KR101125134B1 - A temperature sensor of measuring apparatus for cellular metabolic information - Google Patents

Abstract

The present invention discloses a temperature sensor of a cell metabolic information measuring device. The present invention is inserted into a sample to measure the temperature of the cell in the sample, the temperature measurement unit for measuring the voltage formed in the cell by changing the resistance value according to the temperature of the cell, and applying a current to the temperature measuring unit And a current applying unit that receives the voltage measured by the temperature measuring unit and transmits it to the outside, and is electrically connected to the current applying unit to control the applied current, and the voltage transmitted to the outside from the current applying unit. And a current control unit for calculating the resistance value based on the voltage and calculating the temperature of the cell based on the calculated resistance value.

Description

A temperature sensor of measuring apparatus for cellular metabolic information

The present invention relates to a temperature sensor of the cell metabolic information measuring device, and more particularly to a temperature sensor of the cell metabolic information measuring device for accurately measuring the temperature.

In general, the cell metabolic information measuring device includes a temperature sensor for measuring the temperature of the sample. In particular, the amount of heat change, which is the most important measurement factor, is used to measure cellular metabolic information. In order to measure the amount of heat change, it is important to accurately measure the temperature of the sample with a temperature sensor. Therefore, in order to measure the change in the heat of the cell was measured by inserting a temperature sensor in the sample. At this time, the temperature sensor changes resistance in accordance with the temperature of the sample.

In particular, the temperature sensor used in the cell metabolic information measuring device has a negative characteristic. Therefore, when the temperature of the sample rises, the resistance of the temperature sensor decreases. In addition, when the temperature of the sample decreases, the resistance of the temperature sensor increases. On the other hand, when measuring the temperature, the temperature sensor applies a current to the resistor. At this time, the temperature of the resistance of the temperature sensor is increased by the current. Therefore, the temperature of the sample due to the heating of the resistance rises. In addition, the temperature sensor could not measure the correct temperature of the sample due to the increase in temperature. As the temperature of the sample increases due to the increase in temperature, the cells to be cultured are damaged due to the exotherm.

An object of the present invention is to provide a temperature sensor of the cell metabolic information measuring device for correcting the error of the temperature by the temperature sensor of the cell metabolic information measuring device.

One aspect of the present invention, the temperature measuring unit for inserting a sample to measure the temperature of the cells in the sample, the resistance value is variable according to the temperature of the cells to measure the voltage formed on the cells, and the temperature measuring unit A current applying unit for applying current and receiving the voltage measured by the temperature measuring unit and transmitting it to the outside, and electrically connected to the current applying unit to control the applied current, and transmits from the current applying unit to the outside. The temperature sensor of the cell metabolic information measuring apparatus may be provided by receiving the voltage to calculate the resistance value based on the voltage and calculating the temperature of the cell based on the calculated resistance value. have.

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The temperature sensor of the cell metabolic information measuring device according to the present invention effectively blocks heat due to the operation of the temperature sensor. Therefore, the temperature of the sample is measured accurately and precisely.

1 is a perspective view showing an embodiment of the temperature sensor 100 of the apparatus for measuring cell metabolism information according to the present invention. 2 is a block diagram showing a control flow of the temperature sensor 100 of the apparatus for measuring cell metabolism information shown in FIG. 1.

1 and 2, the temperature sensor 100 of the cell metabolic information measuring device includes a temperature measuring unit 110 is inserted into the sample to measure the temperature of the sample. The temperature measuring unit 110 includes a negative temperature coefficient (NTC) sintered body 113.

The negative sintered body 113 has a negative temperature coefficient (NTC). The negative temperature coefficient has a negative value. That is, when the temperature of the negative sintered body 113 increases by the negative temperature coefficient, the resistance of the negative sintered body 113 decreases. On the other hand, when the temperature of the negative sintered body 113 decreases, the resistance of the negative sintered body 113 increases.

The temperature measuring unit 110 includes a plurality of electrodes 115 fastened to both sides of the negative sintered body 113. The plurality of electrodes 115 applies a current to the negative sintered body 113.

