WO2017000296A1 - Temperature measurement device, central monitoring station, and temperature monitoring system and method therefor - Google Patents

Abstract

A monitoring method for a temperature monitoring system. The monitoring method comprises: allocate a temperature measurement device (10, 20, 30, 40) to each to-be-measured object, so that an identification code of each temperature measurement device (10, 20, 30, 40) identifies a corresponding to-be-measured object; measure the temperature of the to-be-measured object by means of the temperature measurement device (10, 20, 30, 40); the temperature measurement device (10, 20, 30, 40) transmits the temperature and the identification code to the central monitoring station (50); and the central monitoring station (50) displays the temperature corresponding to each to-be-measured object. The temperatures of to-be-measured objects are automatically measured by means of the temperature measurement devices (10, 20, 30, 40) that are in a one-to-one correspondence with to the to-be-measured objects; in another aspect, the central monitoring station (50) displays the temperatures of all the to-be-measured objects in a unified manner, thereby facilitating the management. Also provided are a temperature measurement device, a central monitoring station, and a temperature monitoring system.

Description

Temperature measuring device, central monitoring station, temperature monitoring system and method thereof

[Technical Field]

The invention relates to the technical field of temperature monitoring, in particular to a temperature measuring device, a central monitoring station, a temperature monitoring system and a method thereof.

 【Background technique】

The effect of temperature on biology and the like is very large. For example, in a hospital, the body temperature of a human body has a great influence on a patient's condition. At present, the process of body temperature measurement is generally: an operator, such as a doctor, sends a thermometer to the patient, and then waits for a measurement result, and then the operator retrieves the thermometer, reads the body temperature value, and records the result. The used thermometer is recycled and reused. The hidden cost of reusing a thermometer is high. There is a risk of cross-infection in frequent contact between doctors and patients. At the same time, repeated use of thermometers between different patients is neither hygienic nor cross-infected. Further, manual operation is laborious, cumbersome, inefficient, and error-prone. It is neither convenient nor disturbing the patient's rest to take the patient's cooperation every time the body temperature is measured. Further, the body temperature data cannot be connected to other information systems in the hospital to uniformly display the temperature of all patients.

 [Summary of the Invention]

The technical problem to be solved by the present invention is to provide a temperature measuring device, a central monitoring station, a temperature monitoring system and a method thereof, which can automatically acquire the temperature of each object to be tested, and carry out the temperature of each object to be tested, such as the patient. Unified display for easy management.

In order to solve the above technical problem, a technical solution adopted by the present invention is to provide a monitoring method for a temperature monitoring system, the monitoring method comprising: separately assigning a temperature measuring device to each object to be tested, so that each temperature measuring device The identification code identifies a corresponding object to be tested; the temperature of the object to be tested is measured by the temperature measuring device; the temperature measuring device transmits the temperature and the identification code to the central monitoring station; and the central monitoring station displays the temperature corresponding to each object to be tested.

Wherein the step of measuring the temperature of the object to be tested by the temperature measuring device comprises: measuring the temperature of the object to be tested once every predetermined time by the temperature measuring device.

Wherein, the temperature measuring device and the central monitoring station form a mesh network, and the method further comprises: each temperature measuring device receiving data of the other temperature measuring device and further transmitting, so that the temperature measuring devices relay data to each other, the data includes temperature and An identification code; the step of transmitting the temperature and the identification code to the central monitoring station by the temperature measuring device comprises: each temperature measuring device transmitting the temperature and the identification code to other temperature measuring devices relayed with the temperature measuring device to pass other temperature measurement The device continues to transmit the temperature and identification code until it is transmitted to the central monitoring station.

Wherein, the data further includes a signal strength index, and the method further comprises: each temperature measuring device acquiring a signal strength index of the other temperature measuring device and further relaying the signal strength index to each other until being transmitted to the central monitoring station; the central monitoring station is The signal strength index is combined with a triangle algorithm to obtain the position of each temperature measuring device to locate the position of each object to be tested, wherein the magnitude of the signal strength index is related to the distance between the two temperature measuring devices that are relayed to each other.

In order to solve the above technical problem, another technical solution adopted by the present invention is to provide a temperature measuring device, which includes: a temperature measuring module for measuring the temperature of an object to be tested; a storage module, and a temperature measuring module. The identification code is such that each object to be tested corresponds to an identification code; the transceiver module transmits the temperature and the identification code to the central monitoring station, and the central monitoring station displays the temperature corresponding to each object to be tested.

