CN115144096A - Measuring device for deep temperature - Google Patents

Abstract

The application provides a measuring device of deep temperature, measuring device includes: a parent unit, and a daughter unit comprising at least one temperature sensor, wherein the parent unit is removably connected to the daughter unit; when the daughter unit is connected with the parent unit in a combined mode, the daughter unit is used for acquiring intermittent temperature values of a detection target through the at least one temperature sensor; when the daughter unit and the parent unit are separated from each other, the daughter unit is used for continuously acquiring a continuous temperature value of a detection target through the at least one temperature sensor; the invention solves the problem that continuous body temperature monitoring cannot be carried out in the prior art, can quickly acquire the intermittent temperature value of the detection target and can also continuously monitor the body temperature of the detection target, thereby meeting different requirements of users on intermittent temperature measurement and continuous temperature measurement.

Description

Measuring device for deep temperature

Technical Field

The invention relates to the technical field of temperature measurement, in particular to a deep temperature measuring device.

Background

Body temperature, one of the four basic vital signs, is a key index reflecting the health condition of a human body. The traditional body temperature measurement mainly uses a mercury thermometer, namely a direct insertion type intermittent temperature measuring device, can only be used for clamping the armpit or placing the armpit under the tongue for a period of time to obtain the body temperature when needed, cannot realize continuous body temperature monitoring, and further cannot provide powerful data for doctors to carry out detailed diagnosis of diseases.

Disclosure of Invention

The application provides a measuring device of deep temperature, has solved the problem that has to carry out continuous body temperature monitoring among the prior art, has satisfied the different demands of user to intermittent type formula temperature measurement and continuation temperature measurement.

The application provides a measuring device of deep temperature, measuring device includes: a parent unit, and a daughter unit comprising at least one temperature sensor, wherein the parent unit is removably connected to the daughter unit; when the daughter unit is connected with the parent unit in a combined mode, the daughter unit is used for acquiring intermittent temperature values of a detection target through the at least one temperature sensor; when the daughter unit and the mother unit are separated from each other, the daughter unit is used for continuously acquiring a continuous temperature value of the detection target through the at least one temperature sensor.

Optionally, the parent unit is configured to perform data calibration on the continuous temperature value through the intermittent temperature value to obtain a continuous deep temperature value of the detection target.

Optionally, the daughter unit further comprises: the device comprises a flexible body, a first communication module and a first power supply module; the first communication module is arranged on the flexible body, and the daughter unit is in communication connection with the parent unit through the first communication module; the first power module is arranged on the flexible body and used for providing working electric energy for the first communication module and the at least one temperature sensor.

Optionally, the at least one temperature sensor comprises: a first temperature sensor, a second temperature sensor and a third temperature sensor; the first temperature sensor and the second temperature sensor are arranged at the first end of the flexible body back to back and used for acquiring a first temperature value and a second temperature value of a first temperature measuring point of the detection target; the third temperature sensor is arranged at the second end of the flexible body and used for collecting a third temperature value of the second temperature measuring point of the detection target.

Optionally, when the sub-volume unit further includes a first processing module, the sub-volume unit is configured to obtain a continuous temperature value of the detection target through the at least one temperature sensor, and includes: the first processing module is used for acquiring characteristic parameters according to the third temperature value; the first processing module is further configured to obtain the continuous temperature value of the detection target according to the characteristic parameter, the first temperature value, and the second temperature value.

Optionally, the parent unit comprises: a parent body the second communication module and the second power supply module; the parent body comprises a fixed component with a cavity; the second communication module is fixedly arranged on the fixed component, is in communication connection with the first communication module and the intelligent terminal respectively, and is used for sending the intermittent temperature value and the continuous temperature value to the intelligent terminal; the second power module is arranged on the fixed component and used for providing working electric energy for the second communication module and also used for providing charging electric energy for the first power module.

