JP5253871B2 - Blood cooling device and blood collection device - Google Patents

Description

  The present invention relates to a blood cooling apparatus for cooling collected blood and a blood collection apparatus capable of cooling while collecting blood after blood collection performed at a blood center of the Japanese Red Cross Society.

The blood after blood collection in the blood bag is usually at a temperature of 32 to 31 ° C. At the blood center, in order to lower the temperature of blood to 25 ° C, which is the optimum temperature for removing leukocytes, the collected blood bag is transported to the preparation process in a cooler box containing a coolant frozen during transportation. However, in reality, when the temperature of the blood bag is measured at the time of taking out from the cooler box at the site of the preparation process, most of them do not reach the optimum temperature.
In particular, there are reports that more than half of the people in summer had a blood temperature of 30 ° C or higher.
It has also been reported that the leukocyte removal rate decreases when leukocyte removal using a filter is performed at a temperature higher than 25 ° C., which is not suitable for leukocyte removal.
The blood collection site of the blood center may be performed in a space that is temporarily rented, such as a blood donation bath or open blood collection, so bring in a large-scale power consuming device such as a refrigerator to cool the blood bag on site However, since it is difficult due to problems of transportation and electric power, there is a demand for a device that is small and efficiently cools the blood bag.

In Patent Document 1, during the collection of whole blood, (1) a step of mixing an anticoagulant with the blood, (2) the blood at 4 to 28 ° C.
A step of cooling so that the blood is kept constant at a predetermined temperature, (3) a step of filtering the blood with a leukocyte removal filter to remove leukocytes, and an invention of a blood component separation method comprising the above steps. ing.
Further, in Patent Document 2, a Peltier element (PD) is attached to at least a part of the heat exchange section (2) of the oxygenator, and a heat radiating member (5) is provided on the heat generating surface or the heat absorbing surface of the Peltier element (PD). The invention of the Peltier unit (1) to which is attached is described.

  Further, in Patent Document 3, a blood removal line is connected to the blood inlet of the filtration filter, a blood return line is connected to the blood outlet, and a dialysate line is connected to the dialysate inlet of the filtration filter. In a heating and cooling type CHDF (continuous hemofiltration dialysis) device with a water removal line connected to the outlet, it is returned to either the blood return line or dialysate line by switching the polarity of the supply voltage to the Peltier element. An invention in which a heating / cooling device capable of heating or cooling blood in a blood line is arranged is disclosed.

  In the invention of Patent Document 1, blood temperature control means (cooler) is arranged in the middle of the blood collection tube, so that the blood flow rate in the blood collection tube passing through the cooler is high and low. The cooling time changes, and it is difficult to adjust the temperature uniformly in each blood sample.

JP 2004-173853 A (Claims, FIG. 1) JP 2006-296252 (Claims, FIG. 1) JP 2000-93449 A (Claims, FIG. 1)

  The problem to be solved by the present invention is that a cooling means such as a cooler box, which has been conventionally used as a means for cooling blood after blood collection, does not provide a sufficient cooling effect, and cooling takes a long time. In addition, there is a demand for means for cooling the blood bag even in a place where a large-sized cooling device such as a refrigerator cannot be installed, such as a blood collection site on a business trip of the blood center.