The temperature measuring device and other temperature measuring devices and the central monitoring station form a mesh network, and the transceiver module further receives data of other temperature measuring devices and further transmits the data, so that the temperature measuring devices relay data to each other, and the data includes temperature and identification. The code, wherein: the transceiver module transmits the temperature and the identification code to other temperature measuring devices relayed with the temperature measuring device to continue transmitting the temperature and the identification code through other temperature measuring devices until transmission to the central monitoring station.

The data further includes a signal strength index, and the transceiver module further acquires the signal strength index of the other temperature measuring devices and relays the signal strength indexes to each other until transmission to the central monitoring station, so that the central monitoring station measures the temperature according to the signal strength index. The device is positioned, wherein the magnitude of the signal strength index is related to the distance of the two temperature measuring devices that are relayed to each other.

In order to solve the above technical problem, another technical solution adopted by the present invention is to provide a central monitoring station, the central monitoring station comprising: a transceiver module for receiving an identification code of a plurality of temperature measuring devices and a measured object to be tested The temperature, wherein the identification code of each temperature measuring device corresponds to an object to be tested; and the display module is configured to display a temperature corresponding to each object to be tested.

Wherein, the plurality of temperature measuring devices and the central monitoring station form a mesh network and relay data to each other; the transceiver module further receives a signal strength index between the two temperature measuring devices mutually relayed in the plurality of temperature measuring devices, wherein The magnitude of the signal strength index is related to the distance between the two temperature measuring devices that are relayed to each other; the central monitoring station further includes a processing module that acquires the position of each temperature measuring device according to the signal strength index and the triangle algorithm.

In order to solve the above technical problem, another technical solution adopted by the present invention is to provide a temperature monitoring system, which includes a temperature measuring device and a central monitoring station, wherein the temperature measuring device includes:

a temperature measuring module for measuring the temperature of an object to be tested;

a storage module, configured to store an identification code of the temperature measurement module, so that each object to be tested corresponds to an identification code;

The first transceiver module transmits the temperature and the identification code to the central monitoring station, and the central monitoring station displays the temperature corresponding to each object to be tested;

The central monitoring station includes:

a second transceiver module, configured to receive an identifier of the plurality of temperature measuring devices and a temperature of the object to be tested, wherein the identifier of each temperature measuring device corresponds to an object to be tested;

A display module for displaying the temperature corresponding to each object to be tested.

Wherein, the temperature measuring device and the other temperature measuring device and the central monitoring station form a mesh network, and the first transceiver module further receives data of other temperature measuring devices and further transmits the data, so that the temperature measuring devices relay data to each other, and the data includes temperature And identification code, where:

The first transceiver module transmits the temperature and identification code to other temperature measuring devices relayed with the temperature measuring device to continue transmitting the temperature and the identification code through other temperature measuring devices until transmission to the central monitoring station.

The data further includes a signal strength index, and the first transceiver module further acquires a signal strength index of the other temperature measuring device and relays the signal strength index to each other until transmission to the central monitoring station, so that the central monitoring station according to the signal strength index The temperature measuring device performs positioning, wherein the magnitude of the signal strength index is related to the distance of the two temperature measuring devices that are relayed to each other.

Wherein, the plurality of temperature measuring devices and the central monitoring station form a mesh network, and relay data to each other;

The second transceiver module further receives a signal strength index between two temperature measuring devices that are mutually relayed in the plurality of temperature measuring devices, wherein the magnitude of the signal strength index is related to the distance between the two temperature measuring devices that are mutually relayed;

The central monitoring station further includes a processing module that acquires the position of each temperature measuring device according to a signal strength index in combination with a triangular algorithm.

The invention has the beneficial effects that the temperature monitoring system of the present invention first assigns a temperature measuring device to each object to be tested, so that the identification code of each temperature measuring device identifies a corresponding waiting to be determined. The object is measured, and then the temperature of the object to be tested is measured by the temperature measuring device, and the temperature and the identification code are transmitted to the central monitoring station, and the central monitoring station displays the temperature corresponding to each object to be tested. Therefore, the present invention can automatically measure the temperature of the object to be tested by the temperature measuring device corresponding to the object to be tested, and when the body temperature of the human body is measured, the phenomenon that the user needs to perform the measurement by the user is avoided. The user experience can be improved; on the other hand, the central monitoring station uniformly displays the temperature of each object to be tested, which is convenient for management.