Optionally, the parent body further comprises: the folding component is attached to the contraction component after being folded; the retraction assembly is slidably connected with the fixed assembly so that the retraction assembly is retracted in the cavity of the fixed assembly.

Optionally, one end of the flexible body is disposed in the cavity of the fixing assembly, and the other end of the flexible body is attached to the fixing assembly.

Optionally, the parent unit further comprises: a fourth temperature sensor and a second processing module; the fourth temperature sensor is used for collecting the ambient temperature; the second processing module is used for acquiring the characteristic parameters according to the environment temperature; the second processing module is further configured to obtain the continuous deep temperature value of the detection target according to the characteristic parameter and the continuous temperature value.

Optionally, the parent unit further comprises: a display module; the display module is arranged on the outer surface of the fixed component and used for displaying the environment temperature, the intermittent temperature value, the continuous temperature value or/and the continuous deep temperature value.

Compared with the prior art, the invention has the following beneficial effects:

this embodiment makes through the built-up connection and the alternate segregation of daughter unit and parent unit temperature measuring device is in cut straightly formula intermittent type temperature measurement mode and the continuous temperature measurement mode of SMD respectively to can gather the intermittent type formula temperature value that detects the target fast, also can the continuation carries out body temperature monitoring to detecting the target, satisfied the different demands of user to intermittent type formula temperature measurement and continuation temperature measurement.

Drawings

Fig. 1 is a block diagram illustrating a deep temperature measurement apparatus according to an embodiment of the present disclosure;

fig. 2 is a schematic structural diagram of a deep temperature measurement device according to an embodiment of the present disclosure;

FIG. 3 is a schematic surface view of a parent unit according to an embodiment of the present disclosure;

FIG. 4 is a schematic structural diagram of another deep temperature measurement device provided in an embodiment of the present application;

FIG. 5 is a schematic view of a sensor assembly of a subunit according to an embodiment of the present disclosure;

FIG. 6 shows a flowchart of an embodiment of the present application a characteristic parameter training schematic diagram of (1);

fig. 7 is a schematic diagram illustrating a working flow of a deep portion temperature measurement apparatus according to an embodiment of the present application.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. All other embodiments, which can be obtained by a person skilled in the art without making any creative effort based on the embodiments in the present invention, belong to the protection scope of the present invention.

Example one

Fig. 1 is a block diagram of a deep temperature measurement device according to an embodiment of the present invention, and as shown in fig. 1, the deep temperature measurement device includes:

a parent unit, and a child unit comprising at least one temperature sensor, wherein the parent unit is removably connected to the child unit;

when the daughter unit is connected with the parent unit in a combined mode, the daughter unit is used for acquiring intermittent temperature values of a detection target through the at least one temperature sensor;

when the daughter unit and the mother unit are separated from each other, the daughter unit is used for acquiring a continuous temperature value of a detection target through the at least one temperature sensor.

It should be noted that, in this embodiment, at least one temperature sensor is disposed in the sub-body unit, and when the sub-body unit is connected to the main body unit in a combined manner, the temperature measuring device is in a direct-insertion intermittent temperature measuring mode, and an intermittent temperature value of the detection target is acquired by the at least one temperature sensor.

In this embodiment, when the daughter unit is separated from the mother unit for independent use, the temperature measuring device is in a patch-type continuous temperature measuring mode, and a continuous temperature value of the detection target is continuously collected by the at least one temperature sensor.

Compared with the prior art, the beneficial effect of this embodiment is:

this embodiment makes through the built-up connection and the alternate segregation of daughter unit and parent unit temperature measuring device is in cut straightly formula intermittent type temperature measurement mode and SMD continuous temperature measurement mode respectively to can gather the intermittent type formula temperature value that detects the target fast, also can the continuation carries out body temperature monitoring to detecting the target, satisfied the different demands of user to intermittent type formula temperature measurement and continuation temperature measurement.