Therefore, the present inventor has found no variation in the temperature of the whole blood product, which has been varied before the step of removing leukocytes before storage, up to 25 ° C. at which optimum removal performance can be obtained by the leukocyte removal filter. As a result of intensive studies on an invention that can be adjusted easily and quickly uniformly, the inventors have reached the following invention.
[1] The present invention provides:
A housing (2);
A cooling means (3) for the blood bag (B);
Rocking means (4) of the blood bag (B);
Waste heat means (5),
Means for measuring the temperature of blood in the blood bag (B) (6);
Informing means (7) for notifying that the blood temperature has reached the target temperature;
Display means (8) for target temperature, measured temperature and oscillation speed;
Storage means (10) for storing setting conditions of the target temperature and swing speed;
A power supply (11);
Having control means (9),
The cooling means (3) comprises a Peltier element having an endothermic surface (3.1),
The swinging means (4) is a means for swinging the cooling means (3) together with the blood bag (B) in the horizontal rotation direction, and the swinging means (4) includes a motor (4.1) and A support member that supports the cooling means (3) and the exhaust heat means (5);
The control means (9) controls the power supplied to the cooling means (3), the motor (4.1) of the swing means (4), the notification means (7), and the display means (8). ,
Mounted on the upper part of the housing (2) with the endothermic surface (3.1) of the cooling means (3) facing up,
Disposing the heat removal means (5) on the heat generation surface opposite to the heat absorption surface (3.1) of the cooling means (3),
A support member for the swinging means (4) is disposed below the exhaust heat means (5);
Place the blood bag (B) on the endothermic surface (3.1) of the cooling means (3) and cool it while swinging in the horizontal rotation direction,
Monitoring the temperature of blood in the blood bag (B) by means of temperature measuring means (6);
Detecting that it has been cooled to a set temperature, and notifying the operator by means of the notification means (7),
A blood cooling device (1) capable of stopping the cooling of the blood bag (B), stopping the voltage supplied to the motor (4.1) and stopping the swinging means (4). I will provide a.
[2] The present invention provides:
A tray (22.2) for the blood bag (B);
Oscillating means (24) arranged at the bottom of the saucer (22.2);
The blood bag (B), the saucer (22.2) and the swinging means (24) have a storage space for storing them integrally, and the storage space is hermetically sealed with a lid (22.1) to provide a vacuum chamber ( 22VR) housing (22),
further,
Cooling means (23) for the blood bag (B);
First temperature measuring means (22.7a) and / or second temperature measuring means (22.7b) of blood in the blood bag (B);
Informing means (27) for notifying the operator that the temperature of the blood bag (B) has reached the target temperature;
Display means (28) for target temperature, measured temperature, and oscillation speed;
Storage means (30) for storing set values of the target temperature and oscillation speed;
Control means (29),
The cooling means (23) comprises a Peltier element having an endothermic surface (3.1),
The cooling means (23) is disposed between the saucer (22.2) and the swinging means (24), and the heat absorption surface of the cooling means (23) is disposed in contact with the saucer (22.2). And the heating surface is arranged so as to contact the exhaust heat means (25),
The swinging means (24) is disposed below the exhaust heat means (25),
A blood collection device (21) is provided in which the heat exhausting section (25.2) is connected to the heat exhausting means (25) via the heat conducting section (25.1).
[3] The present invention provides:
The tray (22.2) of the blood cooling device (21) according to [2], the cooling means (23), the swinging means (24), the heat exhausting means (25), the heat conducting section (25.1), and In place of each arrangement of the heat exhaust section (25.2),
The end of the heat conducting part (25.1) is connected to the lower part of the saucer (22.2), and the other end of the heat conducting part (25.1) is connected to the heat absorbing surface of the cooling means (23). connection,
The exhaust heat means (25) is attached to the heat generating surface of the cooling means (23),
The swinging means (24) is arranged at the bottom of the saucer (22.2),
A blood collection device (21.1) is provided in which the heat removal means (25) is mounted outside the housing (22).
[4] The present invention provides:
The blood bag (B) placed on the saucer (21) has a cooling cover (C) that can cover it, and a heat conduction part (25.12) is connected to the cover (C) [2] Alternatively, the blood collection device (21, 21.1) according to [3] is provided.
[5] The present invention provides:
The first temperature measuring means (22.7a) is a non-contact infrared radiation thermometer, and the first temperature measuring means (22.7a) is placed on the wall surface of the housing (22) in the vacuum chamber (22VR). The blood collection device (21, 21.1) according to any one of [2] to [4] is provided.
[6] The present invention provides:
The second temperature measuring means (22.7b) is any one selected from a contact-type thermocouple thermometer, a platinum resistance thermometer, and a thermistor,
[2] to [5], wherein the second temperature measuring means (22.7b) is mounted on the top surface of the plate (22.2) described above (A) and / or (B) mounted on the cover (C). The blood collection device according to any one of (21, 21.1).

In the blood cooling device 1 of the present invention,
(1) By setting the blood temperature after blood collection to a temperature suitable for leukocyte removal, better leukocyte removal performance than before can be obtained in product manufacturing operations.
(2) Since the blood bag can be cooled in a small size and in a short time, it can be loaded in a narrow space such as a blood donation bath, and the current problem that cannot load a large device such as a refrigerator can be solved.
In the blood collection device (21, 21.1) of the present invention,
(3) Since the blood bag is cooled while collecting blood in the blood bag, the trouble of cooling later can be omitted, and the workability is improved.