 [Description of the Drawings]

1 is a schematic structural diagram of a temperature monitoring system according to an embodiment of the present invention;

Figure 2 is a schematic structural view of the temperature measuring device shown in Figure 1;

Figure 3 is a schematic structural view of the central monitoring station shown in Figure 1;

4 is a schematic diagram showing the positioning of a temperature monitoring system according to an embodiment of the present invention;

Figure 5 is a flow chart of a monitoring method of the temperature monitoring system.

【detailed description】

Please refer to FIG. 1. FIG. 1 is a schematic structural diagram of a temperature monitoring system according to an embodiment of the present invention. As shown in FIG. 1, the temperature monitoring system 100 of the present invention includes a central monitoring station 50 and a plurality of temperature measuring devices, such as the temperature measuring devices 10, 20, 30, and 40 shown in FIG.

Referring to FIG. 2 and FIG. 3, FIG. 2 and FIG. 3 are structural diagrams of the temperature measuring device and the central monitoring station shown in FIG. 1, respectively. Here, since the structures of the plurality of temperature measuring devices are the same, the structure of the temperature measuring device 10 shown in Fig. 1 of the present invention is illustrated in detail in Fig. 2 of the present invention.

As shown in FIGS. 2 and 3, the temperature measuring device 10 includes a temperature measuring module 11, a storage module 12, and a transceiver module 13. The central monitoring station 50 includes a transceiver module 51 and a display module 52.

The temperature measuring module 11 is configured to measure the temperature of an object to be tested. The storage module 12 stores the identification code of the temperature measuring module 11 such that each object to be tested corresponds to an identification code. The transceiver module 13 transmits the temperature and identification code to the central monitoring station 50.

The transceiver module 51 of the central monitoring station 50 receives the identification code transmitted by the temperature measuring device 10 and the temperature of the object to be measured measured. It should be noted that the transceiver module 51 also receives the identification code and temperature transmitted by the other plurality of temperature measuring devices 20, 30, and 40. The display module 52 displays the temperature corresponding to each object to be tested.

Therefore, the present invention can automatically measure the temperature of the object to be tested by the temperature measuring device corresponding to the object to be tested, and the central monitoring station uniformly displays the temperature of each object to be tested, which is convenient for management. The temperature monitoring system 100 of the present embodiment can be applied to any occasion where temperature measurement is required, such as in a cold storage for food preservation, or in a hospital. If applied in a hospital, the temperature measuring device 10 can be attached to the patient, each patient corresponds to a temperature measuring device 10, and the temperature measuring device 10 is disposable, thus avoiding the crossover between the patients. The risk of infection. On the other hand, since the temperature measuring device 10 is directly disposed on the patient to measure the body temperature of the human body, the user does not need to operate the user personally, so that the user's experience can be improved.

In the present embodiment, the temperature measuring device 10 and other temperature measuring devices 20, 30 and 40 and the central monitoring station 50 constitute a mesh network. The temperature monitoring system 100 is preferably applied in a mesh network. In a mesh network, any wireless device node can simultaneously act as an AP (Access). Point, access point) and router, each node in the network can send and receive signals, and each node can directly communicate with one or more peer nodes. If the nearest AP is congested due to excessive traffic, the data can be automatically rerouted to a neighboring node with less traffic. And so on, the packet can continue to be routed to the next node closest to it according to the network, until it reaches the final destination. This allows multi-hop access.

The temperature measuring device 10 is a device that is provided on the basis of the Bluetooth chip and has a function of transmitting and measuring temperature. Therefore, the temperature monitoring system 100 of the embodiment of the present invention is specifically applied to a mesh network that transmits by Bluetooth. The temperature measuring device 10 and other temperature measuring devices 20, 30 and 40 and the central monitoring station 50 relay data to each other in the mesh network. As shown in FIG. 1, the temperature measuring device 10 is relayed with the temperature measuring devices 20, 30 and 40, respectively, and the temperature measuring device 20 is further relayed with the temperature measuring device 30, which in turn is associated with the temperature measuring device 40 and the center, respectively. The monitoring station 50 relays and the temperature measuring device 40 is in turn relayed with the central monitoring station 50. Since the temperature measuring device and the central monitoring station in the temperature monitoring system 100 relay data to each other, the temperature monitoring system 100 can transmit data using a low power wireless technology.

