KR102152747B1 - Fluid temperature adjusting device - Google Patents

Abstract

In order to solve the problem that the patient suffers pain in lowering the patient's body temperature, the problem that additional infection may occur to the patient, and the problem of not being able to supply the patient with fluid at an appropriate temperature, the upper pad and the lower part are selectively contacted by each inner surface. A thermally conductive pad including a pad, a seating groove formed on each of the upper pad and the lower pad to form a path into which the transfusion tube is inserted, an electronic cooling element provided on an outer surface of the pad, and an outer surface of the electronic cooling element It provides a fluid temperature control device including a heat sink provided in.

Description

Fluid temperature control device {FLUID TEMPERATURE ADJUSTING DEVICE}

The present invention relates to a fluid temperature control device capable of supplying to a patient by controlling the temperature of the fluid.

In diseases such as cardiac arrest and traumatic brain injury, it is very important to control the patient's body temperature so that it does not become excessively high.

To lower the patient's body temperature, there are a surface cooler method and an endovascular cooler method. In the former method, a low-temperature object is brought into contact with the patient's skin, and in the latter method, the body fluid is extracted and cooled and injected back into the patient's body.

In the case of the electronic method, since it cools the patient's skin, it can cause pain to the patient, and it is cumbersome for clinical use because the device must be installed all over the body.

In the case of the latter method, since the body fluid is extracted and then injected back into the body, the patient may be infected.

In addition to the above two methods, there is a method of lowering the patient's body temperature by supplying a low-temperature fluid to the patient. The method of supplying low-temperature sap is useful in that it is essential in the case of diseases in which body temperature is generally excessively increased.

In a method of supplying a low-temperature sap, in the related art, a sap bag containing sap was stored in a refrigerator and then taken out and supplied to the patient.

However, in this method, condensation occurs in the cooled sap bag, and the water generated on the surface of the sap bag adversely affects nearby devices or causes a possibility of infection of the patient.

In addition, it is difficult to check the temperature of the sap in real time, and even if it can be checked, it is difficult to adjust or maintain the sap to a desired temperature.

An object of the present invention is to solve the above-described problem, a problem in which pain occurs in a patient in lowering the patient's body temperature, a problem in which additional infection may occur in the patient, and a problem in which a fluid at an appropriate temperature cannot be supplied to the patient.

In order to achieve the above or other objects, according to an aspect of the present invention, a thermally conductive pad including an upper pad and a lower pad selectively in contact with each inner surface, the upper pad and the lower pad are formed respectively to form an infusion tube. It provides a fluid temperature control apparatus including a seating groove forming a path to be fitted, an electronic cooling element provided on an outer surface of the pad, and a heat sink provided on an outer surface of the electronic cooling element.

In addition, according to another aspect of the present invention, the path of the seating groove provides a fluid temperature control device, characterized in that it includes a plurality of parallel rows and a plurality of bent portions connecting the plurality of rows.

In addition, according to another aspect of the present invention, there is provided an infusion temperature control device further comprising an upper case covering the upper pad and a lower case covering the lower pad.

In addition, according to another aspect of the present invention, there is provided a fluid temperature control apparatus further comprising a hinge portion hingedly coupling the upper case and the lower case so that the upper pad and the lower pad are selectively opened and closed.

In addition, according to another aspect of the present invention, a temperature controller connected to the electronic cooling element to control heat dissipation of the electronic cooling element based on the temperature of the sap, and a fluid temperature measuring unit that measures the temperature of the sap passing through the sap tube. It provides a fluid temperature control device further comprising.

In addition, according to another aspect of the present invention, there is provided an infusion temperature control device further comprising a temperature measurement terminal coupled to a point of the infusion tube to provide a temperature measurement surface of the infusion solution to the infusion temperature measurement unit.

In addition, according to another aspect of the present invention, the temperature measurement terminal, one side forms the temperature measurement surface and the other side protrudes to a point of the infusion tube and a probe needle made of a metal material in contact with the infusion solution through one point of the infusion tube. It provides a fluid temperature control device including an outer peripheral surface of the branch and a cap surrounding the probe needle.

In addition, according to another aspect of the present invention, the temperature controller provides an infusion temperature control device, characterized in that the temperature of the infusion solution is calculated based on the temperature measured by the infusion temperature control device and the physical properties of the probe needle. .

In addition, according to another aspect of the present invention, a flow rate measuring device for measuring the amount of sap introduced into the pad, and a flow rate for controlling the amount of sap flowing into the pad based on the amount of influent sap measured by the flow rate measuring device It provides a fluid temperature control device including a generating device.