[Blood cooling device 1]
FIG. 1 is an overall view (appearance) of a blood cooling device 1 of the present invention (hereinafter may be simply abbreviated as “device 1”), and FIG. 2 is an entire use state in which a blood bag B is arranged in FIG. 3 is a schematic view (side view) of the internal structure of FIG. 1, FIG. 4 is a schematic view (perspective view) of the internal structure of FIG. 1, and FIG. 5 is a block diagram of the blood cooling apparatus 1 of the present invention. . In FIG. 2, B1 is a parent bag, B2 is a child bag, and T is a tube connecting them. Hereinafter, for convenience of explanation, the parent bag B1 will be described and described as a blood bag B.

As illustrated in FIGS. 1 to 4, the blood cooling device 1 of the present invention has a cooling means 3 attached to the upper part (top surface) of the housing 2, and the lower part of the cooling means 3 (inside the housing 2). An exhaust heat means 5 is disposed. Further, the swinging means 4 is arranged below the heat exhausting means 5 (inside the housing 2).
Display means 8, power supply unit 11, and operation means 12 are arranged on the surface of housing 2 (the top surface or any one of the side surfaces). (In addition, the notification means 7 can be arranged if necessary.)
The blood cooling apparatus 1 of the present invention employs a Peltier element as the cooling means 3, and the blood bag B is placed on the cooling means 3 (Peltier element) and cooled while swinging.
The temperature of the blood in the blood bag B is monitored by the temperature measuring means 6 to detect that the blood has been cooled to the set temperature, and the notifying means 7 notifies the operator or the like.
As illustrated in FIG. 5, the blood cooling device 1 of the present invention includes a cooling means 3 for the blood bag B, a temperature measuring means 6 for blood in the blood bag B, and a notification means 7 for notifying that the target temperature has been reached. A target temperature / measured temperature / oscillation speed display means 8, a storage means 10 for storing the target temperature / oscillation speed setting conditions, and a control means 9 for each of these means.

[Cooling means 3]
The cooling means 3 is formed in a plate shape (dish shape) or an arcuate slope so that the contact surface is along the roundness of the expanded state of the blood bag B. By absorbing, it plays the role of cooling the blood bag B.
A “Peltier element” is used as the cooling means 3 of the present invention. A “Peltier element” is a plate-like semiconductor element that uses the Peltier effect in which heat is transferred from one metal to the other when an electric current is passed through the junction of two types of metal. When applied, one surface absorbs heat (an endothermic surface) and the opposite surface generates heat (a heat generating surface). Since it is small and does not generate noise and vibration, it is generally used as a CPU cooling means for computers and a cooling means for medical equipment.
The cooling means 3 (Peltier element) is arranged in the housing 2 with the heat absorption surface 3.1 facing up. Since heat is generated on the side opposite to the endothermic surface 3.1, the heat exhausting means 5 is arranged to release the heat so that the generated heat does not affect the endothermic surface.

[Oscillating means 4]
The swinging means 4 is disposed at the lower part of the cooling means 3 (Peltier element) (inside the housing 2), and swings the cooling means 3 together with the blood bag B in the horizontal rotation direction.
By absorbing heat while swinging (shaking) the blood bag B in the horizontal rotation direction, the blood in the blood bag B circulates and the cooling effect can be enhanced.
As illustrated in FIGS. 3 to 4, the oscillating means 4 includes an electric motor 4.1 and support members (support 4.2 and support frame 4.3) (of the cooling means 3).
The power of the motor 4.1 is transmitted to the support members (the support column 4.2 and the support frame 4.3) through the shaft 4.4, the worm wheel 4.5, and the worm 4.6.
The speed of the motor 4.1 is controlled by the control means 9 described later. The speed of oscillation can be adjusted by controlling the speed of the motor 4.1.
The rocking means 4 can adopt a seesaw type or a three-dimensional compound rocking method in addition to the horizontal rocking method exemplified here.

[Exhaust heat means 5]
For example, a heat radiating plate (heat sink) made of a metal such as copper or aluminum, a cooling fan, or the like can be used as the heat exhausting means 5.
[Temperature control means and temperature measurement means 6]
As temperature control means for lowering the blood in the blood bag B to 25 ° C., which is a temperature suitable for leukocyte removal, (A) a thermocouple temperature measuring means 6 (sometimes referred to as “temperature sensor”) is applied to the blood bag. A means for monitoring the temperature and (B) means for statistically deriving the endothermic time of blood for each amount of collected blood and making the time for applying the voltage timed can be employed.
As the temperature measuring means 6, for example, a thermocouple, a contact type such as a platinum resistance thermometer or a thermistor, a non-contact type infrared radiation thermometer, or the like can be used.
The temperature measured by the temperature measuring means 6 is compared with the target temperature, and when the target temperature is reached, the control section 9 can output the information to the notification means 7 and the display means 8.
Therefore, in the present invention, the temperature control means means the temperature measurement means 6 or the temperature measurement means 6 and the control unit 9.

