JPH0744927B2 - Quantitative blood sampling device - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a quantitative blood sampling device for collecting a predetermined amount of blood from a blood donor, and in particular, to true blood sampling while operating the swinging means of the blood bag. It is a quantitative blood sampling device that can accurately detect the amount.

[Prior Art and Problems of Prior Art] Conventionally, a device for measuring the weight of a blood bag with a spring balance and a device for detecting the expansion of the blood bag by the blood flowing into the blood bag and collecting a constant volume of blood have been used. However, since there were various problems in the work, recently, instead of these, a quantitative blood sampling device which accurately produces a blood sampling amount by a weight measuring means has been used.

The quantitative blood sampling device collects blood by controlling the weight measuring means using the load cell and the swinging means of the blood bag by the control unit, but the weight measurement is performed by detecting the strain in the load cell. Therefore, when measuring the weight, an accurate value cannot be obtained unless the object to be measured is measured.

Therefore, in the above-mentioned quantitative blood sampling apparatus, when measuring the blood sampling amount during blood sampling, the swinging means is temporarily stopped and the weight is measured.

However, when the swinging means and the weight measuring means are alternately operated in this manner, the blood sampling amount becomes larger than the set value due to the time lag until the operation is switched, and it is necessary to more accurately collect the predetermined amount of blood. However, the control of the weight measuring means and the swinging means had to be further corrected, and the control method was complicated.

Also, the blood bag contains an anticoagulant,
It is necessary to uniformly stir the collected blood with these anticoagulants so as not to coagulate. However, since the blood collecting apparatus stops rocking midway, there is a possibility that stirring cannot be performed sufficiently.

Therefore, the present invention diligently examines the weight and time cyclic changes of the weight measuring means and the rocking means, finds the correlation between the position change and the weight change of an arbitrary point on the mounting table, and simultaneously performs the weight measurement and the rocking. However, the present invention provides a quantitative blood sampling device that can accurately detect the blood sampling amount and perform quantitative blood sampling.

[Means for Solving the Problems] A first invention adopted for the above object is to store a blood bag mounting table on which a blood bag having a blood sampling tube is mounted, and a blood bag of the blood bag mounting table. A blood bag weight measuring means for measuring the blood weight, a swinging means for vertically swinging the blood bag mounting table about a horizontal axis of the blood bag mounting table, and closing the blood collecting tube. A quantitative blood sampling device comprising a blood sampling tube closing means for stopping blood sampling in the blood bag, wherein the blood bag mounting table passes while moving from the bottom dead center to the top dead center while the blood bag mounting table is swinging. A horizontal position detecting means for detecting a horizontal position of the blood bag mounting table, and the blood bag weight measuring means when the horizontal position of the blood bag mounting table is detected by the horizontal position detecting means. The blood bag weight is measured by, and when the blood bag weight reaches a predetermined weight, the blood collection tube closing means has an interlocking control means for closing the blood collection tube, and the swinging means comprises the blood bag mounting means. The eccentric rotation unit swings in a swing cycle such that the tilt angle of the table in the vertical direction is centered on the horizontal axis and the bottom dead center is larger than the top dead center.

A second aspect of the invention is characterized in that the eccentric rotation means is a mechanism in which the blood bag mounting table swings about a horizontal axis in an upward range of 5 to 15 ° and a downward range of 10 to 30 °. And

[Operation] According to the above-described invention, when measuring the blood sampling weight of the blood bag placed on the blood bag stationary table, the horizontal position is less likely to be influenced by the inertial force of the blood bag mounting table rocked by the horizontal position detecting means. The position, that is, the horizontal position where the blood bag mounting table passes on the way from the bottom dead center to the top dead center is detected. And when this horizontal position is detected, the amount of blood collected in the blood bag is measured by the blood bag weight measuring means,
When the weight of the blood bag reaches a predetermined weight, the blood collection tube closing means is activated and the blood collection tube leading to the blood bag is closed.

