KR101248865B1 - A device to detect blood temperature for safe blood services - Google Patents

Abstract

It is attached to the outer surface of the blood storage pack that stores the blood, and is located on the upper part of the identification unit where the state characteristic changes according to the temperature of the blood. Disclosed is a blood temperature sensing device for checking a temperature of blood.
Blood temperature sensor for checking the temperature of the blood for safe blood management disclosed is attached to one side of the blood storage pack for storing the blood, and stores the information of the stored blood and the surface color changes according to the temperature of the stored blood Identification unit for changing the state characteristic irreversibly; And located at an upper portion of the identification unit, reading information stored in the identification unit through a reader, calculating blood temperature information based on a change in light quantity according to a change in state characteristics of the identification unit, and calculating the calculated blood temperature information and And a sensor processing unit for transmitting the information read by the reader to the outside.

Description

Blood temperature sensor to check the temperature of blood for safe blood management {A DEVICE TO DETECT BLOOD TEMPERATURE FOR SAFE BLOOD SERVICES}

The present invention is to identify the temperature of the blood stored in the storage pack during the blood management and distribution process, more specifically attached to the outer surface of the blood storage pack for storing blood, blood temperature information based on the change in the amount of light It relates to a technique for calculating the.

Blood management refers to the comprehensive blood management and distribution process from blood donation to test and supply, inventory management, and disposal, and the blood cells and plasma collected from the human body to maintain the cleanliness of blood and improve public health through proper blood management. And blood products, which are blood-related drugs prescribed by Ordinance of the Ministry of Health and Welfare and whole blood, concentrated red blood cells, fresh frozen plasma, concentrated platelets, and other health and welfare directives. Such blood is collected and then supplied to a hospital for transfusion, or sent to a pharmaceutical company to fractionate each component of the blood and manufactured as a blood product containing the necessary components as a major component, which is then supplied to an unspecified number of patients.

In general, blood donation refers to the collection and management of blood from a healthy person so that a blood transfusion operation is performed in a blood vessel of a patient who lacks blood or its components.

Blood collected by a single blood donation is sealed in a blood storage pack and stored for a certain period of time, and a blood information label including information such as blood type, blood date, control number, and barcode is attached to one surface of each blood storage pack. . Each blood storage pack is stored in a refrigerator or freezer and periodically checks whether the container (pack) and label are broken, turbidity and discoloration, hemolysis, and the like.

However, this identification method has a problem that it is difficult to identify the temperature of the blood stored in each blood storage pack that is most important for blood storage.

In addition, even if you store multiple blood storage packs in one storage location, each blood temperature may vary depending on the storage location. You should check.

However, it is time-consuming and costly to measure the blood temperature of each blood storage pack. Rather, there is a concern that the storage state of the blood deteriorates or the blood deteriorates during the measurement of the periodic blood temperature.

That is, in the related art, since the administrator directly managed the blood storage pack by directly checking the temperature of the blood stored in the blood storage pack, there was a problem that the efficiency of blood management was lowered.

In addition, even when the blood is not stored at the proper temperature and is deteriorated, it appears to be stored normally, and there was a problem that the accuracy of blood storage and management is lowered.

In addition, conventionally, by identifying the temperature of the blood storage environment, it is possible to determine only the current temperature state, there was a problem that can not determine what state the blood has been stored in the past.

In order to solve this problem, conventional methods using Zion ink or RFID have been proposed. However, in the case of Zion ink, the manufacturing method is treated as a gas tightly, so that the use range is limited and the change process cannot be confirmed by the reversible reaction.

In addition, in case of RFID, many readers / writers have to continuously generate and measure signals, so additional costs are inevitable, and the use of radio waves is restricted to prevent interference with medical devices in places such as operating rooms. There was a problem that the range is limited.

Accordingly, the present invention has been proposed to solve the above problems,

An object of the present invention is to provide a blood temperature sensing device for checking the temperature of the blood for safe blood management for automatically detecting the temperature of the blood stored in the blood storage pack.

