RU2219959C2 - Infusion device for injection of fluids within a wide range of transparency - Google Patents

Abstract

FIELD: automatic infusion devices for injection of fluids by means of a pump. SUBSTANCE: the infusion device represents a peristaltic pump designed for intake of fluid from a separate reservoir and delivery of it to the patient's organism, it has a standard single infusion system linked with the working part of the peristaltic pump, and a control unit. The infusion device is provided with a photometric air sensor located on a flexible transparent tube of the single infusion system. The photometric sensor is made with one light radiator and two photodetectors. The flexible transparent tube serves as a lens between the photoradiator and photodetectors. The first photodetector is positioned opposite the light radiator on the other side of the flexible transparent tube along the straight beam from the light radiator passing the middle of the cross- section of the flexible transparent tube, the second photodetector is positioned at an angle of not more than 90 deg to the direction of the straight beam from the light radiator. This provides for operation of the first photodetector for receiving of the transmitted light, and of the second on-receiving of the reflected and scattered light from the fluid in the transparent tube of the single infusion system. EFFECT: expanded range of transparency of injected fluids, enhanced reliability of catching of the bubbles of air that has got into the hydropath. 4 dwg

Description

 Known infusion devices for the introduction of liquid drugs using pumps of various types: peristaltic (roller, finger, etc.), syringe or others. These infusion devices are equipped with additional devices that provide control and reliability of operation, namely, a drop sensor, an air bubble sensor, an occlusion sensor, etc.

 It is known an infusion device containing a pump and tubes of elastic material, through which fluid is pumped into the patient's body, as well as a system of sensors for detecting air bubbles in the tube of the infusion system (US Pat. US 5123275, NKI 73 / 19.03). The sensor system consists of two ultrasonic (ultrasound) transducers in housings located one above the other. The upper case contains a transmitting ultrasonic transducer, and the lower one contains a receiving ultrasonic transducer. A tube of elastic material through which fluid is supplied passes between the housings. To fix the tube in the lower case, a U-shaped groove is made, and the upper case is pressed against the tube by a spring, due to which the tube is deformed and flattened from above. As a result, the shape of the tube between the upper and lower bodies approaches a rectangular shape. When an air bubble enters the area between the buildings, the compressibility of this segment changes dramatically, which leads to a change in the distance between the upper and lower bodies and, accordingly, between the transmitting and receiving SPDs. This change is recorded by the electronic circuit.

 Known infusion device (US Pat. US 4981467, NKI 604-65), containing an infusion pump designed to take fluid from a separate source and enter it through the connecting hose into the patient's body, an ultrasonic sensor for detecting air in a moving fluid stream and connected to the sensor is a secondary transducer that identifies bubbles of inappropriate sizes. The principle of operation of the transducer is based on determining the distance that the bubble travels during its detection and which is the criterion for recognizing bubbles having a size that exceeds the allowable limit.

 The disadvantage of using infusion pumps with ultrasonic air bubble sensors is the high requirements for manufacturing accuracy (for technological repeatability) and the significant cost of ultrasonic sensors. In addition, they do not allow working at a certain distance from the hydrotract, because large radiation powers are required with increasing distance between the transmitting and receiving parts, and this causes an increase in interference caused by the ultrasound device and can cause injury to drug components at the molecular level. Such sensors do not distinguish the transparency of liquids.

 Known infusion device (application EPO 0405148), which contains a pump connected to the outlet of the pump tube and installed in the area of the tube device with a flow sensor for determining the places of blockage of the tube. The sensor is thermal and contains a heating element in contact with the current heat-removing liquid. There is a circuit that generates an output signal on the flowing liquid or in the presence of heat-insulating air bubbles in the circumference of the heating element, which drives the alarm device.

 Thermal sensors have a high inertia, i.e. at high infusion rates are not suitable. In addition, they have limited temperature use and, like the previous ones, do not distinguish the transparency of liquids.