In this embodiment, as shown in fig. 1, the sub-body unit includes: the device comprises a flexible body, a first communication module and a first power supply module; the first communication module is arranged on the flexible body, and the daughter unit is in communication connection with the parent unit through the first communication module; the first power module is arranged on the flexible body and used for providing working electric energy for the first communication module and the at least one temperature sensor.

The parent unit comprises: the mother body, the second communication module and the second power module; the parent body comprises a fixing component and a contraction component, wherein the fixing component is provided with a cavity, and the contraction component is connected with the fixing component in a sliding mode and is contracted in the cavity of the fixing component; the second communication module is arranged in the cavity of the fixed component, is in communication connection with the first communication module and the intelligent terminal respectively, and is used for sending the intermittent temperature value and the continuous temperature value to the intelligent terminal; the second power module is arranged in the cavity of the fixed assembly and used for providing working electric energy for the second communication module and also used for providing charging electric energy for the first power module.

It should be noted that the parent unit in this embodiment can be regarded as the charging bin of the child unit, so that the first power module in the child unit can use paper batteries, film batteries, etc. without arranging too large capacity batteries, and can continuously maintain the operation for a period of time, for example, more typically, the operation can be maintained for 24 hours. The first communication module in the sub-body unit can be based on wired communication modes such as I2C, SPI, UART and the like, and when the sub-body unit is separated from the parent unit to work, the collected temperature data is recorded; when the sub-body unit is combined with the parent body unit, the temperature data is transmitted to the parent body unit through the first communication module to be interactively displayed. The first communication module can also be in a wireless communication mode such as Bluetooth and WIFI, can be directly in remote communication with a mobile phone and a target of a user, and presents a measurement result in real time to feed back to the user.

In the embodiment, the second power module in the parent unit is opposite to the first power module in the child unit, and the battery with large capacity mainly provides the module work of the parent unit and charges the first power module in a wired or wireless mode; the second communication module is used for communicating with the daughter unit and is also used for communicating with intelligent terminals such as mobile phones and tablets.

Example two

Fig. 2 is a schematic structural diagram of a deep temperature measuring apparatus according to an embodiment of the present application, and as shown in fig. 2, fig. 2-a is a schematic external view of a parent body, the parent body includes a fixed component 1 having a cavity, a contracting component 2 and a folding component 3, the contracting component 2 is foldably connected to the folding component 3, and the contracting component 2 is slidably connected to the fixed component 1; when the folding component 3 is folded in half and attached to the outer surface of the contraction component 2, the contraction component 2 is pushed into the cavity inside the fixing component 1 in a sliding manner through contraction, the folding component 3 is contracted inside the fixing component 1 together, the fixing component 1 is regarded as the minimized form of the parent unit, and the temperature measuring device is a small box or a form similar to a key hanging buckle and is convenient for a user to carry. The mother unit is made of rigid materials, and can be folded into a minimized form by structurally designing a contraction sliding rail, a folding point and the like; but not limited to the parent unit minimized form set forth herein, in other embodiments, a folding or contracting assembly may be employed to achieve a reduced parent unit form for portability.

Further, fig. 2-b is an appearance schematic diagram of a flexible body in the daughter unit, the flexible body is made of a flexible material, the first communication module, the second power module and the at least one temperature sensor can be arranged on the flexible body, a flexible daughter unit is formed after injection molding and packaging are carried out through materials such as silica gel, and the flexible daughter unit can be attached to the mother unit.

Optionally, the first communication module, the second power module and the at least one temperature sensor can be manufactured into a flexible circuit board, and the flexible circuit board and the flexible body are packaged to obtain the flexible sub-body unit.

In this embodiment, when the daughter unit and the mother unit are combined, i.e. in the state of fig. 2-c, the temperature measuring device is in the direct-insertion intermittent temperature measuring mode.

