JP2830443B2 - Blood bag heater - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION <Industrial Application Field> The present invention relates to a blood bag heater mounted on a blood sampling device or the like to heat blood in a blood bag.

<Prior Art> FIG. 3 is a diagram showing a general configuration of a blood sampling apparatus, in which 1 is an arm of a blood donor, 2 is an ACD liquid bag storing an ACD liquid, and 3 is a physiological saline. A raw food bag storing water, 4 is a blood bag for storing collected blood, 4 'is a weight detector for detecting the weight of the blood bag 4, and 5 is plasma for storing plasma separated from the collected blood. Plasma bag, 6 is a drainage bag for storing drainage, 7a to 7f are first to sixth detectors for detecting each fluid (such as ACD liquid and physiological saline), 8a to 8e are ACD liquid pumps, First to fifth pumps called a blood pump, a circulation pump, an air pump, and a plasma pump (in which the second pump 8b and the fourth pump 8d are pumps capable of sending fluid in both forward and reverse directions), 9a To 9 g are first to seventh clamps for opening and closing the respective flow paths through which the respective fluids flow, and 10 a to 10 d are first clamps. Fourth pressure gauge, 11 a to 11 c of the first to
The third chamber, 12a and 12b, are a blood detector and a hemolysis detector, respectively, and 13 is a membrane 13a that passes plasma and does not pass blood cell components.
For example, a separator 14 having a double-tube structure, the inside of which is divided into an inner chamber 13b and an outer chamber 13c, is a needle which is punctured into the arm 1 of the blood donor.

In the blood collection apparatus having such a configuration, the blood circuit (the first chamber 11a, the second pump 8b, the blood bag 4, the third
Pump 8c, second chamber 11b, separator 13, and third
A priming operation of washing the inside of a flow path through which blood flows through the chamber 11 and the like with a physiological saline solution, storing blood collected from a donor in a blood bag 4 and then leading the blood to the blood circuit to form the separator 13 An operation of collecting blood plasma and a blood collecting operation of collecting blood flowing through the blood circuit are performed.

Note that the weight detector 4 'is not always necessary, and the weight detector 4' may be removed from the blood bag 4 when a later-described blood bag heater is attached to the blood bag. In the case of a cholesterol removing device (commonly called COMET) or the like, only the blood bag heater is mounted on the blood bag.

<Problems to be Solved by the Invention> However, a conventional blood bag warmer (not shown) mounted on the blood bag 4 of the above-described blood sampling apparatus has an aluminum plate attached to a heating element. I could only heat it. Therefore, when the blood pump 8b stops and the blood in the blood bag stops, the temperature of the blood rises due to the heat capacity of the aluminum plate even if the power supplied to the heating element is reduced to zero. As a result, hemolysis may occur. The present invention has been made in view of the drawbacks of the conventional example, and has as its object to provide a warmer for a blood bag which does not reach a temperature at which blood causes hemolysis.

<Means for Solving the Problems> A feature of the present invention that solves the above-described problems is that a control temperature setting unit that sets a desired set temperature in a blood bag heater, A power control unit that receives a set temperature signal from the unit, a heating unit that heats the blood bag according to a command from the power control unit, and a cooling unit that cools the blood bag according to a command from the power control unit. A temperature measuring unit for detecting the temperature of the blood bag, so that even if the power supplied to the heating unit becomes zero, the cooling unit is operated so that the measured temperature does not become higher than the set temperature. Control.

<Example> Hereinafter, the present invention will be described in detail with reference to the drawings. FIG. 1 is a block diagram of an embodiment of the present invention. In the figure, reference numeral 15 denotes a control temperature setting unit such as a setting unit of a microcomputer, 16 denotes a power control unit, 17 denotes a heating unit formed of, for example, a heater, 18 Is a cooling unit composed of, for example, an electronic cooler, and 19 is a temperature measuring unit composed of, for example, a thermistor.

FIG. 2 is a flowchart for explaining the operation of the present invention. Hereinafter, according to this flowchart,
The operation of the embodiment of the present invention will be described.