[Notification means 7]
The notification means 7 can use a buzzer, light emission, or the like in order to inform the operator that the target temperature has been reached.
[Display means 8]
The display means 8 employs a 7-segment LED, a liquid crystal screen, etc., and can display the temperature set as a target, the temperature currently measured, and the speed of the swing mechanism as numerical values.
Moreover, an LED lamp, a liquid crystal screen, etc. are employable as a display means which alert | reports the ON state of a power supply, or the state which reached target temperature.
[Control means 9]
As the control means 9, a means using a built-in microcomputer (CPU), a means using software operating on a personal computer (PC) outside the apparatus 1, and the like can be adopted as in a general embedded system device. . For example, when the device 1 is operated alone, control by the former built-in microcomputer (CPU) can be selected, but a plurality of devices 1 are operated for a plurality of blood bags B to manage temperature changes. In the case of recording, the means using the latter software can be selected. In that case, the control means 9 includes a communication means 13 such as a USB port or RS-232C in order to communicate with the PC.
The control means 9 can control the power supplied to the cooling means 3 (Peltier element), the motor 4.1, the notification means 7, and the display means 8. For example, when the temperature of the blood bag B measured by the temperature measuring unit 6 reaches the target temperature stored in the storage unit 10, the indicator lamp of the display unit 8 is turned on or the notification unit 7 is sounded. Or let it come out. Furthermore, the voltage supplied to the cooling means (Peltier element) 3 can be stopped to stop the cooling of the blood bag B, or the voltage supplied to the motor 4.1 can be stopped to stop the oscillation.

[Storage 10]
The storage means 10 is for storing target temperature setting conditions and swing speed setting conditions. As the storage means 10, a DRAM, a flash memory, or the like can be employed. In addition, when the control is performed from an external PC, the setting conditions can be stored on the HDD of the PC.
[Power supply unit 11]
The power supply unit 11 supplies power to the cooling unit 3 (Peltier element), the motor 4.1, the temperature measurement unit 6, the notification unit 7, the display unit 8, and the storage unit 10 through the control unit 9. The power supply unit 11 is provided with a power switch 11.1 and can switch ON / OFF of power feeding.
[Operating means 12]
The operation means 12 is for starting the operation of the blood cooling device 1, setting a target temperature, and controlling the speed of the motor 4.1, and may adopt a dial type or a switch type. it can.

[Description of Operating Method of Blood Cooling Device 1]
(1) Turn on the power by turning on the power switch 11.1.
(2) A target set temperature is input by the operating means 12. Further, the speed of the swinging means 4 is set. (This operation can be omitted by storing the setting in the storage means 10 for the second and subsequent uses.)
(3) The blood bag B after blood collection is placed on the endothermic surface 3.1 of the cooling device 3 (Peltier element).
(4) Further, the temperature measuring means 6 is set in the blood bag B. (When the non-contact type temperature measuring means 6 is used, this operation can be omitted by arranging the temperature measuring means 6 at a position where the temperature of the blood bag B can always be measured.)
(5) The start switch 12.1 is pressed to operate the blood cooling device 1.
(6) When the target temperature is reached, the notification means 7 (sound, light emission) and the display means 8 notify. [At this time, the heat absorption operation of the cooling means 3 (Peltier element) is stopped, but the swinging means 4 may be left activated. ]
(7) Remove blood bag B.
(8) When the work is finished, turn off the power by turning off the power switch 11.1.

[Blood collection device 21]
6 to 11 are schematic views of the blood collection device 21 (21.1) of the present invention on which the cooling means 3 (Peltier element) is mounted. FIG. 6 is an overall view (outside view), and FIG. 7 is a blood collection device. 21 is a schematic view (cross-sectional view), FIG. 8 is a schematic view (cross-sectional view) showing another embodiment of the blood collection device 21.1, and FIG. 9 is a block diagram.

