JPH03244468A - Transfused liquid monitoring device - Google Patents

Abstract

PURPOSE:To adjust precisely the rate of flow in a short measuring time by calculating the weight of transfusion liquid par unitary number of drops from the weight change amount of the liquid measured by a weight measuring means and the number of drops counted by a counting means. CONSTITUTION:A transfusion liquid monitoring device concerned includes a counting means 1, weight measuring means 2, calculating means 3, display means 4, and operating means 5, and computes the rate of flow through calculation of the liquid weight per unitary number of drops, for example the weight of one drop, from the weight change amount of the liquid measured by the mentioned weight measuring means 2 and the number of drops counted by the counting means 1. This means 1 counts the drops in dripping as supplied by a liquid vessel, wherein the measuring is made by a photo-sensor 7 which senses that each drop 8 falling blocks the beam of light given by a light emitting diode 6, and a passage signal is fed to the calculating means 3 every time a drop passes. The weight measuring means 2 measures the weight of the transfusion liquid and the vessel filled therewith. Thus, the weight of each drop is calculated from the weight change and the number of drops.

Description

[Detailed description of the invention] [Industrial application field]

The present invention relates to an infusion monitoring device used for injecting nutritional supplements and drugs such as parenteral nutrition and enteral nutrition into patients, and in particular, to accurately measure the weight of each infusion drop. This allows for an infusion monitoring device that can accurately measure the amount injected.

[Conventional technology]

When injecting an infusion into a patient, the optimal injection volume is determined depending on the patient's health condition and the type of infusion. Various infusion monitoring devices have been developed to accurately inject the amount of infusion. For example, a drip monitoring device is described in the following publication. ■ JP-A-60-114269 ■ JP-A-54-35035 ■ JP-A-59-71 ■ JP-A-56-140211 ■ JP-A-59-166816 Disclosed in these publications Infusion monitoring devices can be broadly divided into:
There are two types of methods: those that detect changes in weight and those that count the number of drips. The infusion monitoring device shown in the publications ① and ② measures changes in weight. The infusion monitoring device shown in the publication No. 3 suspends an infusion container using a spring. When the amount of infusion filled in the container decreases and becomes lighter, the infusion container is lifted by the spring. The rise of the container is detected by a sensor. A sensor detects the rise of the container and sounds a chime. This device is configured to sound an alarm with a chime when the infusion is drained from the container and becomes lighter. In the infusion monitoring device described in the publication No. 2, the infusion container is suspended from the lower end of a spring, and the upper end of the spring is wound around the winding shaft of the motor. This device is configured to monitor the state of the infusion and issue an alarm when a predetermined infusion volume is reached or when the infusion is stopped due to some accident. Furthermore, the publications (1), (2), and (2) describe devices for counting the number of infusions. The device described in the publication (2) is equipped with photoelectric means for counting the number of infusions. The photoelectric means counts and converts the number of infusions into the amount of infusion and displays it. Furthermore, the device disclosed in Publication (2) also detects the number of infusions using a photodetector. The drip flow rate for one minute is displayed based on the detected number of drips. Furthermore, the device shown in the publication No. 2 is equipped with means for measuring the size of infusions in addition to the number of infusions. In other words, this device drops a droplet between a light source and a phototransistor, measures the time it takes for the droplet to block light, and
Measuring the size of the drip.

[Problem to be solved by the invention]