External protective means 114 is fastened to the outside of the negative sintered body 113 and the plurality of electrodes 115. The outer protective means 114 is formed by coating a glass-based material. Therefore, the external protection means 114 protects the negative sintered body 113 and the plurality of electrodes 115 from the external material.

The plurality of conductive wires 111 are fastened to one side of the plurality of electrodes 115. The plurality of conductive wires 111 are fastened to extend to one side from the plurality of electrodes 115. The plurality of conductive wires 111 supplies current to the plurality of electrodes 115 from the outside.

A portion of the plurality of conductive wires 111 protruding to the outside of the external protection means 114 is coated with an electrically insulating material to prevent the plurality of conductive wires 111 from being contaminated by an external material. Therefore, the plurality of conductive wires 111 may stably supply current to the plurality of electrodes 115.

On the other hand, the temperature sensor 100 of the cell metabolic information measuring device includes a current applying unit 120 for applying a current to the temperature measuring unit 110. The current applying unit 120 may include an analog-to-digital conversion circuit (ADC, not shown) for converting an AC power applied from an external power source into a DC power source.

The temperature sensor 100 of the cell metabolic information measuring device includes a current control unit 130 that is electrically connected to the current applying unit 120. The current controller 130 controls the current applying unit 120 to control the current applied to the temperature measuring unit 110. Therefore, the current controller 130 can precisely control the current applied to the temperature measuring unit 110.

Hereinafter, the operation of the temperature measuring unit 110, the current applying unit 120, and the current control unit 130 described above will be described in detail.

Figure 3 is a flow chart showing an embodiment of a temperature sensor control method of the cell metabolic information measuring device according to the present invention. 4 is a graph illustrating an embodiment of a current applied to the temperature measuring unit 110 shown in FIG. 1.

3 and 4, when the user operates the cell metabolic information measuring device (not shown), the temperature sensor 100 measures the temperature related to the cell metabolic information. At this time, a part of the temperature side unit 110 is inserted into the sample. For example, external protective means 114 is inserted into the sample.

When the external protection means 114 is inserted into the sample, the current control unit 130 controls the current applied from the current applying unit 120 to the temperature measuring unit 110. The current controller 130 controls the current to be applied to the temperature measuring unit 110 during the first time T ₁ .

At this time, the resistance of the negative characteristic sintered body 113 changes with the temperature of a sample. When the current is applied to the negative sintered body 113, a voltage is formed in the negative sintered body 113. The negative sintered body 113 measures the voltage and transmits the measured voltage to the current applying unit 120 (step S110).

On the other hand, when the current is applied, heat is generated by the resistance of the negative sintered body 113. The temperature of the sample may rise due to the heat generated by the resistance. Therefore, the first time T ₁ may be set to 1/10 seconds or less.

When the first time T ₁ is set to 1/10 seconds or less, the heat generated by the subsidiary sintered body 113 does not affect the temperature of the external sample. Therefore, since the influence of self-heating of the negative sintered body 113 is insignificant, the temperature of the sample can be measured accurately.

The current applied during the first time T ₁ forms a pulse wave. That is, the pulse wave forms a current of about 200 mA. When the pulse wave is applied, as described above, self-heating generated in the subsidiary sintered body 113 is minimally formed. Therefore, it is possible to prevent the temperature of the sample caused by the negative characteristic sintered body 113 from rising.

The current controller 130 controls the current applying unit 120 to block the current. At this time, the current controller 130 controls the current applying unit 120 to cut off the current for a second time T ₂ different from the first time T ₁ .

The current applying unit 120 cuts off the current applied to the negative sintered body 113 for a second time T ₂ . In the negative sintered body 113, the current is cut off during the second time T ₂ so that the voltage is not formed.

When the current applied to the subsidiary sintered body 113 is interrupted during the second time T ₂ , heat generated during the first time T ₁ is dissipated. Therefore, the heat generated during the first time T ₁ is dissipated so that the temperature of the sample to be measured later can be accurately measured.