In addition, another problem to be solved by the present invention, to automatically read the information of the blood stored in the blood storage pack, and to check the temperature of the blood for safe blood management to calculate the exact blood temperature based on the change in light quantity It is to provide a blood temperature sensing device.

In addition, another problem to be solved by the present invention, blood temperature sensing device for checking the temperature of the blood for safe blood management to facilitate the fastening and separation of the sensor processing unit, and to transmit the temperature of the calculated blood to the outside To provide.

In addition, another object of the present invention is to provide a blood temperature sensing device for identifying the temperature of the blood with the naked eye, and to check the temperature of the blood for safe blood management to increase the ability to identify the color indicating the temperature To provide.

In addition, another problem to be solved by the present invention is a blood temperature sensing device for storing the information of the stored blood, and to check the temperature of the blood for safe blood management for providing the temperature information of the blood according to the displayed color To provide.

In addition, another object of the present invention is to provide a blood temperature sensing device that displays a variety of colors according to the blood storage method, and checks the temperature of the blood for safe blood management to protect the upper surface and the like. .

According to the present invention for solving the above problems "blood temperature sensing device for checking the temperature of the blood for safe blood management",

An identification unit attached to one surface of a blood storage pack for storing blood, storing information of the stored blood, and changing a surface color according to the temperature of the stored blood, the state characteristic being irreversibly changed; And

Located above the identification unit, the information stored in the identification unit is read through a reader, blood temperature information is calculated based on the change in the amount of light according to the change in the state characteristic of the identification unit, and the calculated blood temperature information and the And a sensor processing unit for transmitting the information read by the reader to the outside.

In addition, the sensor processing unit, characterized in that formed to be separated from the identification unit can be reused.

In addition, the sensor processing unit, a power supply for supplying power; A light source connected to the power supply unit to emit light to the identification unit; It is connected to the illumination sensor provided in the identification unit, the control unit for calculating blood temperature information based on the result detected by the illumination sensor and connected to the control unit, characterized in that it comprises a storage unit for storing the blood temperature information do.

The sensor processor may further include an input / output terminal for transmitting blood temperature information of the storage unit and receiving external information.

The identification unit may include: a temperature identification layer whose surface color changes according to the temperature of blood stored therein; Located on the lower portion of the temperature identification layer, the photoresist layer irreversibly change state characteristics according to the temperature of the blood stored therein; Located in the lower portion of the photosensitive agent layer, the illumination sensor for detecting the amount of light passing through the photosensitive agent layer and located in the lower portion of the illumination sensor, characterized in that it comprises an adhesive layer attached to the outer surface of the blood storage pack for storing blood It is done.

The identification unit may further include a reflective layer positioned between the temperature identification layer and the photosensitive agent layer to increase identification power of colors displayed on the temperature identification layer.

The identification unit may further include an information layer for storing information of blood stored in the blood storage pack, wherein the information layer is located between the adhesive layer and the illuminance sensor.

In addition, the information layer is characterized in that using a barcode, RFID or QR code.

In addition, the temperature identification layer, characterized in that it comprises a color display unit for changing the color in multiple steps according to the temperature of the blood and a temperature information unit for displaying the temperature information of the blood according to the color of the color display.

In addition, the color display unit, characterized in that formed in two or more areas having a difference in the temperature range of the display color.

In addition, the identification unit, the coating layer for protecting the upper surface of the temperature identification layer;

Located above the coating layer, and further comprising a light shielding layer for protecting the temperature identification layer and the photosensitive agent layer.

According to the present invention, the temperature of the blood stored in the blood storage pack can be automatically calculated, and the accurate temperature is calculated using the change in the amount of light, thereby improving the efficiency of blood management.

In addition, since the information of the stored blood can be read automatically, there is an effect that can manage the blood more efficiently.

In addition, the fastening and detachment of the sensor processing unit can be facilitated, so that the utilization rate of the sensor processing unit can be improved, and blood temperature information can be easily transmitted to the outside.