As illustrated in FIGS. 6 to 7, the blood collection device 21 of the present invention integrally accommodates the tray 22. 2 of the blood bag B, the swinging means 24 disposed below the tray 22.2, and these. The housing 22 has a housing space, and the housing space is hermetically sealed with a lid 22.1 to form a vacuum chamber 22VR (vacuum structure). Between the tray 22.2 and the swinging means 24, Cooling means 23 is arranged.
More specifically, the cooling means 23 is attached to the lower part of the tray 22.2, the exhaust heat means 25 is attached to the lower part of the cooling means 23, and the swinging means 24 is disposed below the exhaust heat means 25. .
The cooling means 23 arrange | positions the part which contacts the saucer 22.2 as a heat absorption surface, and arrange | positions the part which contacts the exhaust heat means 25 as a heat generating surface.
Further, the heat exhausting means 25 is connected to the heat exhausting part 25.1 via the heat conducting part 25.1, and the heat of the blood bag B absorbed by the cooling means 23 from the heat exhausting part 25.2 is received by the housing 22. It is trying to discharge outside.

Display means 28, power supply 31 (power switch 31.1), and operation means 32 are disposed on the surface of housing 22 (the top surface or any one of the side surfaces). (Note that the notification means 27 can also be arranged if necessary.)
On the upper part of the housing 22, a clamp 34 of the tube T1 and a clamp release lever 34.1 are mounted.
The housing 22 includes a pressure and temperature in the vacuum chamber 22VR, pressure measuring means 22.5 (also referred to as a pressure sensor) for controlling these, pressure control means 22.6, and first temperature measuring means 22. .7a are installed.
The first temperature measuring means 22.7a is mounted on the wall surface of the housing 22 in the vacuum chamber 22VR so as to be positioned (arranged) with respect to the blood bag B placed on the tray 22.2.

Further, although not shown in detail, a weight measuring means 22.3 and a control means 29 (not shown) are arranged inside the housing 22.
As shown in the block diagram of FIG. 9, the control unit 29 includes the swinging unit 24, the cooling unit 23, the weight measuring unit 22.3, the first temperature measuring unit 22.7a (mounted on the housing 22 as illustrated in FIG. 7). The second temperature measuring means 22.7b (attached to the pan 22.2 of the blood bag B and the cover C as exemplified in FIG. 8 described later) is performed. Details will be described later.
The swinging means 24 is not shown in detail, but, for example, like the blood collecting apparatus described in Japanese Patent Application Laid-Open No. 2000-84067, the driving means (motor) and the support member of the saucer 22.2 (from the column and the shaft) And the support member has means (worm and worm wheel) for transmitting a driving force to the saucer 22.2 by the driving means. The saucer 22.2 is formed by a support member and a driving means, and a three-dimensional composite swing of a vertical swing in the front-rear direction and a vertical swing in the horizontal direction,
Further, as in the cooling device 1 of FIG. 1, horizontal swinging and seesaw swinging can be performed.

[Cooling means 23]
As the cooling means 23, the cooling means 3 (Peltier element) of the blood cooling apparatus 1 is used.
[Exhaust heat means 25]
As the exhaust heat means 25, the exhaust heat means 5 of the blood cooling device 1 is used.
[Heat conduction part 25.1]
As the heat conducting portion 25.1, for example, a heat tube made of a metal such as copper or aluminum, or a tube made of a resin material such as polyethylene filled with a radiator liquid is used.
The tube (heat conduction part 25.1) filled with the radiator liquid is a pump having a small radiator liquid between the heat absorbing surface of the cooling means 23, the receiving tray 22.2, and the cover C (only the blood collection device 21.1 in FIG. 8). A mechanism that circulates using the can be employed.
[Notification means 27]
As the notification means 27, the notification means 7 of the blood cooling apparatus 1 is used.
[Display means 28]
As the display means 28, the display means 8 of the blood cooling apparatus 1 is used.
[Weight measuring means 22.3]
As the weight measuring means 22.3, for example, a load cell is used.
[Decompression pump 22.4]
For example, a vacuum pump is used as the decompression pump 22.4.
[Pressure measuring means 22.5]
As the pressure measuring means 22.5, for example, a diaphragm type pressure gauge is used.
[Pressure control means 22.6]
The pressure control means 22.6 is a valve that can be electrically controlled, for example, disposed in a pipe connecting the vacuum chamber VR and the outside air, and a vacuum solenoid is used.
[First temperature measuring means 22.7a]
As the first temperature measuring means 22.7a, a non-contact infrared radiation thermometer is used.
[Second temperature measuring means 22.7b]
As the second temperature measuring means 22.7b, a contact-type thermocouple thermometer, a platinum resistance thermometer, a thermistor, or the like is used. First temperature measuring means 22.7a (mounted on the housing 22 as illustrated in FIG. 7), second temperature measuring means 22.7b (as illustrated in FIG. 8 described later), the tray 22. 2 attached to the cover C), either one may be used, or both may be used together.

