JPS63221220A - Tube for measurement of fluid information - Google Patents

Abstract

PURPOSE:To measure an accurate flow velocity speedily by arranging a sensor which outputs an ultrasonic wave and detects a reflected ultrasonic wave fixed in the tube wall of a tube main body for measurement. CONSTITUTION:The tube 10 for flow rate measurement consists of a tube main body 12 where fluid to be measured flows and a sensor holding part 14 on the external wall of the main body 12. The ultrasonic sensor 16 which detects the flow velocity by using the ultrasonic wave is arranged fixedly in the holding part 14. When the flow velocity is detected, the sensor 16 sends out the ultrasonic wave from its ultrasonic wave transmitter 16a. The sent ultrasonic wave is reflected by the fluid in the tube main body and the reflected ultrasonic wave is received by the ultrasonic wave receiver 16b having a different frequency by Doppler effect. Then this received data is sent to a controller (not shown in figure) through a cable 18 and specific arithmetic operation is performed to obtain the flow velocity.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a fluid information measuring tube for measuring the flow velocity of a fluid to be measured flowing inside a tube body using ultrasonic waves.

[Conventional technology] Conventionally, when measuring the flow velocity or flow rate of a fluid to be measured flowing inside a tube using ultrasonic waves, a probe such as an ultrasonic flowmeter is fixed to the outer wall of the tube. . In addition, in recent years, when performing surgery of interest or other surgeries,
BACKGROUND ART The development of an artificial heart-lung machine, an auxiliary heart, or an artificial heart device for supplementary or temporary replacement of the heart or cardiopulmonary function outside the body is progressing. Such artificial heart-lung machines, auxiliary hearts, or artificial heart devices have also been effective in clinical applications for patients during actual treatment.

In such clinical applications, blood flow measurement is particularly important.
An important monitoring element, ultrasonic flowmeters are important in that they allow flow measurements without direct contact with blood.
It is said to be effective.

[Problems to be Solved by the Invention] When using such an ultrasonic flowmeter, it is necessary to adhere the sublobe having the ultrasonic vibrator to the outer wall of the tube with an adhesive, or attach a band or special holder to the tube. It has to be fixed to the outer wall of the tube through the tube, which is very cumbersome to operate. In particular, substances with different acoustic impedances, such as the outer wall of the tube and the adhesive layer of the probe, are interposed between the ultrasound transducer and the blood. For this reason,
The ultrasonic waves emitted by the ultrasonic transducer are attenuated or reflected, making it difficult to effectively receive echoes from blood. In this way, there is a problem that the flow velocity cannot be accurately measured using this echo. Furthermore, it has been pointed out that errors in the ultrasonic transmission angle and the like occur due to defects in the way the probe is attached, which has a negative effect on measurement accuracy.

This invention was made in view of the above-mentioned problems.
The purpose of this invention is to quickly measure the flow velocity of a fluid to be measured.
Another object of the present invention is to provide a fluid information measuring tube that can reliably improve measurement accuracy.

[Means for Solving the Problems] In order to solve the above-mentioned problems and achieve the purpose, a fluid information measurement tube according to the present invention includes a tube body through which a fluid to be measured flows, and a tube body in which a fluid to be measured flows. The detection means is fixedly arranged in the tube wall and outputs ultrasonic waves toward the fluid to be measured flowing within the tube body, and detects at least data regarding the flow velocity by receiving the reflected ultrasonic waves. It is characterized by things.

Further, the first part of the fluid information measuring tube according to the present invention
According to this embodiment, the tube body has a portion where the detection means is arranged made of a resin material through which ultrasonic waves can pass, and the detection means is fixedly arranged on the resin material. As a result, the direction of input and output of the ultrasonic waves input and output from the detection means is maintained constant.

Further, the second fluid information measuring tube according to the present invention
According to Mr. M, the tube body through which the fluid to be measured flows forms part of a blood circuit connected to an artificial heart-lung device, an artificial heart device, or an auxiliary heart device. .

Moreover, the third part of the fluid information measuring tube according to the present invention
According to this embodiment, the inner circumferential surface of the tube body is treated with antithrombotic treatment.

[Function] In the fluid information measurement tube configured as described above, when measuring the flow velocity of the fluid to be measured flowing inside the tube body, the detection means for outputting ultrasonic waves is activated in advance in the wall of the tube body. This detection operation is as follows:
The detection starts with the start of the ultrasonic output from the detection means, and a rapid detection operation is realized. Furthermore, since there is no substance with different acoustic impedance, such as the outer wall of the tube or the adhesive layer of the probe, between the detection means that outputs ultrasonic waves and the blood, the ultrasonic waves output from the detection means are attenuated or reflected. This improves the condition in which it is difficult to effectively receive echoes from blood. In this way, the flow velocity can be measured with high accuracy using this echo. Furthermore, since the arrangement of the detection means is fixed, errors in the transmission angle of the ultrasonic waves, etc. do not occur, and measurement accuracy is not adversely affected.