The transceiver module 13 of the temperature measuring device 10 further receives data of other temperature measuring devices and further transmits the data, so that the temperature measuring devices relay data to each other. Specifically, the temperature measuring device 10 further includes a processing module 14, and the processing module 14 performs corresponding processing on the data received by the transceiver module 13, for example, compressing the data received by the transceiver module 13 and its own data, and then The transceiver module 13 sends out. Among them, the data includes temperature and identification code. The transceiver module 13 transmits the temperature and identification code to other temperature measuring devices relayed with the temperature measuring device 10 to continue transmitting the temperature and identification code by other temperature measuring devices until transmission to the central monitoring station 50.

As shown in FIG. 1, the transceiver module 13 of the temperature measuring device 10 first transmits the identification code of the temperature measuring device 10 and its measured temperature to the temperature measuring devices 20, 30 and 40 that are mutually relayed with the temperature measuring device 10. The temperature measuring devices 20, 30 and 40 continue to transmit the temperature and identification code of the temperature measuring device 10 to other temperature measuring devices that are relayed to each other. As shown in FIG. 1, the temperature measuring devices 30 and 40 and the central monitoring station 50 are mutually relayed. Therefore, the temperature measuring devices 30 and 40 also transmit the temperature and identification code of the temperature measuring device 10 to the central monitoring station 50. It is to be noted that the temperature measuring devices 20, 30, and 40 also transmit the temperature and identification code measured by themselves when transmitting the temperature and the identification code of the temperature measuring device 10. Therefore, the central monitoring station 50 can receive the temperature and identification code of all of the temperature measuring devices 10, 20, 30, and 40.

The central monitoring station 50 further processes each object to be tested and its temperature in addition to the temperature corresponding to each object to be tested through the display module 52. Specifically, the central monitoring station 50 further includes a processing module 53. The processing module 53 analyzes the identifier and the temperature received by the transceiver module 51, and specifically includes the following analysis:

First: Analyze whether the temperature exceeds the preset temperature threshold and alert you when the preset threshold is exceeded. For example, if the temperature monitoring system 100 is used in a hospital and the measured temperature is the body temperature of the human body, the temperature threshold may be 37.5 degrees. If the processing module 53 finds that the body temperature of the patient to be tested is equal to or greater than the temperature threshold of 37.5 degrees, an alarm is given. The temperature threshold can also vary depending on the object to be tested. For example, in a hospital, patients with different conditions can set different temperature thresholds. For patients with severe disease or temperature affecting the disease, the corresponding temperature threshold can be set lower. On the contrary, the condition is lighter. Or the temperature threshold of the patient whose temperature has little effect on the condition can be set higher.

The process of setting different temperature thresholds for different objects to be tested may be: first setting different temperature thresholds according to different objects to be tested, and then storing the temperature thresholds in the central detecting station 50, after receiving the temperature measuring device 10 When the identification code and temperature transmitted by the transceiver module 13 are compared, the temperature of the temperature measuring device is compared with its corresponding temperature threshold.

The alarm of the embodiment can be audible alarm through an external speaker, or can be alarmed by means of discoloration or flickering of the externally connected lamp, and can also be alarmed by a special display of the display module 52, such as discoloration or zooming or jumping. The embodiment of the present invention does not limit the manner of alarming.

Second: Analyze multiple temperatures of each object to be tested. In this manner, the temperature measuring module 11 measures the temperature of the object to be tested once every predetermined time, that is, the temperature measuring device 11 periodically measures the temperature of the object to be tested, and the transceiver module 13 also periodically transmits the object. These temperatures are to the central monitoring station 50. The processing module 53 of the central monitoring station 50 arranges the received temperatures in chronological order to produce a temperature trend map corresponding to each object to be tested, and then displays it by the display module 52.

Further, it is also possible to analyze the temperature trend graph, for example, to analyze the rise and fall of the temperature in the temperature trend graph. If the rising or falling amplitude exceeds a preset rising threshold or falling threshold, the temperature is highlighted. It should be understood that the identification of the temperature rise and the identification of the temperature drop should be differentiated.

Further, the temperature trend graph can also be analyzed to form a medical body temperature unit.