When the sub-body unit is used independently, the sub-body unit is in a patch type continuous temperature measurement mode, typically, one end of the patch type unit is attached to the armpit, and the other end of the patch type unit is attached to the chest; or one end is attached to the armpit and the other end is attached to the arm or the shoulder for fixation.

In this embodiment, the parent unit further comprises: a fourth temperature sensor and a display module; the fourth temperature sensor is used for collecting the ambient temperature; the display module is arranged on the outer surface of the fixed component and used for displaying the environment temperature, the intermittent temperature value, the continuous temperature value or/and the continuous deep temperature value.

As shown in fig. 3, fig. 3-a is a schematic view of a first surface of the mother unit, wherein a fourth temperature sensor for collecting an ambient temperature and a receiving groove for receiving the daughter unit are disposed on the first surface of the mother unit; fig. 3-b is a schematic diagram of a second surface of the mother unit, and a display module is disposed on the second surface of the mother unit and used for displaying the ambient temperature, the intermittent temperature value, the continuous temperature value, or/and the continuous deep temperature value, etc.; the fourth temperature sensor and the display module are respectively electrically connected with the second processing module.

EXAMPLE III

In this embodiment, one end of the flexible body 420 is disposed in the cavity of the fixing component 410, and the other end of the flexible body 420 is attached to the outer surface of the fixing component 410.

As shown in fig. 4-a, one end of the flexible body 420 is disposed in the fixing component 410 of the mother body, the other end of the flexible body 420 is an extendable fixing component 410 as a temperature probe, wherein the other end of the flexible body 420 can be placed on the outer surface of the fixing component 410 by extension or folding, and the sectional view of the temperature probe is as shown in fig. 4-b, so as to form an attachable original sheet, which can be conveniently attached to the abdomen, forehead, etc. as an independent form for measuring the body temperature.

Example four

In this embodiment, the at least one temperature sensor includes: a first temperature sensor, a second temperature sensor and a third temperature sensor; the first temperature sensor and the second temperature sensor are arranged on the first end of the flexible body back to back and used for collecting a first temperature value and a second temperature value of a first temperature measuring point on a detection target; the third temperature sensor is arranged at the second end of the flexible body and used for collecting a third temperature value of a second temperature measuring point on the detection target.

When the sub-body unit further comprises a first processing module, the sub-body unit is used for acquiring a continuous temperature value of a detection target through the at least one temperature sensor, and comprises: the first processing module is used for acquiring undetermined parameters according to the third temperature value; the first processing module is further configured to obtain a continuous temperature value of the detection target according to the undetermined parameter, the first temperature value and the second temperature value.

It should be noted that the sub-body unit at least comprises a temperature sensor, which can read the temperature of at least one temperature measuring point on the surface of the human skin. Typically, as shown in fig. 5, three temperature sensors are included to calculate the body temperature of the human body, wherein two temperature sensors (i.e. a first temperature sensor and a second temperature sensor) are back-to-back and are disposed on a vertical path, and the other temperature sensor (i.e. a third temperature sensor) is far away from the temperature sensors disposed back-to-back for measuring the temperature of the local microenvironment (i.e. local environment) of the human body.

In the present embodiment, the calculation formula of the continuous temperature value is typically as follows:

T _d ＝f((T ₁ ,T ₂ )|(k ₁ ,…)) (1)

in the formula, T _d Is a continuous temperature value, T ₁ 、T ₂ A first temperature value and a second temperature value respectively collected by the first temperature sensorA second temperature value (k) collected by the sensor ₁ 8230), which is the characteristic parameter to be determined, can be obtained according to formula (2).

In the formula (I), the compound is shown in the specification,

is a parameter of the characteristic to be determined, corresponding to (k) in the formula (1) ₁ ，…)，T ₃ Is a third temperature value collected by the third sensor.