In addition, according to another aspect of the present invention, there is provided an infusion temperature control device further comprising an output unit that outputs at least one of the flow rate of the infusion solution, the temperature of the infusion solution, and the volume of the infusion solution injected so far.

In addition, according to another aspect of the present invention, a temperature measurement terminal that is detachably coupled to a point protruding from a point of the infusion tube passing through the pad, and the temperature of the infusion solution passing through one point of the infusion tube in contact with the temperature measurement terminal Including an infusion temperature measuring unit to measure, the temperature measuring terminal, the cap surrounding the outer circumferential surface of the protruding branch of the infusion tube, and a probe needle penetrating inside the protruding branch of the infusion tube and contacting the infusion solution, the probe needle It provides a fluid temperature control device including a metallic material.

In addition, according to another aspect of the present invention, the probe needle is configured in a conical shape whose cross-sectional area decreases toward one end, and provides an infusion temperature control device including a temperature measuring surface formed in a conical bottom region.

In addition, according to another aspect of the present invention, a thermally conductive pad, a seating groove formed on the pad to form a path into which the transfusion tube is inserted, a case for mounting the pad and forming an opening in one area, the outer surface of the pad An electronic cooling element in contact with and a heat sink in contact with an outer surface of the electronic cooling element, wherein the electronic cooling element and the heat sink provide a fluid temperature control device provided in the one region.

In addition, according to another aspect of the present invention, a temperature controller connected to the electronic cooling element to control heat dissipation of the electronic cooling element based on the temperature of the sap, and a fluid temperature measurement that measures the current temperature of the sap passing through the sap tube. It provides a fluid temperature control device further comprising a portion.

In addition, according to another aspect of the present invention, there is provided an infusion temperature control device further comprising a temperature measurement terminal coupled to a point of the infusion tube to provide a temperature measurement surface of the infusion solution to the infusion temperature measurement unit.

In addition, according to another aspect of the present invention, the temperature measurement terminal, one side forms the temperature measurement surface and the other side protrudes to a point of the infusion tube and a probe needle made of a metal material in contact with the infusion solution through one point of the infusion tube. It provides a fluid temperature control device including an outer peripheral surface of the branch and a cap surrounding the probe needle.

The effect of the fluid temperature control device according to the present invention will be described as follows.

According to at least one of the embodiments of the present invention, there is an advantage in that the temperature of the sap can be lowered by minimizing the occurrence of condensation.

In addition, according to at least one of the embodiments of the present invention, there is an advantage that the infusion tube can be easily replaced.

In addition, according to at least one of the embodiments of the present invention, there is an advantage that the temperature of the sap can be kept constant.

In addition, according to at least one of the embodiments of the present invention, there is an advantage that the temperature measuring unit of the sap can be easily replaced.

In addition, according to at least one of the embodiments of the present invention, there is an advantage of minimizing the possibility of infection that may additionally occur in the patient.

Further scope of applicability of the present invention will become apparent from the detailed description below. However, since various changes and modifications within the spirit and scope of the present invention can be clearly understood by those skilled in the art, detailed description and specific embodiments such as preferred embodiments of the present invention are understood to be given by way of example only. Should be.

1 (a) is a perspective view of an infusion temperature control device associated with the present invention, and FIG. 1 (b) is an exploded perspective view of an infusion temperature control device related to the present invention.
2 is a cross-sectional view taken along the AA′ direction of FIG. 1(a).
3(a) is an enlarged view of area B of FIG. 1(a), and FIG. 3(b) is an enlarged view of area C of FIG. 1(b).
4 is a cross-sectional view of FIG. 3(b) in the DD' direction.
5 is an overall configuration diagram of an infusion temperature control device related to the present invention.
6 is a block diagram showing the control flow of the infusion temperature control device related to the present invention.

1 is a combined and exploded perspective view of a fluid temperature control device 10 related to the present invention.

1(a) is a perspective view of an infusion temperature control device 10, and FIG. 1(b) is an exploded perspective view of the infusion temperature control device 10. As shown in FIG.

The infusion solution radiates heat while passing through the infusion tube 100 provided between the pads 200, so that the temperature decreases, and the infusion solution whose temperature decreases passes through the pad 200 and is administered to the patient.

The pad 200 receives heat from the infusion solution passing through the infusion tube 100 and transfers the heat to the heat sink 410 exposed to the outside of the temperature control device 10. Therefore, the pad 200 may include a material having high thermal conductivity.

