CN219810550U - Temperature detection monitoring system - Google Patents

Abstract

The utility model provides a temperature detection monitoring system, which comprises a machine, a temperature control system and a material taking assembly, wherein the machine comprises a processing assembly for processing products, and a first temperature acquisition assembly for acquiring the temperature of the products is arranged in the processing assembly; the temperature control system comprises an alarm module and a monitoring module, wherein the monitoring module is used for receiving the acquisition signal of the first temperature acquisition component and feeding back the signal to the machine, and the alarm module is used for sending out an alarm signal; the material taking assembly comprises a fixing part and a grabbing part, one end of the grabbing part is connected with the fixing part, the other end of the grabbing part is used for grabbing products in the processing assembly, and a second temperature acquisition assembly used for acquiring the temperature of the grabbed products is arranged on the grabbing part. The temperature of the product during processing and material taking is detected through the first acquisition component and the second acquisition component, and the alarm module timely prompts the product with abnormal temperature, so that the problems of untimely alarm, low product qualification rate and the like caused by untimely monitoring of the temperature of the product are solved.

Description

Temperature detection monitoring system

Technical Field

The utility model relates to the technical field of mold temperature detection, in particular to a temperature detection monitoring system.

Background

Along with the continuous development of the automation technology field and the demands of enterprises on the automation technology, the enterprises are urgent to realize centralized monitoring of automation control so as to view the running condition of each automation device in real time, and when abnormality occurs, the system can give an alarm in time to remind engineers of processing.

However, in the processing processes of magnesium aluminum alloy and the like, the current automatic construction equipment cannot monitor the processing temperature condition of the product in real time, and the product cannot be early-warned and treated in time when the temperature is abnormal, so that the problems of lower qualification rate of the product, high cost and the like are caused.

Disclosure of Invention

The utility model provides a temperature detection monitoring system, which aims to solve the problems of low product qualification rate, high cost and the like caused by untimely monitoring and early warning in the product processing process.

Embodiments of the present utility model are implemented as follows:

a temperature detection monitoring system, comprising:

the machine comprises a processing assembly, wherein the processing assembly is used for processing products, the processing assembly is provided with a first temperature acquisition assembly, and the first temperature acquisition assembly is used for acquiring the temperature of the products in the processing assembly;

the temperature control system is arranged on one side of the machine table and comprises an alarm module and a monitoring module, the monitoring module is in communication connection with the first temperature acquisition assembly and is used for receiving an acquisition signal of the first temperature acquisition assembly and feeding back a signal to the machine table, and the alarm module is used for sending an alarm signal when the monitoring module monitors that the temperature of the product is not in a preset temperature range;

the material taking assembly comprises a fixing part and a grabbing part, wherein the fixing part is arranged at intervals with the machine table, one end of the grabbing part is connected with the fixing part, the other end of the grabbing part is used for grabbing a product in the processing assembly, a second temperature acquisition assembly is arranged on the grabbing part and is in communication connection with the monitoring module, and the second temperature acquisition assembly is used for acquiring the temperature of the grabbed product and sending an acquisition signal to the monitoring module.

Therefore, the temperature of the product is detected through the first acquisition component and the second acquisition component in the processing stage and the material taking stage of the product, the alarm module timely prompts the product with abnormal temperature, and a machine or a worker can make corresponding operation according to prompt information, so that the problem of overheating or insufficient heating of the product is reduced, and the problems of untimely alarm, low product qualification rate, high cost and the like caused by the fact that the temperature of the product in each processing stage is not monitored in time are solved.

In a possible implementation manner, the temperature control system further comprises a parameter setting module, wherein the parameter setting module is electrically connected with the monitoring module, and the parameter setting module is used for setting the highest temperature and the lowest temperature of the preset temperature range.

In one possible embodiment, the processing assembly further comprises a stamping die, the stamping die comprises an upper die and a lower die matched with the upper die, the upper die is provided with a first molding cavity, the lower die is provided with a second molding cavity corresponding to the first molding cavity, the first temperature acquisition assembly comprises a first temperature sensor, and the first temperature sensor is arranged at the top of the first molding cavity and/or at the bottom of the second molding cavity.

In one possible embodiment, a plurality of the first temperature sensors are distributed at intervals on the top of the first molding cavity and/or on the bottom of the second molding cavity.

In one possible embodiment, the second temperature acquisition assembly includes a second temperature sensor, the second temperature sensor being provided on one side of the gripping portion, the second temperature sensor being connected to the monitoring module.

