JPH0422368A - Flow control device for transfused solution - Google Patents

Abstract

PURPOSE:To keep the rate of flow constant at all times by furnishing a rate--of-flow correcting means which performs correction in the direction of increasing the rate of flow in the rate-of-flow adjusting part, in case the temp. sensed by a temp. sensing part is higher than the reference temp., and which conducts a correction in the direction of decreasing the rate of flow in case the temp. is low. CONSTITUTION:A feedback control is performed so that the number of drops N becomes identical in the same manner as conventional on the basis of the post- correction reference number-of-drops N0c determined through a correction of the reference number of drops No. That is, the actual number of drops N within a certain specified time sensed by a drop sensor 4 is compared with the post-correction reference number N0c, and the adjusting amount (m) of a rate-of-flow adjusting device 5 is adjusted on the basis of this result of comparison (N0c-N). Thus control is made so that the number of drops N of transfusion liquid becomes identical to the post- correction reference number of drops N0c. Now the number of drops N in the dripping part 3 varies in proportion to the temp. T, and in case this temp. T differs from the reference temp. To, so the number of drops N differs from the reference number of drops No too, but the actual rate of transfusion liquid flow through a transfusion liquid tube 2 is kept always constant regardless of the temp. T.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to an infusion flow rate control device that controls the flow rate of an infusion during infusion or the like.

(Prior art) During infusion, etc., the infusion solution supplied from the drug solution bag is dripped in the middle of the infusion tube in the form of drops, and the flow rate of the infusion solution is adjusted so that the number of drops becomes a predetermined number. It's in control.

A conventional infusion flow rate control device that controls the flow rate based on the number of drops is shown in Figure 4.

The medicinal solution in the medicinal solution bag 1 is fed through an infusion tube 2 extending from the lower end, and is infused into the patient. The infusion tinib 2 is provided with a dripping part 3 for dropping the infusion into drops, and is also equipped with a dripping sensor 4 for detecting the number of drops of the infusion in the dripping part 3.

Further, below the dripping section 3, a flow rate adjustment device 5 is attached that clamps the infusion tube 2 to adjust the flow rate of the infusion flowing therethrough.

The dripping sensor 4 and the flow rate adjustment device 5 are connected to a control device 8 via an inter 7/8 6.7. The control device 8 is a computer device that performs control by the operation of the CPU 8a, and by inputting the number of drops of infusion detected by the dripping sensor 4 via the interface 6, the amount of adjustment of the flow rate in the flow rate adjustment device 5 is controlled by the interface 7. It is designed to be controlled via.

As shown in FIG. 5, the control amount [8 is determined by comparing the reference number Na of drops in a predetermined time unit set in advance with the actual number N of drops within a predetermined time detected by the drip sensor 4. Adjustment amount m of the flow rate adjustment device 5 based on the comparison result (N@-N)
By adjusting , feedback control is performed so that the number N of infusion drops matches the number N9 of drops per $1. Conventionally, the flow rate of the infusion solution has been controlled only by keeping the number N of drops per hour in the dripping section 3 constant.

(Problems to be Solved by the Invention) However, the volume of each droplet of the infusion solution dripped by the dripping section 3 decreases as the surface tension of the infusion solution decreases. The surface tension of this infusion decreases as the temperature increases. Therefore, even if the number of infusion drops in the dripping section 3 is controlled to be constant, the volume of each drop will change if the temperature changes, so the flow rate of the infusion flowing through the infusion tube 2 will not be constant.

For this reason, the conventional flow rate control device has a problem in that the flow rate of the infusion that actually flows through the infusion tube 2 changes depending on the temperature, and the flow rate cannot be accurately controlled.

In view of the above circumstances, the present invention detects the temperature of the infusion and corrects the control of the number of drops based on this temperature, so that even when the volume of drops to be dropped changes depending on the temperature,
The object of the present invention is to provide an infusion flow rate control device that can always maintain a constant flow rate.