In addition, by changing the surface color in accordance with the temperature of the blood, there is an advantage that can identify the temperature of the blood even with the naked eye, there is an advantage to improve the discriminating power of the displayed color.

In addition, by having a bar code, RFID or QR code stored in the stored blood information, there is an effect that can additionally obtain the information of the stored blood, and can provide blood temperature information for each color, two or more It is possible to display various colors according to the blood storage method through the color display.

In addition, it is possible to reduce the influence of the temperature stimulus generated from the outside, there is an advantage that can identify the temperature of the blood more accurately.

1 is a cross-sectional view showing an embodiment of the present invention.
Figure 2 is a side view showing an embodiment of the present invention identification unit.
Figure 3 is a block diagram showing an embodiment of the sensor processing unit of the present invention.
Figure 4 is an embodiment showing the temperature identification unit of the present invention.
Figure 5 is another embodiment showing the temperature identification unit of the present invention.
6 is a plan view showing another embodiment of the sensor processing unit of the present invention.
7 is a perspective view showing a state of use of the present invention.

Hereinafter, a preferred embodiment of the blood temperature sensing device of the present invention will be described in detail with reference to the accompanying drawings.

1 is a cross-sectional view showing an embodiment of the present invention, the blood temperature sensing device 40 is composed of the identification unit 10 and the sensor processing unit 20. The identification unit 10 is for identifying the temperature of the blood stored in the blood storage pack 100 and to store the information of the stored blood, the sensor processing unit 20 automatically measures the temperature of the blood from the identification unit 10 To calculate and read the stored information.

The identification unit 10 is attached to one surface of the blood storage pack 100, and the sensor processing unit 20 is attached to the top of the identification unit 10 is formed.

2 is a side view showing an embodiment of the present identification unit, the identification unit 10 is the adhesive layer 11, the information layer 12, the illuminance sensor 13, the photoresist layer 14, the reflective layer 15, The temperature identification layer 16, the coating layer 17, and the light shielding layer 18 are formed.

The adhesive layer 11 is formed on the front of the lowermost layer of the identification unit 10, and serves to fix and attach the identification unit 10 to the surface of the blood storage pack 100.

The illuminance sensor 13 is formed on the adhesive layer 11 and detects the amount of light that has passed through the identification unit 10. In the present invention, the amount of light is detected using the CDS illuminance sensor. The illuminance sensor 13 is the most basic sensor of the optical sensor, and serves to convert the electrical properties to the brightness of the light. In particular, CDS is the most commonly used illuminance sensor. It is not suitable to increase the resistance linearly with brightness but rather close to the log graph, so it is suitable for determining the 'bright / dark' degree rather than obtaining accurate LUX value. Sensor.

CDS Ambient Light Sensor has high resistance like insulator in the dark and low resistance like conductor when visible light touches, and can detect light sources in various areas from visible light to infrared light and simplify the circuit configuration. It can be done.

In the present invention, a CDS illuminance sensor is used, but a photodiode, a phototransistor, and a photocoupler may be used.

The photosensitive agent layer 14 is formed on the illuminance sensor 13 and consists of a photosensitive agent. Photosensitizers generally refer to organic and inorganic compositions in which physical and chemical changes occur under the action of heat, light, and radiation energy, or compositions based on light irradiation. That is, when heat is applied to the photosensitive agent, chemical and physical changes in the molecular structure occur, and physical property changes such as change in solubility (solubilization or insolubilization), coloring, and curing of a certain solvent occur.

That is, by forming the photosensitive agent layer 14 as a photosensitive agent, physical and chemical changes occur in the photosensitive agent according to the temperature of blood stored therein. The change corresponds to an irreversible change, so that the changed state is maintained even when the temperature changes again.