In one possible implementation manner, the temperature detection monitoring system further comprises a stock piece, wherein the stock piece is located on one side of the material taking assembly, and the stock piece is used for temporarily storing products with abnormal temperature detection.

In one possible implementation manner, a suction part is arranged on one side of the grabbing part, the suction part comprises a plurality of suction heads, the suction heads are symmetrically distributed on one side of the grabbing part, and the suction heads are used for sucking the product.

In one possible implementation manner, the grabbing part is further provided with an air blowing part, and the air blowing part is arranged between the two suction heads and opposite to the second temperature acquisition component.

In one possible embodiment, the temperature control system further comprises a storage module for storing the processing data of the product collected by the first temperature collection assembly.

In one possible implementation manner, the machine includes a first machine, a second machine and a third machine, where the first machine, the second machine and the third machine are sequentially arranged at intervals, the first machine, the second machine and the third machine are respectively in communication connection with the temperature control system, and the temperature control system is used for respectively detecting temperature conditions of the products in the first machine, the second machine and the third machine under different processing states.

The temperature detection monitoring system comprises the steps that firstly, a material taking assembly grabs a product into a processing assembly of a first machine table; then, an upper die and a lower die in the processing assembly process products, in the product processing process, a first temperature sensor in a first acquisition assembly acquires the temperature of the products in the processing assembly, the acquired temperature of the products is transmitted to a monitoring module through a temperature controller, and when the monitoring module monitors that the temperature of the products in the processing assembly is not in a preset temperature range, an alarm signal is sent out by an alarm module; then, a grabbing part in the material taking assembly grabs the product in the first machine to a second machine, and a second temperature acquisition assembly arranged on the grabbing part acquires the temperature of the product grabbed by the grabbing part in the grabbing process; finally, after the grabbing part grabs the grabbed product to the second machine, the first acquisition component in the second machine acquires the temperature of the product, and when the monitoring module monitors that the temperature of the product in the processing component is not in the preset temperature range, the alarm module sends out an alarm signal again. So, at every stage of product processing, all have first collection subassembly and second collection subassembly to gather the temperature of product, when the temperature is not in the scope of predetermineeing, alarm module sends out the alarm to the product temperature of each processing stage of untimely control of product temperature has not been solved and has led to the fact the alarm untimely, the product qualification rate is low, the cost is high grade scheduling problem.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the following description will briefly describe the drawings in the embodiments, it being understood that the following drawings only illustrate some embodiments of the present utility model and should not be considered as limiting the scope, and that other related drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic structural diagram of a temperature detecting and monitoring system according to an embodiment of the utility model.

Fig. 2 is a schematic diagram of a part of a temperature detecting and monitoring system according to an embodiment of the utility model. Fig. 3 is a schematic view of the processing assembly of fig. 1.

FIG. 4 is a schematic diagram of the temperature control system of FIG. 1.

Fig. 5 is a schematic view of the take-off assembly of fig. 1.

Fig. 6 is a schematic view of the gripper of the take-out assembly of fig. 5.

Fig. 7 is a schematic diagram of a temperature detecting and monitoring system according to an embodiment of the utility model.

Description of main reference numerals:

temperature detection monitoring system 100

Machine table 10

Machining assembly 11

First temperature acquisition assembly 12

First temperature sensor 121

Stamping die 13

Upper die 131

Lower die 132

First molding cavity 133

Second molding cavity 134

First machine 14

Second machine 15

Third machine 16

Temperature control system 20

Display assembly 21

Alarm module 22

Monitoring module 23

Parameter setting module 24

Temperature setting module 241

Compensation setting module 242

Memory module 25

Material taking assembly 30

Fixing portion 31

Gripping part 32

Suction portion 321

Suction head 322

Blowing part 323

Second temperature acquisition component 33

Second temperature sensor 331

First take out assembly 34

Second take out assembly 35

Third take off assembly 36

Stock piece 40

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments.

It will be understood that when an element is referred to as being "fixed to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. When an element is referred to as being "disposed on" another element, it can be directly on the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like are used herein for illustrative purposes only.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this utility model belongs. The terminology used herein in the description of the utility model is for the purpose of describing particular embodiments only, and are not intended to limit the utility model. The term "or/and" as used herein includes any and all combinations of one or more of the associated listed items.

Some embodiments of the utility model are described in detail. The following embodiments and features of the embodiments may be combined with each other without collision.