[Control means 29]
As the control means 29, the control means 9 of the blood cooling apparatus 1 is used.
As illustrated in FIG. 9, the control means 29 includes a cooling means 23 (Peltier element), a motor (oscillating means 24), a notification means 27, a display (similar to the control means 9 of the blood cooling device 1). The power supplied to the means 28 can be controlled. For example, when the temperature of the blood bag B measured by the temperature measuring means 22, 7a (22.7b) reaches the target temperature stored in the storage means 30, the indicator lamp of the display means 28 is turned on. Or make the notification means 27 make a sound. Further, the voltage supplied to the cooling means (Peltier element) 23 is stopped to stop the cooling of the blood bag B, or the voltage supplied to the motor (swing means 24) is stopped to stop the swinging. it can.
Similarly to the known blood collection device disclosed by the applicant [for example, JP 2000-84067 A (other JP 2005-253991 A, JP 2005-152626 A)], And “driving unit”.
The “control unit” includes an input / output circuit in addition to the above means. A detection signal of a swing speed detection sensor (fixed position stop sensor) of the saucer 22.2 is transferred to the input / output circuit. The storage means 30 can store data such as the tare amount of the blood bag B, the negative pressure generated in the storage space, and the set blood collection amount. The “control section” is connected to display means 28 and operation means 32 (including various switches, an operation panel having a drive circuit, a setting panel, etc.), and these input data are transferred to the control means 29.1.
The “drive unit” is connected to the “control unit” and includes two conversion circuits A / D (analog → digital) and D / A (digital → analog). One conversion circuit A / D is connected to weight measuring means 22.3 and pressure measuring means 22.5 via a switch and an amplifier AP, respectively. A motor (drive means 24) is connected to the other conversion circuit D / A via a drive circuit DC. Furthermore, a decompression pump 22.4 is connected to each other drive circuit DC via a clamp solenoid, a vacuum solenoid, and a power control unit, and the clamp solenoid, pressure control means 22.6 (vacuum solenoid), The vacuum pump 22.4 and the motor (driving means 24) are controlled.

In addition, the blood collection device 21.1 illustrated in FIG. 8 has an end of the heat conducting portion 25.1 connected to the lower portion of the tray 22.2 and the other end of the heat conducting portion 25.1 is connected to the cooling means. The heat removal means 25 is attached to the heat generation surface (the surface opposite to the heat absorption surface) of the cooling means 23.
In order to increase the cooling efficiency of the blood bag B, the exhaust heat means 25 is attached to the outside of the housing 22.
Further, in order to increase the cooling efficiency, a cover C (an endothermic sheet made of an endothermic gel) that is in direct contact with the blood bag B placed on the tray 21 can be used in combination with the cooling means 23. The cover C is also connected to the heat conducting portion 25.12. The other end of the heat conducting part 25.12 is connected to the heat absorbing surface of the cooling means 23.
The second temperature measuring means 22.7b is attached to both the saucer 22.2 (the top surface thereof) and the cover C.
One of the second temperature measuring means (22.7b) is mounted on the top surface of the plate 22.2 which is in contact with the blood bag B mounted on the tray 22.2, and the other is blood of the cover C. It is mounted on the surface that contacts bag B.
The blood bag B is cooled by inducing heat from the endothermic surface of the cooling means 23 to the tray 22.2 and the cover C through the heat conductors 25.1 and 25.12.
Since the other configuration of the blood collection device 21.1 is substantially the same as that of the blood collection device 21 of FIG.
Detailed description is omitted.
In addition, the cover C which attached the 2nd temperature measurement means 22.7b and connected the heat conduction part 25.12 can also be used for the blood collection apparatus 21 of FIG. In the blood collection device 21, the other end of the heat conducting unit 25.12 is connected to the heat absorbing surface (or the heat exhausting unit 25.2) of the cooling means 23.

[Description of operating method of blood collection device 21 (21.1)]
(1) Turn on the power by turning on the power switch 31.1.
(2) A target set temperature is input by the operation means 32. Furthermore, the speed of the rocking means 24, the target blood collection amount to collect blood, and the negative pressure are set. (This operation can be omitted by storing the setting in the storage means 32 for the second and subsequent uses.)
(3) Place an empty blood bag B before blood collection on the saucer 22.2, secure the blood flow by puncturing a blood collection needle N into the donor's vein, and close the lid 22.1 of the vacuum chamber 22VR. Then, the start switch 32.1 is pressed to start blood collection.
(4) With the start of blood collection, the receiving tray 22.2 starts cooling (the cover C is also cooled in the blood collection device 21.1 in FIG. 8). At the same time, the temperature measurement means 22.7a (22.7b) starts measuring the temperature of the collected blood from when the blood collection is started.
(5) When the target blood collection amount is reached, the blood collection tube T1 is closed by the clamp 34, the vacuum state is released, and the blood collection is finished. However, the cooling means 23 and the swinging means 24 are set to the target temperature measured by the temperature measurement means 26. It continues to operate until it reaches the temperature.
(6) When the target temperature is reached, the notification means 27 (sound, light emission) and the display means 28 notify.
[Although the heat absorption operation of the cooling means 23 (Peltier element) is stopped, the swinging means may be left activated. ]
(7) Remove blood bag B from blood collection device 21 (21.1).
(8) When the work is completed, turn off the power by turning off the power switch 31.1.