(Means for Solving the Problems) The flow rate control device of the present invention includes a dripping part for this infusion and a flow rate adjusting part on the passage for the infusion, and detects the number of drops of the infusion per hour in the dripping part. An infusion flow rate control device that controls the flow rate of an infusion by adjusting the flow rate in a flow rate adjustment unit so that the number of drops matches a reference number of drops, the device comprising: a temperature detection unit that detects temperature; The temperature detected by the temperature detection unit is based on 71! If the temperature is higher than the temperature, the flow rate adjustment unit makes a correction in the direction of increasing the flow rate, and if the temperature is low, the flow rate correction means makes a correction in the direction of decreasing the flow rate, thereby achieving the above purpose. achieved.

(Function) In the above configuration, the temperature detection section is installed at a location where the temperature of the infusion can be directly or indirectly detected, for example by being attached to the infusion tinib. Then, based on the temperature detected by the temperature detection section, the flow rate correction means corrects the flow rate adjustment by the flow rate adjustment section. This correction is performed so that the flow rate of the infusion fluid increases when the temperature is high, and decreases when the temperature is low.

Note that the correction by this flow rate correction means is performed by, for example, the fifth
In addition to correcting the standard number of drops NO, which is the target value of the conventional control system in the figure, the number of drops N detected by the drop sensor 4 as a control variable, and the flow rate adjustment device as a deviation! 5 or the adjustment amount m adjusted by this flow rate adjustment device 5 as the manipulated variable.

As a result, according to the present invention, when the surface tension is reduced due to the high temperature of the infusion and the volume of each drop at the dripping portion is reduced, correction is performed in the direction of increasing the flow rate. Therefore, although the number of drops is greater than the standard number of drops, the actual flow rate of the infusion can be kept the same as at the reference temperature. Furthermore, even when the temperature of the infusion is low, the actual flow rate can be kept constant in the same way.

(Example) The invention will now be described with reference to examples.

An embodiment of the present invention is shown in Figs. 1 to 3.

Note that the same reference numerals are given to the structural members having the same functions as those of the conventional example shown in FIG.

The medicinal solution in the medicinal solution bag 1 is sent out through an infusion tinib 2 extending from the lower end, and is infused into the patient. In the middle of this infusion Chicove 2, there is a dripping part 3.
is provided, and the infusion solution is once dripped in the form of drops at this dripping part 3.

A dripping sensor 4 is attached to this dripping part 3. The dripping sensor 4 is composed of, for example, a transmission type optical sensor or the like, and is capable of detecting the number of drops of the infusion dripped by the dripping part 3. A flow rate adjustment device 5 is attached below this dripping section 3. The flow rate adjustment device 5 consists of a clamp part 5a and a motor 5b, and when the clamp part 5a driven by the motor 5b presses/releases the infusion tube 2 made of flexible synthetic resin,
The flow rate of the infusion flowing through this can be adjusted. The motor 5b is composed of, for example, a stepping motor, and can arbitrarily increase or decrease the amount of adjustment of the flow rate by the clamp part 5a by pulse input or the like, and can maintain the adjustment amount if no increase or decrease is necessary. .

Moreover, a temperature sensor 9 is attached above this dripping part 3. This temperature sensor 9 consists of a temperature sensing element such as a thermistor, thermocouple or semiconductor transducer,
The temperature of the infusion flowing through the infusion tube 2 can be detected. However, this temperature sensor 9 may be attached to any location as long as it can directly or indirectly detect the temperature of the infusion.

The dripping sensor 4, flow rate adjustment device 5, and temperature sensor 9 are as follows:
Each is connected to the control device 8 via an interface 6.7.10. The control device 8 includes a CPU 8a;
ROM8b connected to this CPU8a via a bus,
This is a combinator device consisting of a RAM 8c and an input/output device 8d.