Examples

Referring to fig. 1 to 7, the present embodiment provides a temperature detection and monitoring system 100, which is used for monitoring the temperature of a product in real time in the production process of an intelligent factory, and giving an alarm in time when the temperature of the product is abnormal. In this embodiment, the product may be a metal working product, for example, a product working product of a material such as magnesium, aluminum, or the like, and in other embodiments, may be a workpiece other than the metal working product, which is not limited to this utility model.

The temperature detection and monitoring system 100 comprises a machine 10, a temperature control system 20, a material taking assembly 30 and a material storage 40. The machine 10 comprises a processing assembly 11, wherein the processing assembly 11 is used for processing products, a first temperature acquisition assembly 12 is arranged in the processing assembly 11, and the first temperature acquisition assembly 12 is used for acquiring the temperature of the products in the processing assembly 11. The temperature control system 20 is located board 10 one side, and temperature control system 20 includes display module 21, alarm module 22 and monitoring module 23, and wherein, alarm module 22 and monitoring module 23 are all located in the display module 21, and monitoring module 23 communication connection first temperature acquisition assembly 12, monitoring module 23 are used for receiving the acquisition signal of first temperature acquisition assembly 12 and feedback signal to board 10, and alarm module 22 is used for sending alarm signal when monitoring module 23 monitors that the temperature of the product that first temperature acquisition assembly 12 gathered is not in the default range. The alarm signal may be displayed on the display panel of the display assembly 21, or may be provided with a prompt audio through an audio assembly connected to the display assembly 21. The material taking component 30 is arranged on one side of the machine table 10 at intervals and is in communication connection with the temperature control system 20, the material taking component 30 comprises a fixing part 31 and a grabbing part 32, the fixing part 31 and the machine table 10 are arranged at intervals, one end of the grabbing part 32 is connected with the fixing part 31, the other end of the grabbing part 32 is used for grabbing products in the processing component 11, a second temperature acquisition component 33 is arranged on the grabbing part 32, the second temperature acquisition component 33 is in communication connection with the monitoring module 23 and is used for acquiring the temperature of the products when the grabbing part 32 grabs the products and sending acquisition signals to the monitoring module 23. The stock piece 40 is disposed at one side of the material taking assembly 30, and the stock piece 40 is used for temporarily storing the product with abnormal temperature detection. In this embodiment, the storage member 40 is a material frame, which is a frame with one end closed and the other end open, so that the material taking assembly 30 is convenient to grasp and place the product with abnormal temperature detection into the material frame, and in other embodiments, the storage member 40 may be other components besides the material frame, such as a tray, etc., and the utility model is not limited herein.

Before the product is processed, the grabbing part 32 of the material taking assembly 30 grabs the product to be processed into the processing assembly 11 of the machine table 10, in the process that the grabbing part 32 grabs the product to be processed, the second temperature acquisition assembly 33 arranged on the grabbing part 32 can acquire the temperature of the grabbed product, the acquired temperature is fed back to the temperature control system 20, the temperature of the product before processing is recorded by the temperature control system 20, and the machine table 10 can set parameters such as heating feeding, heating duration and the like of the value processing assembly 11 according to the information recorded by the temperature control system 20. After the product to be processed is placed in the processing assembly 11, the processing assembly 11 processes the product, and the processing process comprises a hot-press plastic process. Meanwhile, in the process of processing the product, the first temperature acquisition component 12 arranged in the processing component 11 acquires the temperature of the product in real time, and transmits the acquired product temperature information to the monitoring module 23 of the temperature control system 20. When the monitoring module 23 monitors that the real-time temperature of the product transmitted by the first temperature acquisition component 12 and the second temperature acquisition component 33 is not within the preset range, the alarm module 22 gives an alarm, the monitoring module 23 feeds back information of abnormal temperature detection to the machine 10, and the machine 10 controls the processing component 11 to stop processing the product. After the processing procedure is finished, when the material taking assembly 30 takes out the product from the processing assembly 11, the second temperature collecting assembly 33 on the grabbing portion 32 can further detect the temperature of the product again, further judge whether the temperature of the product after hot pressing processing meets the requirement, if so, send the product to the next processing equipment, if not, judge that the processing of the product is bad, and the staff or the machine can adjust the heating parameters according to the detection result. The temperature acquisition process of the product processing process through the first temperature acquisition component 12 and the second temperature acquisition component 33 can monitor the temperature conditions of the products in different processing states in real time, and when the abnormal temperature is detected, the alarm module 22 timely sends out an alarm signal, so that the problems of low product qualification rate, high cost and the like caused by the fact that the temperature of the products cannot be detected in place in the processing process are avoided. The first temperature acquisition assembly 12 and the second temperature acquisition assembly 33 respectively arranged in the processing assembly 11 and the material taking assembly 30 are comprehensively used, so that the temperature of a product can be detected in multiple directions and multiple angles, the detection accuracy is improved, and the misjudgment condition is reduced.