Advance, setting the desired temperature T ₁ of the control temperature setting unit 15. Set temperature signal S ₁ is controlled temperature setting unit indicating the temperature T ₁ of
From 15 is transmitted to the power control unit 16. Also, the temperature measuring section
The measurement signal S ₂ indicating the detected temperature T ₂ is sent from the temperature measuring unit 19 to the power control unit 16 in 19.

In this state, when the operation of the embodiment of the present invention starts,
The power control unit 16 reads the set temperature signals S ₁ and the measurement signal S _2, then, the power control unit 16 obtains the deviation of the set temperature signals S ₁ and the measurement signal S _2, the power so that this deviation becomes zero (The power supplied to the heating unit 17). afterwards,
It is determined whether the power supplied to heating section 17 is zero or not. If it is determined not to be zero, a deviation reads power control unit 16 sets the temperature signals S ₁ and the measurement signal S _2, the operation of controlling the power so that this deviation becomes zero is repeated.

When the power supplied to the heating unit 17 is determined to be zero, whether high or not than the measured temperature T ₂ is the set temperature T _1. If it is determined to be low, the power control unit 16
There a deviation reads the set temperature signals S ₁ and the measurement signal S _2, this deviation to control the power to be zero, then the power supplied to the heating unit 17 determines whether zero or The operation is repeated.

If the measured temperature T ₂ is determined to be higher than the set temperature T ₁ of the power supplied from the power control unit 16 to the cooling unit 18 is controlled. That is, even when the power is zero, which is supplied to the heating unit 17, when the measured temperature T ₂ is about to become higher than the set temperatures T ₁ actuates the cooling unit 18, the measurement temperature T ₂
There is controlled not higher than the set temperature T _1.

The present invention is not limited to the above-described embodiment, and various modifications are possible. For example, the cooling unit 18 may be water-cooled instead of electronically-cooled, and the signals handled by the control system are analog signals and digital signals. Or a mixed signal.

<Effects of the Invention> According to the present invention as described in detail above, unlike the case of the conventional example, since the cooling unit is provided, sufficient power can be supplied from the power control unit to the heating unit and the cooling unit, and as a result, A blood bag warmer that does not reach a temperature at which blood causes hemolysis with improved control characteristics is realized.

That is, in the case of the conventional example having no cooling means, the temperature rise is determined by the heat capacity of the plate portion and the amount of blood in the blood bag, so that the power to the heating portion is limited when trying to operate safely. And it takes time to raise the temperature. However, according to the present invention, since the cooling unit is provided, sufficient power can be supplied from the power control unit to the heating unit and the cooling unit. As a result, the control characteristics are improved and the setting is performed regardless of the presence or absence of blood flow. Another advantage is that the temperature can be controlled.

[Brief description of the drawings]

FIG. 1 is a block circuit diagram of an embodiment of the present invention, FIG. 2 is a flowchart for explaining the operation of the embodiment of the present invention, and FIG.
The figure is an explanatory diagram of a general configuration of a blood sampling apparatus. 1 ... arm of the donor 2 ... ACD liquid bag 3 ... saline bag 4 ... blood bag 4 '... weight detector 5 ...
Plasma bag, 6 ... Drainage bag, 7a-7f ... Detector, 8a
... 8e Pump, 9a-9g Clamp, 10a-10d Pressure gauge, 11a-11c Chamber, 12a, 12b Blood detector and hemolysis detector, 13 Separator, 14 Needle , 15 ...
... Control temperature setting section, 16 ... Power control section, 17 ... Heating section, 18 ... Cooling section, 19 ... Temperature measuring section

Claims (1)

(57) [Claims] 1. A blood bag warmer mounted on a blood sampling device or the like for warming blood in a blood bag, wherein a control temperature setting section for setting a desired set temperature, and a set temperature signal from the control temperature setting section. A power control unit, a heating unit that heats the blood bag according to a command from the power control unit, a cooling unit that cools the blood bag according to a command from the power control unit, and a temperature of the blood bag. And a temperature measuring unit for detecting the temperature, wherein even if the electric power supplied to the heating unit becomes zero, the cooling unit is operated to control the measured temperature so as not to be higher than the set temperature. Characteristic warmer for blood bags.