that a buzzer (not shown) or other acoustic system of the flow control device 10 is operating within a predetermined operating range. Button 500 is selected on screen 402 (FIG. 5B) displaying (FIG. 5C) in step 602. FIG. The buzzer is then activated in 604 to be heard by the user. At decision time 606, the user is queried whether a buzzer has been heard and then the user presses a button 514 indicating YES or a button 516 indicating NO or NOT SURE. Press When the user presses button 514 in step 608, software subsystem 36 verifies that button 514 is functional and also confirms the buzzer's recertification. If button 516 is pressed, in step 330 the software subsystem 36 determines whether all manual tests have been performed and passed through step 330. If the software subsystem 36 enters step 330, the repetition process 331 proceeds to perform another manual test under subroutine B because another manual test has already been performed.

In step 610, if the user selects the button 502 on the screen 402, an LED task screen provides a means for verifying that the LED light source 86 on the user interface 40 operates within a predetermined operating range. 406 (FIG. 5D) is indicated at step 612. Microprocessor 62 has LED light 86 cycles through red, yellow, and green LED light sources 86 in step 614. At decision time 616 the user is inquired about whether the LED light source 86 is actually circulated and the user presses a button 520 indicating yes or a button 522 indicating no. If the user presses the button 520, in step 618 the software subsystem 36 verifies that the button 520 is operable and also reconfirms that the LED light source 86 is operating within a predetermined operating range. However, if the user presses the button 522, then in step 330 the software subsystem 36 enters the repetition process 331 to perform another manual test under the subroutine B.

In step 622, if the user selects the button 506 on the screen 402, the user is provided with step-by-step instructions to perform a battery test on a battery (not shown) that powers the flow control device 10. Providing screen 408 (FIG. 5E) is displayed at step 624. This step-by-step instruction instructs the user to disconnect AC power to the flow control device 10, which dims the LED light source 86. At decision time 626, software subsystem 36 determines whether the battery is at the end of its life or is in a minimum or critical state of charge based on a predetermined value stored in database 134. If the battery is at end of life or at a minimum or critical charge state, then at step 632 the software subsystem 36 activates an alarm. After the alarm is activated, the user is instructed to reconnect AC power to flow control device 10 at step 628. However, if the battery has not reached its end of life or is at a minimum or critical state of charge, the software subsystem 36 enters the repetition process 331 to perform another manual test at step 328.

In step 634, if the user selects the button 508 on the screen 402, the sensor 30 may detect that the recertification supply set 14 is loaded into the second recess 60. Screen 410 (FIG. 5F) is shown in step 636 to perform a manual test to verify the presence of the sensor and to instruct the user to specifically detect the engagement of the mounting member 74 into the second recess 60. FIG. Screen 410 instructs the user to remove recertification feed set 14 from flow control device 10 in step 638. Once sensor 30 detects removal of recertification feed set 14 from flow control device 10, the buzzer sounds in step 640 by software subsystem 36. In step 642 the user reloads the recertification feed set 14A into the flow control device 10 as described above. Once the recertification feed set 14A is loaded, the software subsystem 36 activates the buzzer and verifies that the sensor 30 can detect the engagement of the mounting member 74 into the second recess 60. And verify that button 508 is working. A button 530 is provided on screen 410 to cancel this process if the user desires.

Once it has been verified that all manual tests have been performed at decision point 330, software subsystem 36 displays button 510 at step 332 and prompts the user for subroutine C at step 334. Button 510 may be actuated on screen 402 to allow automatic testing to be initiated during execution.

In step 334 the automatic test is performed under subroutine (C). The user first selects at least one part of the flow control device 10 involved in driving the fluid through the recertification supply set 14, such as the rotor 26, the gear arrangement 34, and the single motor source 44. Press button 510 on screen 402 to initiate an automated test that provides a recertification procedure to verify that it operates within its operating range. A screen 412 (FIG. 5G) is shown to the user displaying a “in progress” message to the user indicating that automatic testing is performed by the software subsystem 36 in step 702. Once the automated test is initiated, the software subsystem 36 determines at decision time 704 whether the automated test was successful.

If the automatic test is unsuccessful, in step 706 the software subsystem 36 sends test data to an external computer (not shown) via a serial port (not shown) of the flow control device 10. Send it. In step 708 the software subsystem 36 displays a "Recertification Failed" message to the user on screen 416 (FIG. 5I). After this message is displayed, in step 716 the user cuts off power to flow control device 10 by pressing button 532 to complete subroutine C.

If the automatic test is successful, at step 710 the software subsystem 36 stores the automatic test results in the database 134. Once the automated test results are stored, in step 712 the software subsystem 36 sends test data to the external computer via the serial port of the flow control device 10.

After completion, a screen 414 (FIG. 5H) is shown to the user displaying a " recertification complete " message to the user at step 714. Then, in step 716, the software subsystem 36 instructs the user to cut off the power of the flow control device 10 to terminate the procedure of the recertification system 12 according to the present invention.

While specific embodiments of the present invention have been shown and described, it should be understood from the above that various modifications may be made without departing from the spirit and scope of the invention as would be apparent to those skilled in the art.

Claims (9)

Flow control device 10, a) a flow control device 10 configured to be loaded with a recertification supply set 14, b) a sensor 30 for sensing the loading of the recertification feed set 14 into the flow control device 10, c) a software subsystem 36 operatively connected with the sensor 30, The software subsystem (36) includes a recertification procedure that can verify that at least one component of the flow control device (10) operates within a predetermined operating range. 2. The software subsystem 36 according to claim 1, wherein the software subsystem 36 initiates the recertification procedure when it is sensed by the sensor 30 that the recertification supply set 14 is loaded into the flow control device 10. Flow control device. The flow control device of claim 1, wherein the recertification supply set (14) is in circulation with a fluid. 3. Flow control apparatus according to claim 2, wherein the recertification supply set (14) comprises a mounting member (74). 5. Flow control apparatus according to claim 4, wherein the mounting member (74) comprises one or more identification members (76). Flow control device 10, a) a flow control device 10 configured to be loaded with a recertification supply set 14, b) a sensor 30 for sensing the loading of the recertification feed set 14 into the flow control device 10, c) a software subsystem 36 operatively connected with the sensor 30, The software subsystem (36) initiates a recertification procedure when the sensor (30) detects that the recertification supply set (14) is loaded into the flow control device (10). A method of verifying that at least one component of the flow control device 10 operates within a predetermined operating range, a) loading the recertification feed set 14 into the flow control device 10, b) detecting that the recertification supply set 14 is loaded into the flow control device 10, c) using a software subsystem (36) comprising a recertification procedure capable of verifying that at least one component of the flow control device (10) operates within a predetermined operating range. 8. The method of claim 7, wherein said at least one component is selected from the group consisting of an audio, visual, mechanical and electronic system. 8. The method of claim 7, wherein said recertification supply set (14) further comprises a mounting member (74), said mounting member (74) being sensed.

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