Therefore, after the photosensitive agent layer 14 is changed to a state other than the proper temperature for safely storing blood, the blood storage pack 100 containing the blood is left at a temperature higher than the proper temperature. Physical and chemical changes occur. Thereafter, even when the blood storage pack 100 is placed at an appropriate temperature state, the state of the photosensitive agent layer 14 remains unchanged.

Whether the photoresist layer 14 has been physically or chemically changed is determined using the illuminance sensor 13. That is, since the amount of light detected by the illuminance sensor 13 changes when the photosensitive agent layer 14 is physically and chemically changed, the storage state of the blood storage pack 100 may be determined using the photosensitive agent layer 14.

By the above-described method, if it is determined that the blood storage pack 100 has not been stored at an appropriate temperature state, the blood storage pack 100 can be quickly recovered to perform a detailed examination of the blood state.

In addition, the identification unit 10 according to the present invention preferably further forms a reflective layer 15 on the photoresist layer 14. The reflective layer 15 is formed of a thin metal film to block the light from the outside, and serves to improve the discriminating power of the color displayed on the temperature identification layer 16.

In addition, the identification unit 10 according to the present invention preferably further forms an information layer 12 on the adhesive layer 11. The information layer 12 is formed between the adhesive layer 11 and the illuminance sensor 13, the information layer 12 stores the blood information stored in the blood storage pack 100. That is, information such as blood type, blood date and time, management number, etc. are stored, and a barcode, RFID or QR code may be used as the information layer 12.

In addition, since the temperature change does not occur by the information layer 12, the temperature identification layer 16 is not affected. As a result, accurate temperature identification is possible in the temperature identification layer 16.

In addition, by using in parallel with the existing blood information label 50, there is an advantage that the utilization of the stored blood information is improved and the amount of information obtainable is increased.

The temperature identification layer 16 is formed on the reflective layer 15 and is a printed layer whose surface color changes according to the temperature of blood contained therein.

The Zion Ink is also called 'Zion Pigment', 'Temperature Pigment', and 'Thermocolor' and is largely water-based in 9 standard colors. In addition, the Zion ink may be prepared by setting a change temperature in a variety of -16 ℃ to 70 ℃ according to the user's purpose.

For example, in the case of the blue Zion ink that changes at 20 ° C., the color appears blue at 20 ° C. or lower, and when the temperature is 22 ° C., the color disappears. A variety of Zion colors may be expressed by mixing the Zion Inks. For example, two Zion Inks may be combined to express different colors, or two or more Zion Inks having different temperatures may be mixed and expressed in different colors. .

In addition, when the temperature is increased by mixing the general ink and the Zion ink is expressed as two mixed colors, when the temperature is increased, the color of the Zion ink disappears and only the general ink color is displayed.

Reversible Zion Ink and irreversible Zion Ink can also be used to determine the past temperature change as well as the current temperature of the blood.

All parts of the temperature identification layer 16 may be coated with Zion ink, and as shown in FIG. 4, the temperature identification layer 16 may be formed of a color display unit 160 and a temperature information unit 163. . That is, the color display unit 160 is a portion formed by the Zion ink that changes color depending on the temperature, and the temperature information unit 163 serves to display the temperature information of the blood according to the color of the color display unit 160.

For example, transfusion whole blood and red blood cell concentrate are stored in a blood-only refrigerator at 1 to 6 ° C., as shown in the embodiment of the present invention, the Zion pigment of the color display unit 160 is stored at a temperature of about 1 ° C. or less to about 7 ° C. or more. It is formed to display in a multi-level color of about 2 ℃ range, and compare the color displayed on the color display unit 160 with the temperature information described in the temperature information unit 163, easily identify the blood temperature for each blood storage pack 100 with the naked eye You can do it.

In other words, according to the color displayed on the color display unit 160, it is possible to check whether the temperature of the blood maintains the proper storage temperature, and identify that the temperature of the surface color shown in the color display unit 160 is not suitable for the blood storage temperature If it is, it can be recovered quickly and the blood state can be examined closely.

In addition, the color display unit 160 may be composed of two or more areas according to the blood storage method.