[Example] Below, the configuration of an example of the fluid information measuring tube according to the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 1, the flow rate measurement tube 1° includes a tube body 12 through which blood as a fluid to be measured flows, and a sensor holding portion 14 integrally attached to the outer wall of the tube body 12. Inside this sensor holding part 14, a second A
As shown in FIG. 2B and FIG. 2B, an ultrasonic sensor 16 as a detection means for detecting the flow velocity of blood flowing inside the tube body 12 via ultrasonic waves is installed in a fixed state. has been done.

As shown in FIG. 3, this ultrasonic sensor 16 is electrically connected to a calculation device 20 via a cable 18, and this calculation device 20 uses the flow velocity detected by the ultrasonic sensor 16 to The tube body! 2 is configured to calculate the flow rate of blood flowing through the blood.

The above-mentioned ultrasonic sensor 16 is a sensor holding portion that is integrally attached to the outer wall of the tube body 12 through which blood as a fluid to be measured flows, as shown in different cross sections in FIGS. 2A and 2B. 4 is formed with a recess 22 that is open to the inner circumferential surface of the tube body 12. This recess 22
A sensor block 24 made of acrylic resin and fixed to the tube body 12 is disposed inside. Note that the above-described ultrasonic sensor 16, recess 22, and sensor block 24 constitute the detection means of the present invention.

On this sensor block 24, there is an ultrasonic transmitter 16 that outputs ultrasonic waves toward the blood flowing inside the tube body 12.
a and an ultrasonic receiver 16b that receives ultrasonic waves reflected from flowing blood and detects data regarding flow velocity, with their axes intersecting each other. One end of the cable 18 described above is connected to these ultrasonic transmitters 16a.
and an ultrasonic receiver 16b, respectively.

The ultrasonic transmitter 18a and the ultrasonic receiver 16b constitute an ultrasonic sensor 16 that detects data regarding flow velocity.

On the other hand, the tube body 12 to which such an ultrasonic sensor 16 is attached is made of a soft vinyl chloride resin. Further, the bottom surface of the sensor block 24 is formed of a curved surface along the inner circumferential surface of the tube body 12. Also,
This tube body 1 is provided on the entire inner peripheral surface of the tube body 12.
An antithrombotic agent 26 is attached to prevent the blood flowing through the tube 2 from coagulating, and a so-called antithrombotic treatment is applied.

In this embodiment, the fluid information measurement tube 14
constitutes a part of the blood circuit conduit in the heart-lung machine 28. That is, in this heart-lung machine 28, venous blood drained from the patient's veins via the blood removal line 3o, and blood that bleeds from the patient's incision site during the surgical procedure in question are aspirated and pumped into the cardiopulmonary tube. Dormy reservoir 3
The blood that has been defoamed in step 2 and sent from there is stored in a venous reservoir 34, and the venous blood stored in the venous reservoir 34 is transferred to a heat exchanger 38 by driving a blood pump 36. The blood is exchanged with oxygen through the artificial lung 40 and the artificial lung 40, and then the blood is returned to the patient's artery via the blood supply line 42.

Note that this fluid information measurement tube 10 is not only applicable to such a heart-lung machine 28, but also to, for example,
As shown as a modification in FIG. 4, it can also be used to measure blood flow velocity in a blood circuit 44 for an auxiliary heart. That is, the pump 4 for the auxiliary heart
A part of the blood removal cannula 48 that sends blood from the patient to the tube 6 is employed as the tube 10 through which the blood as the fluid to be measured flows. A blood feeding cannula 5o is attached to the auxiliary heart pump 46 for returning the energized blood to the patient. The fluid information measurement tube 10 can also be employed as a part of the blood feeding cannula 50 in the auxiliary heart pump 46.

The operation of using the fluid information measurement tube 10 in the heart-lung machine 28 configured as described above will be described.

When the heart-lung machine 28 is used in the surgical procedure of interest, the flow rate of the removed blood is determined by the flow rate measurement tube 1 in order to control the driving state of the blood pump 36.
Measured by 0. In this measurement, first, the power of the arithmetic device 2o is turned on. Here, the ultrasonic sensor 16 is fixedly arranged in the tube wall of the tube body 12 in advance. Therefore, in this detection operation,
In order to prevent air or bubbles from entering between the tube body 12 and the sensor block 24 and increasing the attenuation of the ultrasonic waves, there is no need to apply a jelly-like liquid in advance. Further, unlike in the past, after applying this jelly, it is no longer necessary to fit the probe for fluid information measurement into the attachment portion of the tube body through which blood as the fluid to be measured flows.

Furthermore, since the operation of attaching the probe is omitted in this way, the operator will not be able to make a mistake in the attachment position.