Meanwhile, the second time T ₂ may be set to be equal to or greater than the first time T ₁ . The second time T ₂ may be set to be three times or more than the first time T ₁ .

The current applying unit 120 transmits the voltage to the current control unit 130. The current controller 130 calculates a resistance value of the subsidiary sintered body 113 based on the voltage value. At this time, the current control unit 130 calculates the temperature of the sample based on the resistance value (step S130).

The current control unit 130 may calculate the temperature of the sample based on the resistance value by a formula. In addition, the current controller 130 may compare the temperature of the sample based on the resistance value by making a numerical table. Therefore, the current controller 130 can accurately measure the temperature of the sample based on the resistance value.

On the other hand, the current controller 130 measures the number (n) of applying and blocking the current during the first time (T ₁ ) and the second time (T ₂ ). At this time, the current control unit 130 determines the number of times the temperature of the sample is measured in the sub-characteristic sintered body 113 based on the number n.

The current controller 130 determines whether the measurement is performed for a preset number N based on the number n. The current controller 130 determines whether the number n is greater than or equal to the predetermined number N (step S140).

If it is determined that the number n is less than the predetermined number N, the current controller 130 adds 1 to the number n and again supplies current to the sub-sintered body 113 for the first time T ₁ . The current applying unit 120 is controlled to apply (S150).

In addition, when the above process is completed, the current control unit 130 controls the current applying unit 120 to cut off the current to the secondary sintered body 113 for a second time (T ₂ ).

On the other hand, if it is determined that the number n is greater than or equal to the predetermined number N, the current controller 130 ends the measurement of the temperature of the sample in the current controller 130.

Therefore, the temperature sensor 100 of the cell metabolic information measuring device and the temperature sensor control method of the cell metabolic information measuring device provide an accurate temperature of the sample to the user. In particular, when measuring the temperature of the sample related to the cell metabolic information, the accurate temperature is measured by minimizing the heat generated by the subsidiary sintered body (113).

1 is a perspective view showing an embodiment of a temperature sensor of a cell metabolic information measuring apparatus according to the present invention.

FIG. 2 is a block diagram illustrating a control flow of a temperature sensor of the apparatus for measuring cell metabolic information shown in FIG. 1.

Figure 3 is a flow chart showing an embodiment of a temperature sensor control method of the cell metabolic information measuring device according to the present invention.

FIG. 4 is a graph showing an embodiment of a current applied to the temperature measuring part shown in FIG. 1.

<Brief description of symbols for the main parts of the drawings>

100: temperature sensor of cell metabolic information measuring device

110: temperature measuring unit

111: lead wire

113: negative sintered body

114: external protection measures

115: electrode

120: current applying unit

130: current control unit

Claims (14)

A temperature measuring unit inserted into a sample to measure a temperature of a cell in the sample and measuring a voltage formed in the cell by changing a resistance value according to the temperature of the cell; A current applying unit for applying a current to the temperature measuring unit and receiving the voltage measured by the temperature measuring unit and transmitting it to the outside; Is electrically connected to the current applying unit to control the applied current, receives the voltage transmitted from the current applying unit to the outside, calculates the resistance value based on the voltage, and based on the calculated resistance value Temperature sensor of the cell metabolic information measuring device comprising a current control unit for calculating the temperature of the cell. The method according to claim 1, And the current control unit controls the current applying unit to apply the applied current for a first time and block the second applied time for a second time different from the first time. The method according to claim 2, Wherein the first time is 1/10 seconds or less. The method according to claim 2, The second time is a temperature sensor of the cell metabolic information measuring device exceeding the first time. The method according to claim 4, Wherein said second time is at least three times greater than said first time. The method according to claim 2, And the current control unit alternately alternately applies the current for the first time and controls the current application unit to cut off the current for the second time. The method according to claim 2, The temperature sensor of the cell metabolic information measuring device is a current applied during the first time is a pulse wave. The method according to claim 1, The temperature sensor is a temperature sensor of the cell metabolic information measuring device including a negative polarity (NTC) sintered body. delete delete delete delete delete delete

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