[Example] FIG. 1 is an exploded perspective view of a quantitative blood sampling device 1 of the present invention, FIG.
FIG. 1A is an enlarged view of the cam 11, FIG. 2B is an enlarged view of the guide rail 13, and FIGS. 3A to 3C are enlarged views showing an embodiment of the horizontal position detecting means 5. is there.

FIG. 4 is a block diagram of the quantitative blood sampling device 1.

The quantitative blood collecting device 1 is basically a blood bag mounting table 2 a blood bag weight measuring means 3 a swinging means 4 of the mounting table 2 a horizontal position detecting means 5 of the mounting table 2 a blood bag collecting tube closing means 7 a weight measuring means 3 and the operation of the rocking means 4 are interlockedly controlled,
The control unit 8 controls the opening and closing of the closing means 7.

The swinging means 4 of the mounting table 2 includes a weight measuring means 3, that is, a load cell base 9 on which the load cell 3 is mounted, a swing arm 10 fixed to the load cell base 9, and a swing arm.
It is composed of an eccentric cam 11 and a motor 12 for transmitting motion to 10.

The shaft 18 of the eccentric cam 11 is mounted in the groove 19 of the guide rail 13, and the guide rail 13 is fixed to the swing arm 10.

A gear head 17 is attached to the motor 12, and these are attached to a motor base 15.

The rotational movement of the motor 12 is transmitted to the swing arm 10 via the gear head 17, the eccentric cam 11, and the guide rail 13.

Further, the eccentric cam 11 is provided with the horizontal position detecting means 5 with the mounting table 2.
It is attached to the motor base 15 via.

The horizontal position detecting means 5 is composed of, for example, a plate 14 with a slit and a center 16, the plate 14 with a slit is mounted so as to rotate simultaneously with the eccentric cam 11, and the sensor 16 has a light emitting part 20 and a light receiving part 21 with slits. It is attached to the motor base 15 so as to be located on both sides of the plate 14.

FIG. 3 (a) is an enlarged view of these horizontal position detecting means 5, and at the moment when the slit 14a of the slitted plate 14 comes between the light receiving portion 21 of the light emitting portion 20 of the sensor 16, the light emitting portion 20 The horizontal position of the mounting table 2 is detected by the light emitted from the light receiving portion 21 reaching the light receiving portion 21.

In that case, small holes may be formed in addition to the slits 14a of the plate 14 with slits, or a reflecting member or a protruding member may be mounted.

FIG. 3 (b) shows another embodiment of the horizontal position detecting means 5 in which the reflecting member 24a of the plate with reflecting member 24 has come to a predetermined position (for example, an intermediate position between the light emitting section 20 and the light receiving section 21). At a moment, the light emitted from the light emitting section 20 is reflected by the reflecting member 24a and the light receiving section 2
When 1 is achieved, the horizontal position of the mounting table 2 is detected.

FIG. 3 (c) shows another embodiment of the horizontal position detecting means 5 in which the protruding portion 34a of the plate 34 with the protruding member is the light emitting portion 2 of the sensor 16.
At the moment when it comes between 0 and the light receiver 21, the light emitter 20 of the sensor 16
The horizontal position of the mounting table 20 is detected by blocking the light emitted from the table.

Next, the swing motion of the present invention will be described.

As shown in FIG. 5 (a), when the cam 11 rotates counterclockwise about the point P, the slit 14a of the slitted plate 14 changes from A → B → C → D → A, In response to this, the mounting table 2 swings about the 0 point as a rotation axis.

Mounting table 2 when the horizontal axis is X ₀ connecting the rotation axis 0 and any point on the mounting table 2, about the horizontal axis X _0, Figure 5 upward as shown in (b) θ ₁ = 5 to 15 °, θ ₂ downward
Repeated swinging in the range of 10 to 30 °.

Next, the principle of the weight measurement of the present invention will be described.

FIG. 6 is a diagram showing changes in the weight felt by the load cells 3 installed in parallel on the upper surface of the blood bag mounting table 2 and fluctuations in the amplitude height when an arbitrary point on the mounting table 2 swings. .