The heat sink 410 refers to a configuration made to easily receive heat from the pad 200.

As an example, the heat sink 410 may be formed of a metal material including a plurality of radiating fins 411. The heat sink 410 may maximize a cross-sectional area relative to the volume through the plurality of radiating fins 411. The larger the cross-sectional area, the higher the heat dissipation efficiency into the air.

Alternatively, in some cases, the heat sink 410 may include a configuration such as cooling water or a heat pipe. The heat of the pad 200 may be taken away by using the specific heat of the liquid or the phase change of the material.

The electronic cooling element 400 is provided between the pad 200 and the heat sink 410. One side of the electronic cooling element 400 contacts the pad 200 and the other side contacts the heat sink 410 to perform heat transfer.

The electronic cooling element 400 takes heat from the pad 200 by applying a current and transfers it to the heat sink 410. This effect is referred to as the Peltier Effect, and a configuration that generates this effect is also referred to as a Peltier device. The pad 200 must effectively take heat from the fluid passing through the fluid tube 100. Accordingly, the pad 200 is preferably provided in close contact with the infusion tube 100.

The pad 200 may be made of a material such as thermal grease, a thermal compound, and a thermal pad so as to sufficiently generate thermal-coupling. In order to provide the infusion tube 100 and the pad 200 in close contact with each other, the pad 200 may have a seating groove 210 on the inner side 2001.

The seating groove 210 may be provided in a shape corresponding to the outer surface 1001 of the infusion tube 100. The seating groove 210 may be sufficiently implemented not to cover and cover the entire length of the infusion tube 100, but to cover a partial area.

The seating groove 210 forms a path through which the infusion tube 100 of a predetermined length is inserted. Since the infusion tube 100 is provided as a replacement type, the infusion tube 100 must be attached to and detached from the pad 200. Accordingly, the pad 200 may be provided in a configuration of an upper pad 200a and a lower pad 200b that are selectively coupled.

It is advantageous that the seating groove 210 is formed to be elongated in the inner surface 2001 of the pad 200. This is because, as the heat dissipation is performed on the infusion tube 100 with a large area, a temperature drop can be relatively easily caused.

In order to secure the length of the seating groove 210 formed in the pad 200, the seating groove 210 may include a plurality of bent portions 212.

The mounting groove 210 may include a path shape having a plurality of parallel rows 211 as shown in FIG. 1. The plurality of parallel rows 211 may be connected through a plurality of bent portions 212.

When the inner surface 2001 of the pad 200 is rectangular, if the seating groove 210 is composed of a combination of a plurality of linear parallel rows 211 and a plurality of bent portions 212, it will be provided with a high density compared to the area. I can. This increases the likelihood of being within the effective range of the electronic cooling element 400 and the heat sink 411, and thus efficient heat dissipation is possible.

However, the path of the seating groove 210 is not necessarily limited to the above-described shape, and it is sufficient if the length of the infusion tube 100 is provided in a shape and arrangement such that it is inserted into the pad 200 so that the temperature drop of the infusion solution is sufficient. Figure 2 is a cross-sectional view in the direction AA' of Figure 1 (a). For convenience of explanation, it will be described with reference to FIG. 1.

The seating groove 210 may be symmetrically provided on the upper pad 200a and the lower pad 200b. That is, based on the cross-section of the infusion tube 100, the lower half of the fluid may be in close contact with the lower pad 200b, and the upper half may be in close contact with the upper pad 200a.

The electronic cooling element 400 and the heat sink 410 may be provided by being coupled to the outer surface 2002 of the pad 200. That is, the electronic cooling element 400 and the heat sink 410 may be provided by being coupled to the outer surface 2002 of at least one of the upper pad 200a or the lower pad 200b. When provided on both sides of the pad 200, heat dissipation of high output is possible.

The case 300 surrounds the pad 200 to protect the pad. The case 300 may include an upper case 300a and a lower case 300b. The upper case 300a covers the upper pad 200a, and the lower case 300b covers the lower pad 200b.

The case 300 may secure a space in which the electronic cooling element 400 directly contacts the pad 200 by forming an opening 301 in one area. The electronic cooling element 400 is provided in the opening 301 of the case 300 so that one surface 4001 contacts a region of the pad 200 and the other surface 4002 contacts the heat sink 410 to provide heat. Carry out delivery.