More specifically, the first processing module is configured to obtain, according to the third temperature value, a specific formula of the characteristic parameter as follows:

wherein k is ₁ Is a parameter of the characteristic to be determined, theta ₁ 、θ ₂ 、θ ₃ Is undetermined parameter (default values are respectively 5.6, 3.2 and 1.2, and actual values can be obtained through actual measurement data statistics of designed products), gamma ₁ 、γ ₂ 、γ ₃ Also undetermined parameters (default values of values are 5, 2 and 2 respectively, which can be obtained by actual measurement data statistics of designed products), T ₃ Is a third temperature value collected by the third temperature sensor.

In another embodiment, more generally, segmentation may also be performed based on the third temperature value, the segmentation determining the characteristic parameter in equation (2). During actual work, the segmentation is determined according to the local environment temperature, then the characteristic parameters are determined, and finally the continuous temperature value is calculated.

As shown in FIG. 6, T _ij The steady-state temperature data collected by the jth temperature sensor in the ith group of data is represented, and the specific training process is described as follows: (1) The segmentation based on local ambient temperature may be in (— infinity, 15)]、(15,25]、(25,36]，(36,38]，(38,+∞]Carrying out segmentation; (2) Collecting not less than 50 people according to different environmental temperatureNot less than 100 groups of data, wherein the data comprises temperature rise process data of the multiple temperature sensors and corresponding human body temperature; (3) And obtaining the characteristic parameters based on a machine learning or deep learning algorithm.

In this embodiment, when the ambient temperature is relatively stable (for example, when there is clothes in the armpit and the armpit does not move, the local ambient temperature is relatively stable), the first processing module is further configured to obtain the continuous temperature value according to the characteristic parameter, the first temperature value, and the second temperature value, and the calculation formula of the continuous temperature value is:

T _d ＝T ₁ +k ₁ ·(T ₁ -T ₂ ) (4)

wherein, T _d Is a continuous temperature value, T ₁ 、T ₂ Respectively a first temperature value collected by the first temperature sensor and a second temperature value, k, collected by the second temperature sensor ₁ Are characteristic parameters, which can be obtained according to the above formula (3) or based on a machine learning/deep learning algorithm.

In an actual application scenario, when the local environment temperature is relatively stable, the continuous temperature value obtained by the independent operation of the daughter unit may also be regarded as a continuous deep temperature value.

EXAMPLE five

In this embodiment, the parent unit is configured to perform data calibration on the continuous temperature value through the intermittent temperature value to obtain a continuous deep temperature value of the detection target.

Further, the parent unit further comprises: a fourth temperature sensor and a second processing module; the fourth temperature sensor is used for collecting the ambient temperature; the second processing module is used for acquiring the characteristic parameters according to the environment temperature; the second processing module is further configured to obtain the continuous deep temperature value of the detection target according to the characteristic parameter and the continuous temperature value.

It should be noted that, when the parent unit and the daughter unit are integrated, the parent unit not only serves as a rigid support to form a direct-insert thermometer to work, but also can be used for improving the accuracy of continuous temperature measurement through joint calculation.

The measuring device provided by the embodiment has two working states of intermittent temperature measurement and continuous temperature measurement, can acquire body temperature and related parameters based on a mature continuous temperature measurement scheme, and provides initial values and calibration for continuous body temperature monitoring. The specific working flow is shown in fig. 7, and the specific temperature measuring process includes:

(1) Direct insertion type temperature measurement: the temperature measuring device provided by the embodiment is assembled into an in-line thermometer, typically, the in-line thermometer is clamped under an armpit, and temperature data are read;

(2) Acquiring an initial body temperature value: generally, the armpit can be clamped for about 10 minutes to obtain a temperature value close to the body temperature of a human body, and meanwhile, the temperature measuring device provided by the embodiment can continuously record temperature rise data in the armpit clamping and temperature rise process, so that a basis is provided for further feature extraction;

(3) Surface mount temperature measurement: taking down the sub-body part, wherein one end of the sub-body part is attached to the armpit, and the other end of the sub-body part is attached to the chest, and temperature data of the temperature sensor are continuously acquired;

(4) Continuously monitoring the body temperature: and determining a continuous temperature measurement model and characteristic parameters according to the initial body temperature value and the temperature rise data acquired in the direct-insertion temperature measurement stage, and calculating the body temperature in the continuous temperature measurement stage.