Then, according to the program stored in ROM8b, C
By operating the PU 8a, based on the number of drops of infusion detected by the dripping sensor 4, the amount of adjustment of the flow rate in the flow rate adjustment device 5 is controlled so that this number of drops matches the reference number of drops. . At this time, based on the temperature detected by the temperature sensor 9, if this temperature is higher than the reference temperature, the adjustment amount of the flow rate adjustment device 5 is corrected in the direction of increasing the flow rate, and if the temperature is low, the adjustment amount of the flow rate adjustment device 5 is corrected in the direction of increasing the flow rate. Correction is made in the direction of decreasing flow rate. The reference number of drops and the reference temperature are values set in advance by the operator via the input/output device 8d, and are stored in the RAM 8C.

The control operation of the control device 8 will be explained in more detail based on FIG. 2. When the temperature T of the infusion is detected by the temperature sensor 9, a temperature difference ΔT having a positive or negative value is calculated from the difference between this temperature T and the reference temperature TO. Then, by multiplying this temperature difference ΔT by the correction coefficient S to obtain S・ΔT, and adding this to the standard number of drops Nll, the standard number of drops after correction N
Get i1o.

The correction coefficient S is set so that even if the volume of the infusion droplet in the dripping section 3 changes depending on the temperature, the same flow rate as when the standard number of drops NII is dripped every predetermined time at the standard temperature Ta is obtained. This is a coefficient for correcting the reference number of drops Na, and is stored in advance in the ROM 8t) or RAM 8c. Here, the temperature difference ΔT is multiplied by the constant S on the assumption that the temperature characteristics are in a proportional relationship, but any calculation may be performed as long as it conforms to the actual temperature characteristics.

Standard number of drops after correction for each predetermined range of temperature difference ΔT N11c
It is also possible to change it in stages.

When the reference number of drops NB is corrected as described above, the following is the corrected reference number of drops Nθ obtained thereby.

Based on this, feedback control is performed so that the number of drops N matches as in the conventional method. That is, the standard number of drops after correction N8c
and the actual number N of drops within a predetermined time detected by the dripping sensor 4, and based on this comparison result (Nsc N), the flow j! By adjusting the adjustment 1m of the adjustment device 5, the number N of infusion drops becomes the standard number Ng of drops after correction. control to match.

Then, as shown in FIG. 3, the number N of drops in the dripping section 3 changes in proportion to the temperature T, and this temperature T becomes the reference temperature '
If it is different from T-, the number of drops N will be different from the reference number of drops N91, but the flow rate of the infusion that actually flows through the infusion tube 2 is always kept constant regardless of the temperature T.

(Effects of the Invention) As is clear from the above description, the infusion flow rate control device of the present invention detects the number of drops of infusion and controls the flow rate.
This has the effect that a constant flow rate can always be supplied without being affected by temperature.

4. Don't worry! Nitto Figures 1 to 3 show one embodiment of the present invention, in which Figure 1 is a block diagram of an infusion flow rate control device, Figure 2 is a block diagram showing the control operation of the control device, and Figure 3 is a block diagram of an infusion flow rate control device. The figure is a graph showing the relationship between temperature and the number of drops, and Figures 4 and 5 show conventional examples. Figure 4 is a block diagram of an infusion flow rate control device, and Figure 5 is a block diagram of a control device. It is a block diagram showing control operation.

2... Infusion tube (infusion passage), 3... Dripping part, 5... Flow rate adjustment device (flow rate adjustment part), 4... Dripping sensor, 9... Temperature sensor (temperature detection part) , 8...
Control device (flow rate correction means).

that's all

Claims (1)

[Claims] 1. A dripping part and a flow rate adjusting part for this infusion are provided on the infusion passage, and the number of drops of the infusion in units of time at the dripping part is detected, and this number of drops is used as a standard drip. An infusion flow rate control device that controls the flow rate of an infusion solution by adjusting the flow rate in a flow rate adjustment unit so as to match the number of infusions, comprising a temperature detection unit that detects temperature, and a temperature detected by the temperature detection unit that is a reference value. An infusion flow rate control device comprising: a flow rate correction means that corrects the flow rate in a flow rate adjustment unit to increase the flow rate when the temperature is higher than the temperature, and correct the flow rate to decrease the flow rate when the temperature is lower.