As the upper case 300a and the lower case 300b are selectively coupled, each inner surface 2001 of the upper pad 200a and the lower pad 200b may selectively contact each other. In order to maximize heat dissipation efficiency, when the upper case 300a and the lower case 300b are coupled, it is preferable that the inner surface 2001 of each pad 200 except for the seating groove 210 is provided so as to be completely in close contact.

The upper case 300a and the lower case 300b may be opened or closed by providing a hinge portion in which the corresponding corners are hinged to each other, or may be opened and closed by hook coupling. Alternatively, these coupling methods may be applied in combination to implement opening and closing.

As an example, as shown in FIG. 1, assuming that the fluid tube 100 is inserted and withdrawn from one edge of the pad 200, the edge of the case 300 corresponding to the other edge of the pad 200 is hinged to each other. The upper case 300a and the lower case 300b are opened and closed, and a hook coupling part is provided at the corner of the case 300 corresponding to one corner of the pad 200 so that the infusion tube 100 coupled to the pad 200 It is possible to maintain the fastening of the case 300 so as to be in close contact.

As another example, the upper case 300a and the lower case 300b may be opened and closed by magnetic coupling.

In addition, the embodiments of FIGS. 1(a) and 1(b) disclose a case where the pad 200 is separated into an upper pad 200a and a lower pad 200b, but may be provided integrally in some cases. have.

In this embodiment, the separated form as shown in FIG. 1(b) is not applied, and may be configured as in the form of FIG. 1(a).

The integral pad 200 may be mounted on the case 300 and provided.

In the same manner as in the above-described embodiment, the pad 200 may form a seating groove 210 so that the infusion tube 100 may be inserted. The pad 200 of the present embodiment may also be made of the material of the pad 200 described above.

Alternatively, the pad 200 may be provided with a fluid liquid having a viscous property. In this case, the infusion tube 100 may be inserted into the case 300 without forming a separate seating groove to maintain contact with the pad 200. In this case, the case 300 may be provided so that an area other than a partial area is sealed so that the pad 200 does not overflow or come out of the case 300.

3(a) is an enlarged view of area B of FIG. 1(a), and FIG. 3(b) is an enlarged view of area C of FIG. 1(b). For convenience of description, it will be described with reference to FIG. 1.

The temperature measurement terminal 520 is coupled to a point of the infusion tube 100 to measure the temperature of the infusion solution. When defining the area of the infusion tube 100 before entering the pad 200 as an inlet area and the area of the infusion tube 100 passing through the pad 200 as an outlet area, the temperature measurement terminal 520 is an outlet It can be combined at one point in the area.

One point of the infusion tube 100 to which the temperature measurement terminal 520 is coupled may have a protruding branch 110 so that the temperature measurement terminal can be easily coupled.

The temperature measurement terminal 520 may include a probe needle 522 and a cap 521. One side of the probe needle 522 forms a temperature measurement surface 5221 exposed to the outside for temperature measurement, and the other side passes through the branch of the infusion tube 100 to form a probe 5222 in contact with the infusion solution. . The probe needle 522 has a specific temperature based on the temperature of the sap passing through the branch 110 through heat transfer, and measures the specific temperature of the temperature measuring surface 5221 and inversely measures the temperature of the sap. do.

4 is a cross-sectional view in the direction D-D' of FIG. 3(b). For convenience of explanation, it will be described with reference to FIG. 3.

The probe 5222 of the probe needle 522 has a sharp needle shape so as to easily penetrate the protruding surface 5101 of the branch 110, and the temperature measurement surface 5221 must form a sufficient area. Therefore, the probe needle 522 may have a conical shape. That is, the conical region of the probe needle 522 may be the temperature measuring surface 5221, and the region near the conical vertex may be the probe 5222.

The cap 521 serves to fix the probe needle 522 to the branch 110 of the infusion tube 100 so as to maintain the coupled state. The cap 521 may be fixed by being coupled to the outer peripheral surface 5223 of one area of the probe needle 522. For example, the cap 521 may be double injection formed on the probe needle 522.

The cap 521 may form an inner circumferential surface 5211 that is equal to or slightly smaller than the outer circumferential surface 5102 of the branch 510 so as not to be easily separated after being coupled to the branch 510. In this case, the cap 521 may be made of a material having elasticity of a certain degree or more.

Alternatively, the temperature measurement terminal 520 may be screwed to the branch 510 by having a spiral shape corresponding to the inner circumferential surface 5211 of the cap 521 and the outer circumferential surface 5102 of the branch 510 (not shown).