Therefore, the present invention can transmit the temperature of each object to be tested through the mesh network, and then display and uniformly process the temperature of each object to be tested, which is convenient for management. Especially in the hospital where the object to be tested is a person, and the individual who can move, the temperature monitoring system 100 of the present invention can greatly improve the user experience.

Further, in order to further manage the object to be tested according to the temperature after the temperature of the object to be tested is obtained, the embodiment of the present invention further provides a solution for determining the position of the object to be tested, which is for managing the object to be tested, in particular A subject with mobility capability, such as a patient in a hospital, will provide great convenience, thereby improving management capabilities. The specific positioning process will be detailed below.

The data received by the temperature measuring device in this embodiment further includes a signal strength index. Specifically, the transceiver module of the temperature measuring device further acquires the signal strength indexes of the other temperature measuring devices and relays the signal strength indexes to each other until being transmitted to the central monitoring station 50, so that the central monitoring station 50 according to the signal strength index to the temperature measuring device Positioning. Wherein, the magnitude of the signal strength index is related to the distance between the two temperature measuring devices that are relayed to each other. If the distance is larger, the signal strength index is smaller, and vice versa.

It should be understood that the signal strength index should refer to the signal strength between the two temperature measuring devices. As shown in FIG. 1, the signal intensity indices between the temperature measuring device 10 and the temperature measuring devices 20, 30, and 40 are I8, I5, and I6, respectively. The signal strength index between the temperature measuring devices 20 and 30 is I7, the signal strength indices between the temperature measuring device 30 and the temperature measuring device 40 and the central monitoring station 50 are I3 and I1, and the temperature measuring device 40 and the central monitoring station 50 The signal strength index is I2.

The transceiver module 51 of the central monitoring station 50 receives the signal strength index between the two temperature measuring devices that are mutually relayed among the plurality of temperature measuring devices 10, 20, 30, and 40, and transmits the signal strength indices to the processing module. 53. The processing module 53 acquires the position of each temperature measuring device according to the signal strength index in combination with the triangle algorithm to locate the position of each object to be tested.

This embodiment describes an example of the process of positioning the processing module 53. Specifically, the object to be tested is a patient in a hospital. Please refer to FIG. 1 and FIG. 4, wherein FIG. 4 is a schematic diagram of the positioning of the temperature monitoring system 100 according to an embodiment of the present invention. As shown in FIG. 1 and FIG. 4, the transceiver module 51 of the central monitoring station 50 receives a signal strength index between every two temperature measuring devices, such as I1, I2, I3, I5, I6, and I7 shown in FIG. I8. The processing module 53 calculates the corresponding distances of the signal strength indexes, and then obtains the distance between the adjacent two temperature measuring devices as shown in FIG. 4 or the temperature measuring device and the central monitoring station according to the triangle algorithm. D1, d2, d3, d5, d6, d7 and d8.

In the embodiment of the present invention, the position of the central detecting station 50 and one of the temperature measuring devices, for example 40, in the temperature monitoring system 100 is first determined. For example, as shown in FIG. 4, the central monitoring station 50 is the origin of the coordinate system, and its coordinates are ( 0, 0), the coordinate position of the temperature measuring device 40 is obtained at the same time, for example, (x1, y1). Then, based on the triangular relationship between the central monitoring station 50 and the temperature measuring devices 40 and 30, in conjunction with the coordinate relationship between the central monitoring station 50 and the temperature measuring device 40, the coordinate position of the temperature measuring device 30 can be derived, for example, (x2, y2). By analogy, the coordinate positions of the temperature measuring devices 10 and 20 can be calculated. In the actual application, the actual position is corresponding to the coordinate system, and the actual positions of the temperature measuring devices 10, 20, 30, and 40 can be known based on the corresponding relationship.

Since each temperature measuring device is correspondingly disposed on an object to be tested, the embodiment of the present invention can know the actual position of the object to be tested. Therefore, when the temperature of the object to be tested is abnormal, the position of the object to be tested is provided in time, which facilitates the processing of the object to be tested. For example, in a hospital, if a patient's temperature is significantly increased or decreased, the patient can be quickly found to treat it, thereby greatly ensuring the therapeutic effect.

Further, the data sent by the embodiment of the present invention further includes a key. That is, each temperature measuring device further receives a corresponding key for decrypting the encrypted data information in addition to the temperature, identification code and signal strength index of the temperature measuring device that is relayed to each other. Preferably, in the embodiment of the present invention, the key, the identification code, the temperature, and the signal strength index may be compressed and packaged and sent together.