The hatched area of the line indicates the range in which the weight can change, and indicates that the true weight is detected at W ₀ .

From FIG. 6, the true weight of the blood bag can be detected when the arbitrary points on the mounting table 2 are at the positions of and, but only when the arbitrary points on the mounting table 2 are at the positions of due to the following reasons. Indicates the true weight.

The cam 11 makes a uniform circular motion, but as can be seen from FIG. 6, the amplitude of the mounting table 2 is not a uniform circular motion.

When the cam 11 is rotated at a very gentle speed so that the weight of the mounting table 2 and the blood bag does not have inertia, an arbitrary point on the mounting table 2 becomes horizontal on the mounting table 2 when the position of is reached. Since it is in the position, the load cell 3 can detect the true value W ₀ .

However, since the cam 11 is rotating at a speed of 15 rpm to 30 rpm (times / minute), an inertial force acts on the object (the mounting table 2 and the blood bag) on the load cell 3, particularly when an arbitrary point is, Since it moves from top to bottom, the inertial force is likely to act, and further, the blood collection amount gradually increases, so the inertial force is likely to change, and the detected amount of the load cell weight at the point according to its speed is the true value W _0. It becomes easy to vary from top to bottom.

That is, when the movements of the blood bag and the mounting table 2 are compared with each other during the rotational movement of the cam 11, when the blood bag receives the inertial force and moves downward at a high speed, the load cell 3 has a true weight. The weight is detected as a value that is heavier than W ₀ .

On the other hand, when the blood bag moves downward after the inertia and only the mounting table 2 moves downward first, the load cell 3 detects the weight as a value smaller than the true weight.

On the other hand, when the arbitrary point is on, the inertial force is braked because it moves from the bottom to the top, and the influence of the inertial force is less likely to occur.

Therefore, the point can detect the true value W ₀ regardless of changes in weight, speed, and inertial force.

However, as the rotational speed of the cam increases, it becomes more susceptible to the inertial force, so that the true value W ₀ can be detected only within the rotational speed range of ₀ to 60 rpm.

As described above, when an arbitrary point on the mounting table 2 is at the position on the horizontal axis X ₀ , the eccentric cam 11 corresponding to the position where the true weight W ₀ is always shown is provided and the slit is driven. By detecting the position of the slit 14a of the plate 14, the true weight of the blood bag can be measured.

That is, in FIG. 5 (a), while an arbitrary point on the horizontal axis X ₀ on the mounting table 2 changes →→→→, an arbitrary point on the eccentric cam 11 changes →→→→. (Ha, ha, ha, ha correspond to)
Slit 14a of plate 14 with slits at the position corresponding to
If the position of the slit 14a is detected by the sensor 16 when the blood comes, it is possible to collect blood while continuing the swing of the mounting table 2.

Next, a usage example of the quantitative blood sampling device 1 of the present invention will be briefly described.

After mounting the blood bag on the mounting table 2, the motor 12 is driven to swing the mounting table 2.

Subsequently, blood is introduced from the donor into the blood bag body through the blood collection tube of the blood bag.

The blood introduced into the blood bag body is mixed with the anticoagulant filled in the blood bag in advance.

The weight of the blood introduced into the blood bag body is such that the slit 14a of the slitted plate 14 is at the position of FIG. 5 (a) (any point of the horizontal axis X ₀ of the mounting table 2 is at the position). When it comes, it can be measured by detecting it with the sensor 16.

At this time, the swinging means 4 is always operating.

Just before the amount of blood reaches a predetermined amount, a horizontal stop is performed at the position shown in FIG.

In order to improve the stirring effect of blood and anticoagulant, this horizontal stop time should be minimized and the true weight detected within this minimum time.

For example, when trying to stop at 99% of the total blood collection amount, if it is detected at the position of FIG. 6 instead of at the position of FIG. 6,
When the weight is slightly larger than the true value, the vehicle stops at the slightly larger weight data.

In this case, what was trying to stop horizontally between 99% and 100% of the total blood collection may actually be 95% of the total blood collection.