As described above, devices have been developed that monitor the status of infusion by counting the weight or the number of infusions, but these devices have the drawback of not being able to accurately measure the infusion flow rate in a short period of time. . In other words, a device that measures changes in weight can detect when an infusion is complete;
The disadvantage is that it is difficult to accurately adjust the flow rate in a short measurement time. This is because the weight change is extremely small. For example, suppose you measure the flow rate by measuring the change in weight over one minute, and find that the flow rate is twice the set value. Suppose that the flow rate is adjusted to a lower level by squeezing the accessible tube through which the infusion drops. One more step to measure the adjusted flow rate
It takes minutes. If the flow rate cannot be adjusted to an appropriate value through this adjustment, it is necessary to further adjust the degree of constriction of the accessible tube and measure the flow rate over a period of one minute. Therefore, with this method, it is not possible to accurately adjust the flow rate in a short period of time. The method of counting the number of drips falling allows flow rate adjustments to be made in a short time. This is because the time interval during which the drip falls is a function of the flow rate. For example, if the time interval between drip drops is halved, the flow rate will double. Therefore, the flow rate can be calculated by measuring the closure of the drip when it falls. However, the flow rate is not only a function of the number of drips that fall, but also the weight of each drip. As the weight of one drop increases, the flow rate increases even if the number of drips falling is the same. Therefore, a variation in the weight of one drop results in an error in the flow rate. In order to reduce this error, the device described in Publication (2) measures the diameter of the infusion. The weight of the drip is calculated from the diameter. However, this structure has the disadvantage that the shape of the falling drip causes errors, and errors occur depending on the type of infusion. Furthermore, when converting diameter to weight, it is necessary to apply a different coefficient depending on the type of infusion. This invention was developed with the aim of solving these drawbacks of conventional infusion monitoring devices, and an important objective of this invention is to shorten the flow rate adjustment time and to be able to accurately adjust the flow rate. To provide infusion monitoring devices.

[Means to solve the problem]

The infusion monitoring device of the present invention has the following configuration in order to achieve the above-mentioned object. That is, the infusion monitoring device of the present invention includes a counting means for counting the number of drips supplied from the infusion container;
This is an improved device equipped with calculation means for calculating the amount of dripped infusion based on the signal from the counting means. The infusion monitoring device of the present invention includes, in addition to the counting means, a weight measuring means for detecting the weight of the infusion. Also,
The calculating means is configured to calculate the weight of the infusion per unit number of drips from the weight change amount of the infusion measured by the weight measuring means and the number of drops counted by the counting means. Furthermore, the infusion monitoring device of the present invention includes an improvement of the device including a flow rate control means for controlling the drip flow rate under the control of the calculation means. The infusion monitoring device equipped with a flow rate control means includes a calculation means that calculates the weight of the infusion per unit number of drops from the amount of change in the weight of the infusion measured by the weight measurement means and the number of drops counted by the counting means, and further The flow rate control means is configured to calculate the flow rate from the interval of dripping time of the drip detected by the counting means, and to control the drip flow rate so that the calculated flow rate becomes a set flow rate.

[effect]