For example, the blood may be refrigerated storage and frozen storage, and when the refrigerated and frozen storage, the difference in the storage temperature range is much, as shown in Figure 5 the color display unit 160 consisting of two areas In this case, the first region 161 is formed to indicate blood temperature when refrigerated, and the remaining second region 162 is formed to indicate blood temperature when frozen.

At this time, the temperature information unit 163 also provides temperature information according to refrigeration or freezing storage.

In addition, it is preferable that the identification unit 10 according to the present invention further form a coating layer 17 on the temperature identification layer 16.

The coating layer 17 not only protects the surface of the temperature identification layer 16 but also has an effect of reducing the influence of external temperature stimulation when displaying the color according to the blood temperature. The coating layer 17 is preferably made of a transparent material in order to express the color of the color display unit 160 and the temperature information unit 163 to the outside.

In addition, the identification unit 10 according to the present invention preferably further forms a light shielding layer 18 on the coating layer 17.

The light blocking layer 18 not only protects the surface of the temperature identification layer 16, but also has an effect of reducing the influence of external temperature stimulation of the temperature identification layer 16 and the photosensitive agent layer 14.

That is, since the temperature identification layer 16 changes color according to temperature, the temperature of the blood is minimized by minimizing the influence of external temperature, and the photosensitive agent layer 14 is physically and chemically changed depending on the temperature so that the external Minimize the effect of temperature so that it can change with the temperature of the blood.

In particular, since the photoresist layer 14 has an irreversible characteristic, it serves to prevent the state characteristic of the photoresist layer 14 from being deformed by the external environment before the identification unit 10 is used.

In addition, the light shielding layer 18 is preferably made of a material that blocks light to protect the temperature identification layer 16 and the photosensitive agent layer 14 from the external environment.

In the above, the structure and function of the identification part 10 of this invention were demonstrated in detail. Hereinafter, the sensor processing unit 20 of the present invention will be described in detail.

2 is a block diagram illustrating an embodiment of the sensor processing unit 20 of the present invention, wherein the sensor processing unit 20 includes a power supply unit 21, a light source 22, a control unit 23, a transmission module 24, and a storage unit ( 25), the input / output terminal 26 and the reader 27

The power supply unit 21 serves to supply power to each of the components of the sensor processing unit 20, and is preferably configured as an independent power supply.

The light source 22 serves to emit light to the identification unit 10, and the light source 22 is preferably provided at a position corresponding to the illuminance sensor 13. That is, the light emitted from the light source 22 passes through the identification unit 10 and is configured to be detected by the illumination sensor 13, and the illumination sensor 13 detects the amount of light passing through the identification unit 10.

Specifically, the photosensitive agent layer 14 causes physical and chemical changes by the temperature of the blood stored in the blood storage pack 100. If a physical or chemical change occurs in the photoresist layer 14, the amount of light passing through the photoresist layer 14 also changes. Since the amount of light detected by the illuminance sensor 13 is changed by this phenomenon, the temperature of the blood stored in the blood storage pack 100 is calculated using this.

In addition, in order to accurately measure the temperature of blood, the color of the temperature identification layer 16 and the state of the photoresist layer 14 should not be changed by the light emitted from the light source 22. Therefore, the intensity of the light emitted from the light source 22 is adjusted so that the color of the temperature identification layer 16 and the state of the photosensitive agent layer 14 are not changed by the emitted light.

The controller 23 calculates a temperature of blood stored in the blood storage pack 100 based on the amount of light detected by the illuminance sensor 13. That is, the photosensitive agent layer 14 causes physical and chemical changes according to the change in blood temperature, and the amount of light detected by the illuminance sensor 13 through the photosensitive layer 14 is changed by the change.

Using this phenomenon, the controller 23 calculates a temperature of blood based on the detected amount of light. Since the illuminance sensor 13 detects even a minute change, it may calculate an accurate temperature of blood.

In addition, the temperature of the blood calculated by the controller 23 is stored in the storage 25.