By starting the operation of the arithmetic device 20 in this way, ultrasonic waves are emitted from the ultrasonic transmitter 16a of the ultrasonic sensor 16 as continuous waves of, for example, 5 MHz. The ultrasonic waves emitted in this way are reflected by the blood flowing inside the tube body 12, and the reflected ultrasonic waves are received by the ultrasonic receiver 16b with different frequencies due to the Doppler effect. Ru.

The data regarding the flow velocity received by the ultrasonic receiver 16b is sent via the cable 18 to the computing device 20, where the information is processed and the flow rate of the blood flowing inside the tube body 12 is calculated. Calculated.

As described in detail above, in this embodiment, the fluid information measurement tube 10 includes a tube body 12 through which blood as a fluid to be measured flows, and an ultrasonic sensor 16.
It is configured to be integrally formed with. In this way, the presence of materials with different acoustic impedances between the ultrasonic transducer 18a and the blood can be minimized. Therefore, according to this embodiment, the measurement accuracy in measuring the flow velocity is significantly improved.

Further, in this embodiment, the ultrasonic sensor 16 is
It is arranged in a fixed state in the tube wall of the tube body 12. In this way, the emission angle of the ultrasonic waves output from the ultrasonic transducer 16a is always constant, and a highly accurate measurement state is realized.

In general, it is known that if there is a step or a discontinuous part in the blood flow path, such as a connection between a tube and a connector, thrombus is likely to form at this step or discontinuous part. It is being However, in this embodiment, as described above, the fluid information measurement tube 10 is connected to the tube main body 1 that constitutes a part of the blood circuit.
2, there is no need to use a separate connecting member such as a connector when incorporating this into the blood circuit, and the number of connections to the blood circuit can be kept to a minimum. Therefore, according to this embodiment, the possibility of thrombus formation in the blood flow path can be minimized.

It goes without saying that this invention is not limited to the configuration of the one embodiment described above, and can be modified in various ways without departing from the gist of the invention.

[Effects of the Invention] As detailed above, the fluid information measurement tube according to the present invention includes a tube body through which a fluid to be measured flows, and a tube wall of the tube body. The tube body is characterized in that it is equipped with a detection means that outputs ultrasonic waves toward the fluid to be measured flowing within the tube body and receives reflected ultrasonic waves to detect at least data regarding the flow velocity.

Therefore, according to the present invention, there is provided a fluid information measuring tube that can quickly measure the flow velocity of the fluid to be measured and reliably improve the measurement accuracy.

[Brief explanation of drawings]

FIG. 1 is a perspective view schematically showing an embodiment of the fluid information measuring tube according to the present invention; FIGS. 2A and 2B show the fluid information measuring tube cut at different cutting planes. A front sectional view and a side sectional view; FIG. 3 is a circuit diagram schematically showing a blood circuit of an artificial heart-lung machine to which this fluid information measurement tube is applied; FIG. 4 is a fluid diagram of an embodiment of the present invention. FIG. 7 is a perspective view showing a modification example in which the information measurement tube is applied to a pump for an auxiliary heart. In the figure, 10-...Tube for fluid information measurement, 12...
Tube body, 14... Sensor holding part, 16... Ultrasonic sensor, 16a... Ultrasonic transmitter, 16b...
Ultrasonic receiver, 18... Cable, 20... Arithmetic device, 22... Recess, 24... Sensor block, 26
...Antithrombotic agent, 28...Artificial heart-lung machine, 30...
Blood removal line, 32...cardiomi reservoir, 3
4... Venous blood reservoir, 36... Blood pump, 38
...Heat exchanger, 40...Artificial lung, 42...Blood supply line, 44...Blood circuit for auxiliary heart, 46...Pump for auxiliary heart, 48...For blood removal cannula, 50
...It is a cannula for blood delivery.

Claims (4)

[Claims] (1) A tube body through which a fluid to be measured flows, and an ultrasonic wave that is fixedly arranged in the wall of this tube body and outputs and reflects ultrasonic waves toward the fluid to be measured flowing inside the tube body. 1. A tube for measuring fluid information, comprising a detection means for receiving ultrasonic waves and detecting at least data related to flow velocity. (2) The tube body is formed of a resin material through which ultrasonic waves can pass through a portion where the detection means is disposed;
Claim 1 is characterized in that the detection means is fixedly disposed on the resin material so that the input and output directions of the input and output ultrasonic waves are maintained constant. Tube for measuring fluid information as described. (3) The tube body through which the fluid to be measured flows constitutes a part of a blood circuit connected to an artificial heart-lung machine, an artificial heart machine, or an auxiliary heart machine. The fluid information measurement tube described in Section 2. (4) The fluid information measuring tube according to claim 3, wherein the inner circumferential surface of the tube body is treated with antithrombotic treatment.