That is, it is not preferable because the horizontal stop time until reaching the set capacity becomes long.Also, it was trying to stop at 99%, but it was 98% at any swing cycle and 100% at the time when the next swing cycle was reached. In the above case, a signal is immediately sent to the closing means 7 to stop the blood collection, but the actual weight may be 95%.

In the present invention, the main body of the fixed-quantity blood sampling device 1 is equipped with the vacuum pump 25 so that the main body of the constant-quantity blood sampling device 1 is evacuated to collect blood.

Further, a tare weight storage unit 26 and a calculation unit 27 are additionally provided in the control unit 8, and the calculation unit 27 subtracts the value stored in the tare weight storage unit 26 from the value obtained by the weight measuring means 3. The amount of blood collected can also be calculated.

[Effects of the Invention] According to the present invention described above, when a blood bag is placed on a blood bag placing table to measure a blood collection amount, the blood bag placing table swings so that the bottom dead center is larger than the top dead center. Compared to when measuring at other fixed positions, the amount of blood collected is measured at a horizontal position in the middle of going from bottom dead center to top dead center that is oscillating in a cycle and is not easily affected by the inertial force of the oscillating motion. And an accurate measurement value can be obtained. In addition, since blood can be collected while uniformly mixing the collected blood and the anticoagulant,
This is an excellent invention that has an effect that blood can be smoothly collected without the risk of blood coagulating due to the blood remaining in a part of the blood bag.

[Brief description of drawings]

FIG. 1 is an exploded perspective view of the quantitative blood collection device 1 of the present invention, FIG.
FIG. 3A is an enlarged view of a cam, FIG. 2B is an enlarged view of a guide rail, FIGS. 3A to 3C are enlarged views showing an embodiment of horizontal position detecting means, and FIG. FIG. 5 is a block diagram of the quantitative blood sampling device of the present invention, FIG. 5 is a schematic diagram showing the principle of rocking of the present invention, and FIG. It is a diagram which shows the relationship between fluctuation and time. In the figure, 1 is a quantitative blood sampling device, 2 is a mounting table, 3 is weight measuring means (load cell), 4 is swinging means, 5 is horizontal position detecting means of the mounting table, 7 is blood sampling tube closing means, and 8 is control. Part, 9 is a load cell base, 10 is a swing arm, 11 is a cam, 12 is a motor, 13 is a guide rail, 14 is a plate with a slit, 14a is a slit, 15 is a motor base, 16 is a sensor, 17 is a gear head, 18 is a A shaft, 19 is a groove, 20 is a light emitting portion, and 21 is a light receiving portion.

Claims (2)

[Claims] 1. A blood bag mounting table on which a blood bag having a blood collection tube is mounted, blood bag weight measuring means for measuring the weight of blood stored in the blood bag of the blood bag mounting table, and the blood bag mounting table. Quantitation provided with a swinging means for swinging the mounting table in the vertical direction about the horizontal axis of the blood bag mounting table, and a blood collecting tube closing means for closing the blood collecting tube and stopping blood collection in the blood bag. In the blood collecting device, a horizontal position detecting means for detecting a horizontal position of the blood bag mounting table that the blood bag mounting table passes through while the blood bag mounting table is swinging from the bottom dead center to the top dead center during swinging of the blood bag mounting table. And, when the horizontal position of the blood bag mounting table is detected by the horizontal position detecting means, the blood bag weight is measured by the blood bag weight measuring means, and the blood bag weight is a predetermined weight. When the blood collection tube is closed, the blood collection tube closing means closes the blood collection tube.Therefore, the rocking means has a vertical tilt angle of the blood bag mounting table with a horizontal axis as a center. A constant amount blood sampling device, which is an eccentric rotation means that swings in a swing cycle such that the point becomes larger than the top dead center. 2. The eccentric rotation means, wherein the blood bag mounting table is 5 to 15 ° upward and 10 to 30 ° downward about a horizontal axis.
2. A mechanism that swings within the range of 1.
The quantitative blood sampling device described in.