The infusion monitoring device of the present invention calculates the flow rate of infusion under the following conditions. ■ Weight measuring means measures the change in weight of the infusion over a certain period of time. ■ A counting means measures the number of drops of infusion in a certain period of time. (2) The calculation means calculates the weight of one drop by dividing the weight change by the number of infusion drops. (2) The calculating means calculates the flow rate from the interval of dripping time of the drip detected by the counting means. (2) Furthermore, if necessary, the flow rate control means adjusts the flow rate of the infusion solution to a set value based on the calculation result of the calculation means. In this way, the infusion monitoring device of the present invention calculates the weight of one infusion from the weight change and the number of drops. For this reason,
The weight of a single drop can be determined very accurately. It takes some time to measure the weight of one drop. However, the fact that this measurement takes some time hardly prolongs the time for adjusting the flow rate. This is because the weight of one drop needs to be measured only once. After adjusting the flow rate, the flow rate can be calculated immediately from the dripping time of the drip. That is, after adjusting the flow rate, it is possible to accurately know the changed flow rate simply by measuring the time interval during which the drip is dripped. Therefore, the minimum time required to adjust the flow rate is the sum of the dripping time interval and calculation time.For example, if the drip is dripped at 1 second intervals, the time required to measure the flow rate is:
The dropping interval of 1 second is an extremely short computation time that can be ignored. In order to measure the flow rate more accurately, it is sufficient to drip several drops and take the average of the dripping times, but even in this case, the flow rate can be accurately determined by measuring in an extremely short period of time. Furthermore, the infusion monitoring device equipped with the flow rate control means according to the present invention has the advantage that it can be used more conveniently because the flow rate control means adjusts the flow rate of the infusion injected into the patient to a set value. Furthermore, since the flow rate control means can quickly control the flow rate, there is an advantage that the infusion can be injected at a set time extremely accurately. This is because, after calculating the weight of one drop, the flow rate can be calculated by measuring the interval of dripping time. The drip time interval can also be measured as the time it takes for two drops to fall. For this reason,
After the flow rate control means changes the injection flow rate, the changed flow rate can be measured in an extremely short period of time, and the changed flow rate can be compared with a set value for more accurate control. By the way, it is also possible to measure the flow rate based on the weight change of the weight measuring means and to control the flow rate control means based on the measured value. However, with this mechanism, precise flow control is extremely difficult. The reason is that it takes time to measure the flow rate. The reason why it takes time to measure the flow rate is that the change in weight per hour is extremely small. For example, the amount of change in the weight of the infusion after several seconds is usually within the measurement error range of the weight measuring means and cannot be measured accurately. In order to calculate the flow rate based on the weight change of the weight measuring means, time is required for the weight measuring means to accurately measure the change in the weight of the infusion. However, the infusion monitoring device of the present invention can accurately measure the flow rate without measuring changes in weight by simply measuring the time interval during which the infusion falls after measuring the weight of one drop. Therefore, the flow rate control means has the advantage of being able to quickly measure the flow rate after adjustment, and feeding back the measured value to the calculation means to adjust to a more accurate set value. FIG. 6 shows a graph in which an infusion was actually injected into a patient using the infusion monitoring device of the present invention and a conventional infusion monitoring device. Curve A uses the infusion monitoring device of the present invention; curve B;
C and D show characteristics using a conventional device. Curve B is a characteristic obtained by calculating the injection amount based on the falling time of the drip, and manually adjusting the flow rate control means every hour based on this calculation. Curve C is an example in which the flow rate control means is manually adjusted every hour based on the scale of the infusion container. Furthermore, the curved line is an example in which the falling flow rate was initially set and the flow rate was not adjusted thereafter. As shown by curve A, by using the infusion monitoring device of the present invention, accurate infusion was possible within the set time of 7 hours. However, this graph was measured under the following conditions. ■ For infusions, Tribalen No. 1 (600 mJl) [Ogaki Pharmaceutical] and Amibalen (300 mQ) [Ogaki Pharmaceutical],
A preparation of Otsuka MV Injection [Ogaki Pharmaceutical Co., Ltd.] was used. ■ The target injection time was 7 hours. (2) In the infusion monitoring device of the present invention, the flow rate control means is manually adjusted every hour to match the number of infusions indicated on the display device.