The temperature measuring terminal 520 may be sterilized to prevent possible infection. The temperature measurement terminal 520 may be provided as a disposable for hygiene and used as a replacement type.

5 is a block diagram showing the overall configuration of the infusion temperature control device 10 related to the present invention, and FIG. 6 is a block diagram showing the control flow of the infusion temperature control device 10 related to the present invention. For convenience of explanation, it will be described with reference to FIGS. 5 and 6. The temperature control unit 601 is connected to the electronic cooling element 400 to control heat dissipation of the electronic cooling element 400. The degree of heat dissipation of the electronic cooling element 400 may be adjusted by adjusting the amount of current applied to the electronic cooling element 400.

The temperature control unit 601 may adjust the degree of heat dissipation of the electronic cooling element 400 to the patient based on the current temperature of the infusion solution, the target infusion temperature, the current flow rate of the infusion solution, or the target infusion rate.

The temperature of the pad 200 measured by the pad temperature measurement unit 610 and the temperature of the sap measured by the sap temperature measurement unit 620 may serve as a basis for feeding back whether the current sap has reached the target temperature.

The current temperature of the infusion solution may be calculated by the controller 600 in consideration of physical properties of the probe needle 522 based on the temperature of the temperature measurement terminal 520 measured by the infusion temperature measurement unit 620.

The flow rate measurement unit 650 measures the flow rate of the infusion solution currently passing through the infusion tube 100. The flow measurement unit 650 may use an ultrasonic method.

The flow rate generator 660 serves to adjust the flow rate based on the flow rate of the target fluid.

The controller 600 may control the flow rate generation unit 660 based on the target fluid flow rate and the current fluid flow rate to adjust the flow rate of the fluid.

The target fluid temperature or target fluid flow rate described above may be based on biomarker values of the patient. The biomarker measuring unit 630 measures biomarker values from the patient. The biomarker value refers to factors that can determine the patient's physical condition, such as the patient's body temperature, the volume of fluid in the bladder, and blood pressure.

The measured biomarker values are transmitted to the control unit 600 or the temperature control unit 601. The controller 600 may calculate a target fluid flow rate based on the transmitted biomarker values, and the temperature controller 601 may calculate a target fluid temperature based on the transmitted biomarker values.

Of course, if necessary, the target fluid temperature or the target fluid flow rate may be set as a user-defined input value.

The output unit 640 may output the flow rate of the infusion solution, the temperature of the infusion solution, the volume of the infusion solution injected up to a corresponding time point after operation, and biomarkers. The output unit 640 may be provided in the form of a display that outputs an image. The output unit 640 may be connected to the control unit 600 to receive an output signal from the control unit 600.

The output unit 640 may designate a range of desired values for various parameters and transmit a warning signal to a user through sound or a screen when the measured value is out of the corresponding range.

The above detailed description should not be construed as restrictive in all respects and should be considered as illustrative. The scope of the present invention should be determined by reasonable interpretation of the appended claims, and all changes within the equivalent scope of the present invention are included in the scope of the present invention.

10: infusion temperature control device 100: infusion tube
1001: infusion tube outer surface 110: branch
1101: branch protruding surface 200: pad
200a: upper pad 200b: lower pad
2001: inner side of pad 2002: outer side of pad
210: mounting groove 211: parallel multiple rows
212: bend part 300: case
300a: upper case 300b: lower case
301: opening 400: electronic cooling element
4001: electronic cooling element one side 4002: electronic cooling element other side
410: heat sink 510: branch
5101: protruding surface 5102: branch outer peripheral surface
520: temperature measurement terminal 521: cap
5211: cap inner peripheral surface 522: probe needle
5221: temperature measurement surface 5222: probe
5223: probe needle outer peripheral surface 600: control unit
601: temperature control unit 610: pad temperature measurement unit
620: infusion temperature measurement unit 630: biomarker measurement unit
640: output unit 650: flow measurement unit
660: flow generation unit

Claims (18)