In addition, the sensor processing unit 20 according to the present invention preferably further includes a reader 27. The reader 27 reads the information stored in the identification unit 10. That is, the reader 27 automatically reads the information of the stored blood stored in the information layer 12 and transmits the read information to the control unit 23. The control unit 23 stores the information read by the reader 27 in the storage unit 25 or transmits the information using the transmission module 24 or the input / output terminal 26.

In addition, since the information layer 12 is formed of a barcode, RFID or QR code, the reader 27 is provided to read the information layer 12.

In addition, the sensor processing unit 20 according to the present invention preferably further comprises a transmission module (24).

The transmission module 24 is connected to the control unit 23, and serves to transmit the blood temperature information calculated by the control unit 23 and the information read by the reader 27 to the outside, the transmission module 24 is wireless Information is transmitted using communication.

That is, by including the transmission module 24, without having to open and close the blood storage to check the information and the blood temperature of the stored blood, you can check the temperature of the blood sealed in each blood storage pack 100 from the outside There is an advantage.

In addition, the sensor processing unit 20 according to the present invention further includes an input / output (USB-universal serial bus) terminal 26 on an external side as shown in FIG. 6.

The input / output terminal 26 is a separate input / output connection terminal for transmitting blood information and blood temperature information stored in the storage unit 25 to the outside and receiving external information according to blood temperature calculation. Even when data communication is not possible through, it can be used to check the temperature change trend of the specific blood storage pack 100.

In order to secure the distance between the lower surface of the light source 22 and the upper surface of the identification unit, the sensor processing unit 20 according to the present invention preferably forms a part of the outer surface of the sensor processing unit 20 step by step.

In addition, it is preferable to include a fastening unit 30 for fastening the identification unit 10 and the sensor processing unit 20. That is, the fastening protrusion may be formed in the identification unit 10 and the fastening groove may be formed in the sensor processing unit 20 to fasten the identification unit 10 and the sensor processing unit 20. ), The identification unit 10 and the sensor processing unit 20 may be fastened.

In addition, the identification unit 10 and the sensor processing unit 20 may be combined using an adhesive, and in this case, it is preferable to fasten the detachable unit.

In general, although the sensor processing unit 20 fastened to the blood storage pack 100 is formed, after use of the blood, it is discarded together with the blood storage pack 100, but as in the embodiment of the present invention, the sensor processing unit 20 As can be attached and detached, even if the blood stored in the blood storage pack 100 is used, since only the sensor processing unit 20 is separated, it can be used by fastening to the identification unit 10 of the other blood storage pack, the sensor There is an advantage that can increase the reuse rate of the processing unit 20.

In the above, the structure and function of the sensor processing part 20 of this invention were demonstrated in detail. Hereinafter, the use state of the blood temperature detecting device 40 of the present invention will be described in detail.

As shown in FIG. 7, a blood information label 50 including information such as blood type, blood date and time, a management number, and a barcode of the blood storage pack 100 is attached. The blood temperature sensor 40 of the present invention is attached to a portion where the blood information label 50 is not attached.

When the blood temperature detecting device 40 is used, the control unit 23 controls to emit light from the light source 22, and the illuminance sensor 13 detects the amount of light passing through the identification unit 10. The controller 23 calculates a temperature of blood stored in the blood storage pack 100 based on the amount of light detected by the illuminance sensor 13. The temperature of the blood calculated by the controller 23 is stored in the storage 25 or transmitted to the outside through the transmission module 24.

Based on the temperature of the blood calculated by the controller 23, if the calculated temperature is identified as not suitable for the blood storage temperature, it can be quickly recovered, and the blood condition can be closely inspected. That is, since the exact temperature of the blood is automatically calculated, there is an effect that can improve the efficiency of blood storage and management.

In addition, the reader 27 may read information such as blood type, blood date and time, and management number of the stored blood, and transmit the read information to the outside through the transmission module 24.