【Example】

Embodiments of the present invention will be described below based on the drawings. However, the embodiments shown below are illustrative of an infusion monitoring device for embodying the technical idea of the present invention, and the device of the present invention has the material, shape, structure, and arrangement of the component parts as described below. It is not specific to the structure. Various modifications may be made to the device of the present invention within the scope of the claims. The infusion monitoring device shown in FIGS. 1 and 2 includes a counting means 1, a weight measuring means 2, a calculating means 3, a display means 4, and an operating means 5. This infusion monitoring device calculates the weight of the infusion per unit number of drops, for example, the weight of one drop, based on the amount of change in the weight of the infusion measured by the weight measuring means 2 and the number of drops counted by the counting means 1. Calculate the flow rate. The counting means 1 counts the number of drips supplied from the infusion container. An example of the counting means l is shown in FIG. The counting means 1 shown in this figure includes a light emitting diode 6 and an optical sensor 7. The light emitting diode 6 is fixed so as to irradiate light toward the drip chamber 9 so as to irradiate the dripping path of the drip 8 with focused light. The optical sensor 7 is fixed to the surface facing the light emitting diode 6 so as to receive light emitted from the light emitting diode 6. This counting means 1 uses an optical sensor 7 to detect and measure the fact that the falling drip 8 blocks the light from the light emitting diode 6. Therefore, the light emitting diode 6 continuously emits light. When there is no drip 8, the light emitting diode 6
The light is received by the optical sensor 7. However, when the intravenous drip 8 blocks the light, the light incident on the optical sensor 7 becomes weaker. Therefore, passage of the drip 8 can be detected when the incident light of the optical sensor 7 becomes below a certain level. However, in this invention, the drip counting means is not limited to the one shown in FIG. 3, and any means capable of counting the number of drips can be adopted. The counting means 1 manually inputs a passage signal to the calculation means 3 every time the infusion passes. However, the counting means can also convert the number of drips into an electrical signal and input it manually to the calculation means. For example, it is also possible to input a voltage signal proportional to the number of drips into the calculation means. In this case, the counting means transmits a voltage proportional to the number of drops falling in a certain period of time to the calculating means. The weight measuring means 2 measures the weight of the infusion and the container filled with the same. The weight measuring means 2 includes a hook 10 for hooking an infusion container. Although a mechanism for electrically detecting the amount of expansion and contraction of a spring can be used as the weight measurement means, a weight-to-electricity conversion element that converts mechanical strain into an electrical signal is most suitable. The weight measuring means 2 shown in FIG. 2 includes a lever 11 having a hook 10 at its tip, and a strain sensor 13 pressed by a pressing protrusion 12 provided in the middle of the lever 11. The rear end of the lever 11 is connected to the base via a rotating shaft so that the lever 11 can rotate in a vertical plane. Strain sensor-1
3 outputs an output signal proportional to the pressing force when pressed by the pressing protrusion 12 of the lever. In this weight measuring means 2, the pressing protrusion 12 presses the strain sensor 13 in proportion to the weight of the infusion container 14 hooked on the lever 11. Therefore, the strain sensor 13 inputs an output signal proportional to the weight of the infusion container 14 to the calculation means 3. In this state, the strain sensor 13, which outputs an output proportional to the weight, usually outputs an analog signal. When the calculation means 3 performs calculation processing on the digital signal, A/
A D-converter (not shown) is used to convert the analog signal of the weight measuring means into a digital signal. The A/D converter converts the output signal of the weight measurement means into a digital signal and inputs it to the calculation means. Incidentally, in this invention, the weight measuring means 2 is not limited to the above-mentioned one. As the weight measuring means, any device that accurately measures the weight of the container containing the infusion solution and outputs the measurement result as an electrical signal can be used. The calculating means 3 calculates the weight of one drop by calculating the signal from the weight measuring means 2 and the signal from the counting means 1. For example, when an infusion is injected into the body at a constant flow rate, (1) the counting means 1 counts 180 infusions in 3 minutes, and (2) the weight change detected by the weight measuring means 2 is 4.5 times in 3 minutes.
If it is 5g, the weight of one drop is 4.5g/180=0°025g
(25 mg). Further, the flow rate is 4.5/3=1.5 g/min. Furthermore, since there are 180 infusions in 3 minutes, the infusion time interval is 1 second. That is, since the weight of one drop of this infusion is 25 mg, the interval of the drop time of the infusion was changed from 1 second to 0.
If it is set to 5 seconds, the flow rate can be doubled to 9 g/min, and the infusion time can be halved. Also, if the falling time of the drip is changed from 1 second to 2 seconds, the flow rate will be 2.2 g/min, which is half of 4.5 g/min.
5 g/min, which doubles the infusion time. In this way, the calculating means 3 calculates the weight of one drop from the number of infusions in the set time and the change in weight of the infusion. Therefore, the calculation means 3 includes a memory for storing the number of drops sent from the counting means 1 during a certain period of time, a memory for storing the weight sent from the weight measuring means 2 for a certain period of time, It is equipped with a CPU that calculates the weight of one drop of infusion from the stored value in the memory. In this way, the calculation means 3 can be a microcomputer equipped with a CPU, a ROM that stores calculation formulas of the CPU, and a RAM that is a memory that stores input signals from the counting means and the weight measuring means. Further, the calculating means 3 measures the interval of dripping time from the signal inputted from the counting means 1. The interval of drip infusion time can be measured by the number of clock pulses. The rear clock pulse is oscillated by a timer. The period of the clock pulse is sufficiently short with respect to the dripping time of the infusion, for example, 0. It is set to 5 μsec to several tens of μsec. FIG. 4 shows a principle diagram of counting clock pulses to measure the interval of dripping time. As shown in this figure, if there are multiple clock pulses between the infusion pulses at which the counting means l detects the passage of the infusion, the number of clock pulses is proportional to the time interval of the infusion pulses.