In the present embodiment, the calculation formula of the continuous core temperature value is typically as follows:

T _C ＝f((T ₁ ,T ₂ ,T ₃ )|(k ₁ ,k ₂ ,T _d0 …)) (5)

wherein, T _c Is a continuous deep temperature value, T ₁ 、T ₂ 、T ₃ A first temperature value collected by the first temperature sensor, a second temperature value collected by the second temperature sensor, and a third temperature value collected by the third temperature sensor, (k) ₁ ，k ₂ 8230is a undetermined characteristic parameter, which can be obtained according to formula (6), T _d0 The temperature is the initial value of the body temperature obtained in the direct-insertion type temperature measurement stage.

Wherein the content of the first and second substances,

is a parameter of the characteristic to be determined, corresponding to (k) in the formula (5) ₁ ，k ₂ ，…)，T ₄ Is the ambient temperature value collected by the temperature sensor disposed in the parent unit, and in other embodiments, when the temperature sensor is not disposed in the parent unit, the temperature sensor disposed in the child unit for collecting the local ambient temperature value (e.g., the third temperature sensor as set forth in the fourth embodiment) may be used instead.

In this embodiment, in a typical scenario, that is, in a case where the ambient temperature is relatively stable (e.g., in a case where there is clothes in the armpit and there is no movement, the local ambient temperature is relatively stable), the calculation formula of the continuous deep temperature value can be simplified as follows:

T _c ＝T ₁ +k ₁ ·(T ₁ -T ₂ ) (7)

in the temperature measuring device of the embodiment, T can be acquired in a direct insertion mode _d0 Then switching to a patch type working mode (namely the daughter units work independently), and when the patch type working mode reaches thermal balance and the heat balance is taken, obtaining the T ₁ 、T ₂ Substituting into formula (8) to obtain characteristic parameter k ₁ The value is obtained.

k ₁ ＝(T _d0 -T ₁ )/(T ₁ -T ₂ ) (8)

In other embodiments, in general scenarios, the ambient temperature T may be based on ₄ Dividing the zones to obtain the temperature of each sensor and the corresponding body temperature (T) ₁ 、T ₂ 、T ₃ ；T _c ) At least 50 groups of data are collected for training in each section, and a group (k) can be obtained in a linear fitting mode ₁ ，k ₂ ) In actual test, the temperature can be measured according to the environmental temperature T ₄ Determining a group of characteristic parameters to calculate the body temperature, and obtaining the continuous deep part of the detection target according to the characteristic parameters and the continuous temperature value by the second processing moduleThe specific calculation formula of the temperature value is as follows:

T _c ＝T ₁ +k ₁ ·(T ₁ -T ₂ )+k ₂ ·(T ₁ -T ₃ ) (9)

in another embodiment of the present invention, the training method shown in fig. 6 obtains characteristic parameters, and substitutes the characteristic parameters into formula (5) to obtain continuous deep temperature values.

In this embodiment, the parent unit further comprises: a display module; the display module is arranged on the outer surface of the fixed component and used for displaying the environment temperature, the intermittent temperature value, the continuous temperature value or/and the continuous deep temperature value.

Therefore, the deep temperature measuring device provided by the embodiment can be carried about like a key ring at ordinary times, can be embodied as a direct-insert type or intermittent temperature measuring device when needed, and can quickly obtain accurate body temperature. More importantly, the body temperature and the temperature rise process measured in the direct insertion stage can be used as preorder calibration data of the subsequent patch type temperature measurement process to determine characteristic parameters of some patch type temperature measurement models so as to improve the temperature measurement accuracy in the continuous temperature measurement stage.