[Cooling test of blood cooling device 1]
A prototype for confirming the cooling effect of the blood cooling apparatus 1 described in FIGS. 1 to 5 was produced as shown in FIG.
As a blood bag B, a 400 mL bag made by Kawasumi Chemical Industry Co., Ltd. (internal volume CPD solution 56 mL) is used, and as shown in FIG. 10, the blood bag is subjected to a drop through a blood bag tube T from a beaker filled with 36 ° C. warm water. 400 mL of water was collected in B, the temperature was measured by temperature measuring means 6 (thermocouple) inserted into blood bag B, and recorded by a recorder.
The temperature of the test chamber was kept at 25 ° C., and the test was performed in two ways: a condition where cooling was performed by the cooling means 3 (Peltier element) and a condition where cooling was not performed.
The sampling time is set to 8 minutes and 20 seconds, which is typical for actual blood sampling, and a flowmeter with a flow rate adjustment function is installed in a beaker and blood bag so that there is no difference in time due to variations in flow rate. Placed in the blood bag tube T between B, the flow rate was set to 0.8 mL / sec.
As the cooling means 3 (Peltier element), an Ohm electric machine (model 0CE-40P-D24) was used.
The test results are shown in FIG. 11 (graph).
From the result of FIG. 11 (graph), the temperature of the water in the blood bag B that was not cooled reached 30 ° C. in about 2 minutes after the start of sampling, but in the blood bag B that was cooled. The water temperature did not exceed 25 ° C. from the start of sampling until the end of sampling.
In addition, the temperature was measured while maintaining the test state for 4 minutes after the completion of water sampling, but it was confirmed that the temperature decreased greatly when cooling was performed.

Overall view of blood cooling device of the present invention (appearance) Overall view of the usage state with the blood bag shown in Fig. 1 (appearance) Schematic diagram (side view) of the internal structure of FIG. Schematic diagram (in perspective) of the internal structure of FIG. Block diagram of the blood cooling device of the present invention Overall view (appearance) of blood collection apparatus of the present invention Schematic (cross-sectional view) of the blood collection apparatus of the present invention Schematic (cross-sectional view) showing another embodiment of the blood collection apparatus of the present invention Block diagram of the blood collection apparatus of the present invention Schematic which shows an example of the cooling test of the blood cooling device of this invention. The graph which shows the test result of FIG.

Explanation of symbols

1 Blood Cooling Device 2 Housing 3 Cooling Means (Peltier Element)
3.1 Heat absorbing surface 4 Oscillating means 4.1 Motor 4.2 Support column 4.3 Support frame 4.4 Shaft 4.5 Worm wheel 4.6 Worm 5 Heat exhausting means 6 Temperature measuring means (temperature sensor)
7 Informing means 8 Display means 9 Control means 10 Storage means 11 Power supply 11.1 Power switch 12 Operation means 12.1 Start switch 13 Communication means B1 (B) Parent bag (blood bag)
B2 Child bag T Tube 21 (21.1) Blood collection device 22 Housing 22.1 Cover (cover)
22.2 Saucer 22.3 Weight measuring means 22.4 Pressure reducing pump 22.5 Pressure measuring means 22.6 Pressure control means (pressure sensor)
22.7a First temperature measuring means 22.7b Second temperature measuring means 22VR Vacuum chamber 23 Cooling means 24 Oscillating means 25 Heat exhausting means 25.1 Heat conducting section 25.12 Heat conducting section 25.2 Heat exhausting section 26 Temperature Measuring means (temperature sensor)
27 Notification means 28 Display means 29 Control means 30 Storage means 31 Power supply 31.1 Power switch 32 Operation means 32.1 Start switch 33 Communication means 34 Clamp 34.1 Clamp release lever N Blood collection needle T1 Tube C Cover