For example, if there are 10,000 clock pulses between two infusion pulses, and the period of the clock pulse is 10 μs, the interval of drip fall time is 10 μs x 10,000=1 second. The calculation means 3 for realizing this includes a timer that oscillates clock pulses and a counter that counts the clock pulses between the drip passing signals inputted from the counting means 1. The calculation means 3 measures the weight of one drop at an initial fixed time, and thereafter measures the time interval during which the drop falls to calculate the flow rate. If you can measure the time interval between drips falling, you can find out how many drips fall in one minute. Once the number of drops per minute is known, multiplying the number of drops by the weight of one drop gives the injection flow rate per minute. It is easier to understand the flow rate when it is displayed as a flow rate per minute, 10 minutes, or per hour. To calculate the flow rate for 10 minutes, the number of drips falling in 10 minutes can be calculated backwards from the falling time of the drip, and the number of drops can be multiplied by the weight of one drip. Similarly, the flow rate for one hour can be calculated. The calculating means 3 calculates the flow rate per unit time from the interval of the falling time of the drip, and sends the result to the display means 4. The display means 4 displays the flow rate based on the calculation result of the calculation means 3. The calculating means 3 calculates the constant flow rate by calculating the input signal from the counting means 1, and sends the calculation result to the display means 4 for display. Therefore, the display means 4 continuously displays the flow rate injected into the body through the accessible tube 15. Adjusting the constriction of the accessible tube 15 changes the flow rate injected into the body. In this case as well, the display means 4
Continuously displays changing flow rate. Therefore, the nurse can accurately adjust the flow rate while looking at the display means 4. In addition to the flow rate, the display means 4 of the device shown in FIGS. 1 and 2 displays: ■ Remaining volume of infusion ■ Dosage amount ■ Appropriate amount of drip per minute ■ Current number of drops per minute ■ Remaining time There is. As described above, an infusion monitoring device that displays the proper drip amount and the current drip amount has the advantage of being particularly convenient to use. This is because this type of infusion monitoring device often infuses an infusion into a patient by determining the infusion time rather than the flow rate of the infusion. The appropriate amount of infusion per minute can be calculated from the total amount of infusion, infusion time, and weight of one drop. For example, assume that the total amount of infusion is 720 g, which is to be infused over 6 hours. In this case, if the flow rate per minute is set to 2g, the flow rate will be 720g at 6 o'clock. First, the infusion fluid is supplied at an appropriate flow rate and the weight of one drop is calculated. Assume that the calculated weight of one drop is 25 mg. 80 25 mg infusions equal 2g, so if 80 infusions are injected in 1 minute, 2g1 in 1 minute.
This means that 720g of fluid can be injected at 6 o'clock. This calculation can be processed by the calculation means 3. The infusion monitoring device shown in FIGS. 1 and 2 includes an operating means 5 to allow the calculating means 3 to calculate the appropriate drip amount. The operating means 5 includes a keyboard. The keyboard inputs the appropriate dripping time of the infusion into the calculation means 3. The calculation means 3 calculates the appropriate number of drops from the input injection time. When the calculating means 3 calculates the appropriate number of drops, the weight of the infusion can be input manually from the keyboard or from the weight measuring means 2. Further, the current dripping quantity per minute is calculated from the dripping time interval of the dripping and the dripping weight of one drop. That is, if the interval of dripping time is known from the signal from the counting means 1, the number of drops dripped in one minute can be determined. The number of infusions per minute can be calculated as follows: Number of infusions per minute = 60 seconds/interval of infusion time (seconds). For example, if the infusion time interval is 0.
In the case of 8 seconds, the number of drops per minute is 6070.8=75. In this way, the number of infusions actually injected into the patient is calculated by the calculating means 3 based on the input signal from the counting means 1 and displayed on the display means 4. By adjusting the number of drops while watching this display so that the current number of drops becomes the appropriate number, the infusion can be injected in an appropriate time. Furthermore, the remaining amount of infusion can be calculated by subtracting the dose from the infusion weight entered manually from the keyboard. The remaining amount of infusion fluid is calculated by calculation means 3. The dose of the infusion can be calculated by subtracting the current infusion weight from the initial infusion weight. Therefore, the calculation means 3 calculates the remaining amount of the infusion from the signal from the weight measuring means 2 and the weight of the infusion entered from the keyboard, and sends the calculation result to the display means 4, which displays the result. Further, the dose can be displayed by subtracting the current infusion weight from the initial infusion weight. Therefore, the initial infusion weight is stored in the memory, the current weight is detected by the weight measuring means 2, and the difference can be displayed as the dose. This calculation can also be performed by the calculation means 3. Furthermore, the remaining time is calculated by the calculation means 3 from the remaining amount of infusion and the flow rate. That is, the remaining time can be calculated using the formula: remaining time=remaining amount of infusion/flow rate. The infusion monitoring device shown by the chain line in FIGS. 4 and 2 includes a flow rate control means 16 in addition to the device shown in FIG. The flow rate control means 16 is controlled by the calculation means 3 to control the amount of infusion. The flow control means 16 shown in this figure includes a servo motor 17 and a rod 18 that is connected to the servo motor 17 and presses a part of the accessible tube 15. The flow rate is controlled while the rod 18 presses the accessible tube 15. When the rod 18 strongly presses the accessible tube 15 and narrows the infusion passage in the accessible tube 15, the flow rate decreases. Conversely, when the rod 18 presses the accessible tube 15 weakly, the flow rate increases. rod 1
8 presses the accessible tube 15 under the control of a servo motor 17. The servo motor 17 is controlled by the calculation means 3. The calculation means 3 measures the actual flow rate using the method described above from the human input signals from the counting means 1 and the weight measuring means 2, and compares the measured value with the set value. When the measured flow rate is less than the set flow rate, the calculation means 3 drives the servo motor 17 to weaken the pressing force of the rod 18 on the accessible tube 15. On the other hand, if the measured flow rate is too much than the set flow rate, the servo motor 17 is driven so that the rod 18 strongly presses the accessible tube 15. The servo motor 17 is
It will stop after running for a certain period of time. After the servo motor 17 is stopped, the calculation means 3 measures the flow rate again from the interval of the dripping time of the drip, compares the measured flow rate with the set flow rate, and drives the servo motor 17 if the measured flow rate differs from the set flow rate. to adjust the flow rate. The calculation means 3 calculates the set flow rate from the total amount of infusion and the set injection time. In addition, since the infusion flow rate is a fraction of the interval of the dripping time of the infusion, the dripping time is detected instead of the infusion flow rate, and this measured dripping time is compared with the calculated appropriate dripping time. Needless to say, the servo motor 17 can also be driven.