As described above, the embodiment of the present invention can identify different temperatures of objects to be tested, and can also locate different objects to be tested.

The embodiment of the invention also provides a monitoring method of the temperature monitoring system, which is applied to the temperature monitoring system 100 described above. Referring to FIG. 5, FIG. 5 is a flowchart of a temperature monitoring method according to an embodiment of the present invention, and the method includes the following steps:

Step S1: A temperature measuring device is respectively assigned to each object to be tested, so that the identification code of each temperature measuring device identifies a corresponding object to be tested.

Step S2: The temperature of the object to be tested is measured by a temperature measuring device.

The step is specifically: the temperature measuring device measures the temperature of the object to be tested once every predetermined time. Thereby, the temperature of the object to be tested can be comprehensively monitored.

Step S3: The temperature measuring device transmits the temperature and the identification code to the central monitoring station.

The plurality of temperature measuring devices and the central monitoring station form a mesh network, which is preferably a mesh network. The details are as described above, and are not described here.

Moreover, each temperature measuring device of the embodiment further receives data of other mutually relayed temperature measuring devices and further transmits the data, so that the temperature measuring devices relay data to each other, the data including temperature, identification code, and signal strength. Index and key data. The data can be packaged and compressed into data packets for transmission.

Specifically, each temperature measuring device transmits the temperature, the identification code, the signal strength index, and the data packet of the key to other temperature measuring devices that are mutually relayed to continue transmitting the data packet through other temperature measuring devices until Transfer to the central monitoring station.

Step S4: The central monitoring station displays the temperature corresponding to each object to be tested.

The step is specifically: the central monitoring station receives the data packet transmitted by the temperature measuring device, and displays and processes the data of the data packet. Specifically, the temperature of each object to be tested is displayed, and the analysis is performed according to the displayed temperature. The specific analysis process is as described above, and is not described here. On the other hand, the position of each temperature measuring device is obtained according to the signal strength index combined with the triangle algorithm, and each temperature measuring device is positioned to locate the position of each object to be tested. Wherein, the magnitude of the signal strength index is related to the distance between the two temperature measuring devices that are relayed to each other. The specific positioning process is as described above, and will not be described here.

In summary, the embodiment of the present invention can identify different temperatures of objects to be tested, and can also locate different objects to be tested.

The above is only the embodiment of the present invention, and is not intended to limit the scope of the invention, and the equivalent structure or equivalent process transformation of the present invention and the contents of the drawings may be directly or indirectly applied to other related technologies. The fields are all included in the scope of patent protection of the present invention.

Claims (13)

1. A monitoring method of a temperature monitoring system, wherein the monitoring method comprises:

   Each of the objects to be tested is respectively assigned a temperature measuring device, so that the identification code of each of the temperature measuring devices identifies a corresponding object to be tested;

   Measuring, by the temperature measuring device, a temperature of the object to be tested;

   The temperature measuring device transmits the temperature and the identification code to a central monitoring station;

   The central monitoring station displays the temperature corresponding to each object to be tested.
2. The monitoring method according to claim 1, wherein the measuring the temperature of the object to be tested by the temperature measuring device comprises:

   The temperature measuring device measures the temperature of the object to be tested once every predetermined time.
3. The monitoring method according to claim 1, wherein the temperature measuring device and the central monitoring station constitute a mesh network, the method further comprising:

   Each temperature measuring device receives data of the other temperature measuring device and further transmits the data, so that the temperature measuring device relays the data to each other, the data including the temperature and the identification code;

   The step of the temperature measuring device transmitting the temperature and the identification code to the central monitoring station includes:

   Each of the temperature measuring devices transmits the temperature and the identification code to the other temperature measuring device relayed with the temperature measuring device to pass the temperature and the The identification code continues to be transmitted until it is transmitted to the central monitoring station.
4. The monitoring method of claim 3, wherein the data further comprises a signal strength index, the method further comprising:

   Each of the temperature measuring devices acquires a signal strength index of the other temperature measuring device and further relays the signal strength index to each other until transmission to the central monitoring station;