In addition, the temperature of the blood stored in the blood storage pack 100 may be visually confirmed by the color of the temperature identification layer 16.

Although the embodiments of the present invention have been described above, the technical idea of the present invention is not limited to the above embodiments, and various blood temperature sensing devices may be implemented in a range that does not depart from the technical idea of the present invention.

10... Identification
11 ... Adhesive layer 12.. Information layer
13 ... Light sensor 14.. Photoresist layer
15... Reflective layer 16... Temperature identification layer
17 ... Coating layer 18... Shading layer
20... Sensor processing part
21 ... Power supply section 22. Light source
23 ... Control unit 24. Transmission module
25... Storage unit 26.. I / O terminal
27 ... Reader
30 ... The fastening portion
40 ... Blood temperature sensing device
50... Blood Information Label
100... Blood storage pack

Claims (11)

An identification unit attached to one surface of a blood storage pack for storing blood, storing information of the stored blood, and changing a surface color according to the temperature of the stored blood, the state characteristic being irreversibly changed; And
Located above the identification unit, the information stored in the identification unit is read through a reader, blood temperature information is calculated based on the change in the amount of light according to the change in the state characteristic of the identification unit, and the calculated blood temperature information and the It includes a sensor processing unit for transmitting the information read from the reader to the outside,
The identification unit,
A temperature identification layer whose surface color changes according to the temperature of blood stored therein; Located on the lower portion of the temperature identification layer, the photoresist layer irreversibly change state characteristics according to the temperature of the blood stored therein; Located in the lower portion of the photosensitive agent layer, the illumination sensor for detecting the amount of light passing through the photosensitive agent layer and located in the lower portion of the illumination sensor, characterized in that it comprises an adhesive layer attached to the outer surface of the blood storage pack for storing blood Blood temperature sensor for checking the temperature of the blood for safe blood management.
The method according to claim 1,
The sensor processing unit is a blood temperature sensing device for confirming the temperature of the blood for safe blood management, characterized in that formed and separated from the identification unit can be reused.
The method according to claim 2, The sensor processing unit,
A power supply for supplying power; A light source connected to the power supply unit to emit light to the identification unit; It is connected to the illumination sensor provided in the identification unit, the control unit for calculating blood temperature information based on the result detected by the illumination sensor and connected to the control unit, characterized in that it comprises a storage unit for storing the blood temperature information Blood temperature sensor to check the temperature of the blood for safe blood management.
The method of claim 3, wherein the sensor processing unit, the blood temperature detection for confirming the temperature of the blood for safe blood management, characterized in that it further comprises an input and output terminal for transmitting the blood temperature information of the storage unit, receiving external information Device.
delete The method of claim 1, wherein the identification unit, located between the temperature identification layer and the photosensitive agent layer, for the safe blood management, characterized in that further comprising a reflective layer for enhancing the identification of the color displayed on the temperature identification layer Blood temperature sensor to check the temperature of blood.
The blood of claim 6, wherein the identification unit further comprises an information layer for storing information of blood stored in the blood storage pack, wherein the information layer is located between the adhesive layer and the illuminance sensor. Blood temperature sensor to check the temperature of blood for management.
The blood temperature sensing apparatus of claim 7, wherein the information layer uses a barcode, an RFID, or a QR code.
The safe blood of claim 1, wherein the temperature identification layer includes a color display unit in which the color changes in multiple steps according to the temperature of the blood, and a temperature information unit displaying temperature information of blood according to the color of the color display unit. Blood temperature sensor to check the temperature of blood for management.
The blood temperature sensing device of claim 9, wherein the color display unit is formed of two or more regions having a difference in a temperature range of the display color.
The method of claim 6, wherein the identification unit, The coating layer for protecting the upper surface of the temperature identification layer; Located on top of the coating layer, the blood temperature sensing device for checking the temperature of the blood for safe blood management, characterized in that it further comprises a light shielding layer for the protection of the temperature identification layer and the photosensitive agent layer.

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