 The infusion device DLV-1 is known (Designed by NIIEM, Istra: ИМЦЖ 942515.003), which contains a peristaltic pump and a standard single-use infusion system with a built-in working tube made of elastic material that mates with a peristaltic pump, designed for pumping medicinal fluids into the patient's body. This device contains an air bubble sensor based on the photoelectric effect and operating in the infrared range, i.e., in a specific place to the point of insertion of the working tube made of elastic material, there is an LED on one side of the transparent tube of a single infusion system and a photodiode on the other. If there are no air bubbles in the flowing liquid, a mode current flows through the photodiode, which does not cause the threshold device to operate and then no alarm. When air bubbles enter the hydrotract due to a change in the refractive index, the photocurrent flowing through the photodiode changes, a threshold circuit is triggered, and a signal is generated to the alarm device. This sensor works well in a certain range of liquid transparency, easy to manufacture and cheap. However, if the liquid is pumped less transparent (for example, blood), in fact the photosensor does not track the air bubble that has got into the hydrotract. This reduces the reliability of the device and is a significant disadvantage when using injected liquids with a wide range of transparency.

 The aim of the invention is the expansion of functionality, expressed in ensuring the safe operation of the infusion device (for air entering the patient’s body) with injected fluids of a wide range of transparency while maintaining ease of execution.

 The invention consists in the following.

The proposed infusion device is a peristaltic pump designed to collect fluid from a separate reservoir and supply it to the patient, containing a standard one-time infusion system coupled to the working part of the peristaltic pump and a control device equipped with a photometric air sensor located on a flexible transparent tube of a single infusion system. To reliably detect air bubbles trapped in the hydrotract with a liquid of various transparency, the photometric sensor is made with one light emitter and two photodetectors. Moreover, the flexible transparent tube of a single infusion system is actually a lens between the photo emitter and photodetectors. The first photodetector is located on one optical axis passing through the middle section of a transparent tube of a one-time system, with a light emitter, but on different sides of this tube, and the second at an angle less than 90 ^o to this optical axis. This ensures the operation of the first photodetector to receive transmitted, and the second - to receive reflected and scattered light from a liquid in a transparent tube of a single infusion system. With an increase in transparency, the current of the photodetector, which operates to receive reflected and scattered radiation, initially proportionally increases, reaches a certain maximum value and then decreases approximately exponentially. The current of the photodetector, which operates to receive transmitted radiation, initially slightly increases and, with a further increase in transparency, increases approximately according to the hyperbolic law. Therefore, in the entire real transparency range, the current of either the first or second photodetector is above its threshold values. These dependences are derived experimentally, as evidenced by the test report included in the application materials.

 The photocurrents in the first and second photodetectors are amplified and fed to an analog-to-digital converter, the output of which is connected to the input of the control device. When an air bubble enters a tube with a pumped liquid, a change in the transmitted or reflected and scattered amount of light from the light emitter occurs, and hence a change in the photocurrents on both photodetectors. An analog-to-digital converter responds to this change and provides a signal to the control device, which, in turn, generates a signal to stop the peristaltic pump.

 The use of the two photodetectors described above allows you to expand the transparency range of the injected liquids, since with opaque liquids the second photodetector works mainly, and with more transparent ones the first. In any case, the circuit picks up air bubbles trapped in the hydrotract, thereby increasing the reliability of the device as a whole.

 The list of graphic figures and other materials.

 1) Functional diagram of an infusion device for operation in a wide range of transparency of the introduced liquids (Fig. 1).

Legend:
1 - peristaltic pump;
2 - single infusion system;
3 - transparent tube of a one-time system;
4 - elastic tubular insert;
5 - photometric sensor;
6 - light emitter (SI);
7 - the first photodetector (FP 1);
8 - the second photodetector (FP 2);
9 - the first amplifier (CSS 1);
10 - second amplifier (CSS 2)
11 - analog-to-digital Converter (ADC);
12 - control device.

 2) Test report of the photometric air sensor of the infusion device for operation in a wide range of transparency of liquids.

The protocol includes a description of the test conditions, a structural diagram of the test of a photometric air sensor of an infusion device for introducing liquids in a wide transparency range (Fig. 2), test results in the form of a graph (Fig. 3) of the dependence of the currents of the first and second photodetectors on the transparency of the liquid in the transparent the handset. The first photodetector worked on the lumen and was located opposite the light emitter on the other side of the transparent tube, and the second worked on the reception of reflected and scattered radiation and three curves were constructed for it: for the angle between the optical axes: the light emitter is the first photodetector and the light emitter is the second photodetector 90, 45 and <5 ^o . The relative position of the elements of the photometric sensor is shown in figure 4.