Claims (6)

A housing (2);
A cooling means (3) for the blood bag (B);
Rocking means (4) of the blood bag (B);
Waste heat means (5),
Means for measuring the temperature of blood in the blood bag (B) (6);
Informing means (7) for notifying that the blood temperature has reached the target temperature;
Display means (8) for target temperature, measured temperature and oscillation speed;
Storage means (10) for storing setting conditions of the target temperature and swing speed;
A power supply (11);
Having control means (9),
The cooling means (3) comprises a Peltier element having an endothermic surface (3.1),
The swinging means (4) is a means for swinging the cooling means (3) together with the blood bag (B) in the horizontal rotation direction, and the swinging means (4) includes a motor (4.1) and A support member that supports the cooling means (3) and the exhaust heat means (5);
The control means (9) controls the power supplied to the cooling means (3), the motor (4.1) of the swing means (4), the notification means (7), and the display means (8). ,
Mounted on the upper part of the housing (2) with the endothermic surface (3.1) of the cooling means (3) facing up,
Disposing the heat removal means (5) on the heat generation surface opposite to the heat absorption surface (3.1) of the cooling means (3),
A support member for the swinging means (4) is disposed below the exhaust heat means (5);
Place the blood bag (B) on the endothermic surface (3.1) of the cooling means (3) and cool it while swinging in the horizontal rotation direction,
Monitoring the temperature of blood in the blood bag (B) by means of temperature measuring means (6);
Detecting that it has been cooled to a set temperature, and notifying the operator by means of the notification means (7),
The cooling of the blood bag (B) can be stopped, the voltage supplied to the motor (4.1) can be stopped, and the swinging of the swinging means (4) can be stopped.
The blood cooling device (1) characterized by the above-mentioned. A tray (22.2) for the blood bag (B);
Oscillating means (24) arranged at the bottom of the saucer (22.2);
The blood bag (B), the saucer (22.2) and the swinging means (24) have a storage space for storing them integrally, and the storage space is hermetically sealed with a lid (22.1) to provide a vacuum chamber ( 22VR) housing (22),
further,
Cooling means (23) for the blood bag (B);
First temperature measuring means (22.7a) and / or second temperature measuring means (22.7b) of blood in the blood bag (B);
Informing means (27) for notifying the operator that the temperature of the blood bag (B) has reached the target temperature;
Display means (28) for target temperature, measured temperature, and oscillation speed;
Storage means (30) for storing set values of the target temperature and oscillation speed;
Control means (29),
The cooling means (23) comprises a Peltier element having an endothermic surface (3.1),
The cooling means (23) is disposed between the saucer (22.2) and the swinging means (24), and the heat absorption surface of the cooling means (23) is disposed in contact with the saucer (22.2). And the heating surface is arranged so as to contact the exhaust heat means (25),
The swinging means (24) is disposed below the exhaust heat means (25),
The exhaust heat means (25) was connected to the exhaust heat section (25.2) via the heat conduction section (25.1).
A blood collection device (21) characterized by the above. The tray (22.2) of the blood cooling device (21) according to claim 2, the cooling means (23), the swinging means (24), the exhaust heat means (25), the heat conduction part (25.1), and In place of each arrangement of the heat exhaust section (25.2),
The end of the heat conducting part (25.1) is connected to the lower part of the saucer (22.2), and the other end of the heat conducting part (25.1) is connected to the heat absorbing surface of the cooling means (23). connection,
The exhaust heat means (25) is attached to the heat generating surface of the cooling means (23),
The swinging means (24) is arranged at the bottom of the saucer (22.2),
A blood collecting device (21.1), wherein the heat exhausting means (25) is mounted outside the housing (22). It has a cooling cover (C) that can cover the blood bag (B) placed on the saucer (21), and a heat conduction part (25.12) is connected to the cover (C). The blood collection device (21, 21.1) according to claim 2 or claim 3, characterized by the above. The first temperature measuring means (22.7a) is a non-contact infrared radiation thermometer, and the first temperature measuring means (22.7a) is placed on the wall surface of the housing (22) in the vacuum chamber (22VR). The blood collection device (21, 21.1) according to any one of claims 2 to 4, which is mounted. The second temperature measuring means (22.7b) is any one selected from a contact-type thermocouple thermometer, a platinum resistance thermometer, and a thermistor,
The second temperature measuring means (22.7b) is (A) mounted on the top surface of the dish (22.2) and / or (B) installed on the cover (C). The blood collection device (21, 21.1) according to any one of claims 2 to 5.

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