   The central monitoring station acquires a position of each of the temperature measuring devices according to the signal strength index in combination with a triangle algorithm to locate a position of each of the objects to be tested, wherein the magnitude of the signal strength index is mutually relayed The distance between the two temperature measuring devices is related.
5. A temperature measuring device, wherein the temperature measuring device comprises:

   a temperature measuring module for measuring the temperature of an object to be tested;

   a storage module, configured to store an identifier of the temperature measurement module, such that each of the objects to be tested corresponds to an identification code;

   The transceiver module transmits the temperature and the identification code to a central monitoring station, and the central monitoring station displays a temperature corresponding to each object to be tested.
6. The temperature measuring device according to claim 5, wherein said temperature measuring device and other temperature measuring devices and a central monitoring station form a mesh network, said transceiver module further receiving data of said other temperature measuring device and further transmitting, Having the temperature measuring devices relay the data to each other, the data including the temperature and the identification code, wherein:

   The transceiver module transmits the temperature and the identification code to the other temperature measuring device relayed with the temperature measuring device to continue the temperature and the identification code by the other temperature measuring device Transfer until transmission to the central monitoring station.
7. The temperature measuring device according to claim 6, wherein said data further comprises a signal strength index, said transceiver module further acquiring signal strength indices of said other temperature measuring devices and relaying signal strength indices to each other until transmission Going to the central monitoring station, causing the central monitoring station to locate the temperature measuring device according to the signal strength index, wherein the magnitude of the signal strength index is related to the distance between two temperature measuring devices that are mutually relayed .
8. A central monitoring station, wherein the central monitoring station comprises:

   a transceiver module, configured to receive an identifier of the plurality of temperature measuring devices and a temperature of the object to be tested, wherein the identifier of each of the temperature measuring devices corresponds to an object to be tested;

   A display module for displaying the temperature corresponding to each object to be tested.
9. The central monitoring station according to claim 8, wherein said plurality of temperature measuring devices and said central monitoring station form a mesh network and relay data to each other;

   The transceiver module further receives a signal strength index between two temperature measuring devices that are mutually relayed among the plurality of temperature measuring devices, wherein the magnitude of the signal strength index is different from the distance between the two temperature measuring devices that are mutually relayed Related

   The central monitoring station further includes a processing module that obtains a location of each of the temperature measuring devices in accordance with the signal strength index in conjunction with a triangular algorithm.
10. A temperature monitoring system, wherein the temperature monitoring system comprises a temperature measuring device and a central monitoring station, wherein the temperature measuring device comprises:

    a temperature measuring module for measuring the temperature of an object to be tested;

    a storage module, configured to store an identifier of the temperature measurement module, such that each of the objects to be tested corresponds to an identification code;

    The first transceiver module transmits the temperature and the identification code to a central monitoring station, and the central monitoring station displays a temperature corresponding to each object to be tested;

    The central monitoring station includes:

    a second transceiver module, configured to receive an identifier of the plurality of temperature measuring devices and a temperature of the object to be tested, wherein the identifier of each of the temperature measuring devices corresponds to an object to be tested;

    A display module for displaying the temperature corresponding to each object to be tested.
11. A temperature monitoring system according to claim 10, wherein said temperature measuring means and other temperature measuring means and central monitoring station form a mesh network, said first transceiver module further receiving data of said other temperature measuring means and further Transmitting, wherein the temperature measuring devices relay the data to each other, the data including the temperature and the identification code, wherein:

    The first transceiver module transmits the temperature and the identification code to the other temperature measuring device relayed with the temperature measuring device to pass the temperature and the identification by the other temperature measuring device The code continues to transmit until it is transmitted to the central monitoring station.
12. The temperature monitoring system according to claim 11, wherein the data further comprises a signal strength index, the first transceiver module further acquiring a signal strength index of the other temperature measuring device and relaying the signal strength index to each other, Until the transmission to the central monitoring station, causing the central monitoring station to locate the temperature measuring device according to the signal strength index, wherein the magnitude of the signal strength index and the two temperature measuring devices that are mutually relayed Distance related.
13. The temperature monitoring system according to claim 10, wherein said plurality of temperature measuring devices and said central monitoring station form a mesh network and relay data to each other;

    The second transceiver module further receives a signal strength index between two temperature measuring devices that are mutually relayed among the plurality of temperature measuring devices, wherein the magnitude of the signal strength index and the two temperature measuring devices that are mutually relayed Related to the distance;

    The central monitoring station further includes a processing module that obtains a location of each of the temperature measuring devices in accordance with the signal strength index in conjunction with a triangular algorithm.