[Brief explanation of drawings]

1 and 4 are front views of an infusion monitoring device showing an embodiment of the present invention, FIG. 2 is a block diagram of the infusion monitoring device shown in FIGS. 1 and 4, and FIG. 3 is a diagram of the counting means. A cross-sectional view showing an example, FIG. 5 is a graph showing the principle of measuring the interval of drip fall time from a clock pulse, and FIG. 6 is a state of actual infusion using the infusion monitoring device of the present invention and a conventional device. This is a graph showing. l...Counting means, 2...Weight measuring means, 3...Calculating means, 4...
Display means, 5... Operating means, 6...
・・Light-emitting diode, 7・・・・・Light sensor-8・
...Drip, 9...Drip chamber 0...Hook, 11...Lever 2...Press protrusion, 13... - Strain sensor - 4... Container, 15... Flexible tube, 6... Flow rate control means, 7... Servo motor 8... ··rod. Conflict iv 8'j;: Hishi diagram diagram ↓ diagram elapsed time

Claims (2)

[Claims] (1) In a device equipped with a counting means for counting the number of drips of infusion supplied from an infusion container, and a calculation means for calculating the amount of infusion dripped using a signal from this counting means, in addition to the counting means, It is equipped with a weight measuring means for detecting the weight, and is configured to calculate the weight of the infusion per unit number of drops from the amount of change in the weight of the infusion measured by the weight measuring means and the number of drops counted by the counting means. An infusion monitoring device characterized by: (2) A counting means for counting the number of drips of the infusion supplied from the infusion container, a calculation means for calculating the amount of dripping of the infusion based on the signal from the counting means, and a flow rate controlled by the calculation means to control the drip flow rate. In addition to the counting means, the device is equipped with a weight measuring means for detecting the weight of the infusion, and the amount of change in the weight of the infusion measured by the weight measuring means and the number of drops counted by the counting means. An infusion monitoring device characterized in that the calculation means is configured to calculate the weight of the infusion per unit number of drops, and the calculation means controls the flow rate control means to control the infusion flow rate.