A thermally conductive pad including an upper pad and a lower pad selectively contacting each inner surface;
A seating groove formed on the upper pad and the lower pad, respectively, to form a path into which the fluid tube is inserted;
An electronic cooling element in contact with an outer surface of the pad;
A heat sink in contact with an outer surface of the electronic cooling element;
A flow rate measuring device that measures the flow rate of the sap currently flowing into the pad;
A flow rate generator configured to adjust the flow rate of the sap flowing into the pad based on the flow rate of the current inflow sap measured by the flow rate measurement device;
A biomarker measuring unit measuring biomarker values of a patient; And
Infusion temperature control apparatus comprising a control unit for obtaining a target infusion flow rate based on the biomarker values obtained by the biomarker measuring unit. The method of claim 1,
The path of the seating groove,
Parallel plural rows; And
A fluid temperature control device comprising a plurality of bent portions connecting the plurality of rows. The method of claim 1,
An upper case covering the upper pad; And
Infusion temperature control device further comprising a lower case covering the lower pad. The method of claim 3,
The infusion temperature control device further comprises a hinge portion hinge-coupled to the upper case and the lower case so that the upper pad and the lower pad are selectively opened and closed. The method of claim 1,
A temperature controller connected to the electronic cooling element to control heat dissipation of the electronic cooling element based on the temperature of the sap; And
Infusion temperature control device further comprising a fluid temperature measuring unit for measuring the current temperature of the fluid passing through the infusion tube. The method of claim 5,
The infusion temperature control device further comprises a temperature measurement terminal coupled to a point of the infusion tube to provide a temperature measurement surface of the infusion solution to the infusion temperature measurement unit. The method of claim 6,
The temperature measurement terminal,
A probe needle made of a metal material that forms the temperature measurement surface on one side and passes through a point of the infusion tube on the other side and contacts the infusion solution; And
Infusion temperature control device comprising an outer peripheral surface of the branch protruding from one point of the infusion tube and a cap surrounding the probe needle. delete The method of claim 7,
The temperature control unit,
The infusion temperature control device, characterized in that calculating the current temperature of the infusion solution based on the temperature measured by the infusion temperature control device and the physical properties of the probe needle. delete delete The method of claim 1,
Infusion solution temperature control device further comprising an output for outputting the flow rate and the temperature of the infusion solution. A temperature measuring terminal detachably coupled to a point protruding from a point of the infusion tube passing through the pad;
An infusion temperature measuring unit for measuring a temperature of an infusion solution passing through a point of the infusion tube in contact with the temperature measurement terminal;
A flow rate measuring device that measures the flow rate of the sap currently flowing into the pad;
A flow rate generator configured to adjust the flow rate of the sap flowing into the pad based on the flow rate of the current inflow sap measured by the flow rate measurement device;
A biomarker measuring unit measuring biomarker values of a patient; And
And a control unit for obtaining a target fluid flow rate based on the biomarker values obtained by the biomarker measuring unit,
The temperature measurement terminal,
A cap surrounding the outer peripheral surface of the protruding branch of the infusion tube; And
It includes a probe needle that penetrates into the protruding branch of the infusion tube and contacts the sap,
The probe needle is a fluid temperature control device containing a metallic material. The method of claim 13,
The probe needle is configured in a conical shape whose cross-sectional area decreases toward one end,
A fluid temperature control device comprising a temperature measuring surface formed in a conical bottom area. Thermally conductive pads;
A seating groove formed on the pad to form a path into which the fluid tube is inserted;
A case on which the pad is mounted and an opening is formed in a region;
An electronic cooling element in contact with an outer surface of the pad;
A heat sink in contact with an outer surface of the electronic cooling element;
A flow rate measuring device that measures the flow rate of the sap currently flowing into the pad;
A flow rate generator configured to adjust the flow rate of the sap flowing into the pad based on the flow rate of the current inflow sap measured by the flow rate measurement device;
A biomarker measuring unit measuring biomarker values of a patient; And
And a control unit for obtaining a target fluid flow rate based on the biomarker values obtained by the biomarker measuring unit,
The electronic cooling element and the heat sink are infusion temperature control device provided in the one region. The method of claim 15,
A temperature controller connected to the electronic cooling element to control heat dissipation of the electronic cooling element based on the temperature of the sap; And
Infusion temperature control device further comprising a fluid temperature measuring unit for measuring the current temperature of the fluid passing through the infusion tube. The method of claim 16,
The infusion temperature control device further comprises a temperature measurement terminal coupled to a point of the infusion tube to provide a temperature measurement surface of the infusion solution to the infusion temperature measurement unit. The method of claim 17,
The temperature measurement terminal,
A probe needle made of a metal material that forms the temperature measurement surface on one side and passes through a point of the infusion tube on the other side and contacts the infusion solution; And
Infusion temperature control device comprising an outer peripheral surface of the branch protruding from one point of the infusion tube and a cap surrounding the probe needle.

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