The claimed device consists of a peristaltic pump 1 and a single infusion system 2, containing a flexible transparent tube 3 with a soft elastic tubular insert 4, inserted into the working part of the peristaltic pump 1 for controlled compression of it with the aim of pumping the injected fluid from the reservoir with liquid medicinal substance into the patient’s body . The device is equipped with a photometric air sensor 5 located on a flexible transparent tube 3 of a single infusion system 2. To reliably detect air bubbles entering the hydrotract with a liquid of different transparency, the photometric sensor 5 is made with one light emitter 6 and two photodetectors: the first photodetector 7 and the second photodetector 8. The first photodetector 7 is located opposite the light emitter 6 along the optical axis passing through the middle of the cross section and on the other side of the flexible transparent tube 3. The second photodetector 8 is located at an angle to this optical axis. Moreover, the angle between the optical axis: the light emitter 6 is the first photodetector 7 and the optical axis: the light emitter 6 is the second photodetector 8, no more than 90 ^o .

 This is because the first photodetector 7 works to receive transmitted light, and the second - 8 - to receive reflected and scattered light from walls and liquids in a transparent tube 3 of a single infusion system 2. The device also contains two amplifiers. The first amplifier 9 is connected to the output of the first photodetector 7, and the second amplifier 10 is connected to the output of the second photodetector 8. The outputs of both amplifiers are connected to the inputs of the analog-to-digital converter 11, which converts the analog signals to digital form for convenient processing in the control device 12, input which is connected to the output of the analog-to-digital Converter 11, and the output to the peristaltic pump 1 and to the light emitter 6.

 The device operates as follows.

 In the initial state, a single infusion system 2 and a flexible transparent tube 3 are filled with a liquid that is pumped by a peristaltic pump 1 from the reservoir to the patient, while the light emitter 6 emits a light flux towards the flexible transparent tube 3, which is captured by photodetectors 7 and 8. Photodetector 7 located on the same optical axis with the light emitter 6 and perceives the light flux propagating mainly along the optical axis from the light emitter 6. The magnitude of the photocurrent flowing it through the photodetector 7, is directly dependent on the transparency of the liquid filling the flexible transparent tube 3. The photodetector 8 is located at an angle to the optical axis of the light emitter 6 and perceives the light flux due to the reflective and scattering properties of the flexible transparent tube 3 and the liquid filling it. Therefore, the photocurrent arising in the photodetector 8 has an inverse dependence on the transparency of the filling fluid.

 When air gets inside the flexible transparent tube 3, the signal of the photodetector 7 decreases to the level of “air 1”, and the signal of the photodetector 8 decreases to the level of “air 2”, while a significant signal difference (sensitivity) from the photodetector 7 is maintained in the region of the most transparent liquids, and from the photodetector 8 - in the field of least transparent liquids. The signals from the outputs of both photodetectors are amplified by amplifiers 9 and 10 and converted into digital form by an analog-to-digital converter 11. The processed signals are fed to the input of the control device 12, which performs their mathematical processing and generates a control signal for the peristaltic pump 1. Since the photodetectors work effectively 7 and 8 overlap, as a result, the overall sensitivity of the photometric sensor 5 for detecting air remains uniform over a wide range of transparency of liquids, Filling a flexible transparent tube 3.

Claims (1)

An infusion device for introducing liquids, including a peristaltic pump, a single infusion system containing a flexible transparent tube, part of which is located in the working part of the peristaltic pump, a photometric air sensor located around the transparent tube and consisting of light and photodiodes, and a control device connected to a peristaltic pump, characterized in that the photometric air sensor consists of one light emitter and two photodetectors (first and second), First and second amplifiers and an analog-to-digital converter are provided, the first photodetector located opposite the light emitter on the other side of the flexible transparent tube along a direct beam from the light emitter passing through the middle of the cross section of the flexible transparent tube, the second photodetector is located at an angle of no more than 90 ° to the direction of the straight beam from the light emitter, the outputs of the first and second photodetectors are connected respectively to the first and second amplifiers, the outputs of which are connected to the inputs of the analog-digital pre an educator that is connected to a control device.

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