Finally, it is noted that, in this document, relational terms such as "first" and "second," and the like, are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrases "comprising one of 8230; \8230;" 8230; "does not exclude the presence of additional like elements in a process, method, article, or apparatus that comprises the element.

Although the present invention has been described in detail with reference to the preferred embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted without departing from the spirit and scope of the invention as defined in the appended claims.

Claims (10)

1. A deep temperature measuring device, comprising:

a parent unit, and a daughter unit comprising at least one temperature sensor, wherein the parent unit is removably connected to the daughter unit;

when the daughter unit is connected with the parent unit in a combined mode, the daughter unit is used for acquiring intermittent temperature values of a detection target through the at least one temperature sensor;

when the daughter unit and the mother unit are separated from each other, the daughter unit is used for continuously acquiring a continuous temperature value of the detection target through the at least one temperature sensor.

2. The deep temperature measuring apparatus according to claim 1, wherein the parent unit is configured to perform data calibration on the continuous temperature value by using the intermittent temperature value to obtain a continuous deep temperature value of the detection target.

3. The deep temperature measurement device of claim 1, wherein the daughter unit further comprises:

the device comprises a flexible body, a first communication module and a first power supply module;

the first communication module is arranged on the flexible body, and the daughter unit is in communication connection with the parent unit through the first communication module;

the first power module is arranged on the flexible body and used for providing working electric energy for the first communication module and the at least one temperature sensor.

4. The deep temperature measurement device of claim 3, wherein the at least one temperature sensor comprises:

a first temperature sensor, a second temperature sensor and a third temperature sensor;

the first temperature sensor and the second temperature sensor are arranged at the first end of the flexible body back to back and used for acquiring a first temperature value and a second temperature value of a first temperature measuring point of the detection target;

the third temperature sensor is arranged at the second end of the flexible body and used for collecting a third temperature value of the second temperature measuring point of the detection target.

5. The deep temperature measurement device of claim 4, wherein when the sub-body unit further comprises a first processing module, the sub-body unit is configured to obtain continuous temperature values of the detection target via the at least one temperature sensor, comprising:

the first processing module is used for acquiring characteristic parameters according to the third temperature value;

the first processing module is further configured to obtain the continuous temperature value of the detection target according to the characteristic parameter, the first temperature value, and the second temperature value.

6. The deep temperature measurement device of claim 3, wherein the parent unit comprises:

the mother body, the second communication module and the second power module;

the parent body comprises a fixed component with a cavity;

the second communication module is fixedly arranged on the fixed component, is in communication connection with the first communication module and the intelligent terminal respectively, and is used for sending the intermittent temperature value and the continuous temperature value to the intelligent terminal;

the second power module is arranged on the fixed component and used for providing working electric energy for the second communication module and also used for providing charging electric energy for the first power module.

7. The deep temperature measurement device of claim 6, the parent body further comprising:

the folding component is connected with the contraction component in a foldable mode, and the folding component is attached to the contraction component after being folded;

the retraction assembly is slidably connected with the fixed assembly so that the retraction assembly is retracted in the cavity of the fixed assembly.

8. The deep temperature measurement device of claim 6, wherein one end of the flexible body is disposed in the cavity of the fixed component and the other end of the flexible body is attached to the fixed component.

9. The deep temperature measurement device of claim 4, the parent unit further comprising: a fourth temperature sensor and a second processing module;

the fourth temperature sensor is used for collecting the ambient temperature;

the second processing module is used for acquiring the characteristic parameters according to the environment temperature;

the second processing module is further configured to obtain the continuous deep temperature value of the detection target according to the characteristic parameter and the continuous temperature value.

10. The deep temperature measurement device of claim 9, the parent unit further comprising: a display module;

the display module is arranged on the outer surface of the fixed component and used for displaying the environment temperature, the intermittent temperature value, the continuous temperature value or/and the continuous deep temperature value.

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