Specifically, referring to fig. 1 to 3, the temperature control system 20 further includes a parameter setting module 24 and a storage module 25. The parameter setting module 24 is electrically connected to the monitoring module 23, the parameter setting module 24 includes a temperature setting module 241 and a compensation setting module 242, and the temperature setting module 241 and the compensation setting module 242 are used for setting the highest temperature and the lowest temperature of the preset temperature range. A parameter setting module 24 and a memory module 25 are also provided within the display assembly 21. In this embodiment, the temperature setting module 241 and the compensation setting module 242 may be set by an engineer according to practical situations, for example, the temperature setting module 241 may be set to 200 ℃, the compensation setting module 242 may be set to 30 ℃, and the maximum temperature in the preset temperature range is 200 ℃ +30 ℃ =230 ℃, and the minimum temperature in the preset temperature range is 200 ℃ -30 ℃ =170 ℃, so as to obtain the preset temperature range of 170 ℃ -230 ℃. The temperature range is merely an example, and the present utility model is not limited to the preset temperature range, and the temperature values of the temperature setting module 241 and the compensation setting module 242 may be set according to actual conditions, thereby obtaining the preset temperature range. The storage module 25 is used for storing processing data of the product collected by the first temperature collection assembly 12. The processing data includes, but is not limited to, heating temperature, heating duration, variation of heating temperature on a time axis, and the like. When the monitoring module 23 detects that the product temperature is abnormal, an engineer can check historical product heating temperature information in the storage module 25, so that the engineer can analyze the reason of the abnormal product processing process conveniently, and the processing efficiency of the product is improved.

Further, as shown in fig. 1 to 3, the processing assembly 11 further includes a stamping die 13, where the stamping die 13 includes an upper die 131 and a lower die 132 matched with the upper die 131, the upper die 131 is provided with a first molding cavity 133, the lower die 132 is provided with a second molding cavity 134 corresponding to the first molding cavity 133, the first temperature collecting assembly 12 includes a first temperature sensor 121, and the first temperature sensor 121 is disposed on top of the first molding cavity 133 and/or on bottom of the second molding cavity 134. The first temperature sensor 121 is electrically connected to the monitoring module 23. The plurality of first temperature sensors 121 are spaced apart from the top of the first molding cavity 133 and/or the bottom of the second molding cavity 134. In the present embodiment, the first temperature sensor 121 is provided at the top of the first molding cavity 133 and at the bottom of the second molding cavity 134. The number of the first temperature sensors 121 provided at the top of the first molding cavity 133 or the bottom of the second molding cavity 134 may be two or more. For example, two first temperature sensors 121 may be disposed at intervals on the top of the first molding cavity 133, and two first temperature sensors 121 may be disposed at intervals on the bottom of the second molding cavity 134. Three first temperature sensors 121 may be disposed at intervals on the top of the first molding cavity 133, and three first temperature sensors 121 may be disposed at intervals on the bottom of the second molding cavity 134, so as to detect the temperatures of various parts of the product in real time. The present utility model does not limit the number of first temperature sensors 121.

Specifically, referring to fig. 5 and 6, a suction portion 321 is disposed at one side of the grabbing portion 32, the suction portion 321 includes a plurality of suction heads 322, the suction heads 322 are symmetrically distributed at one side of the grabbing portion 32, and the suction heads 322 are used for sucking the product. The symmetrically distributed suction heads 322 can balance the stress of the product everywhere, and reduce the problem of accidental falling of the product. The suction head 322 may be made of a high temperature resistant silica gel material, so as to prevent the suction head 322 from being damaged when the gripping portion 32 grips a high temperature product in the processing assembly 11, and one or more suction heads 322 may be used, and in other embodiments, the suction head 322 may be made of other high temperature resistant materials, and the materials and the number of the suction heads 322 are not set in the present utility model. The grabbing part 32 is further provided with an air blowing part 323, and the air blowing part 323 is arranged between the two suction heads 322 and opposite to the second temperature acquisition component 33. The second temperature acquisition component 33 includes a second temperature sensor 331, the second temperature sensor 331 is disposed on one side of the grabbing portion 32, and the second temperature sensor 331 is connected to the monitoring module 23. In this embodiment, two suction heads 322 are respectively disposed on opposite sides of the grabbing portion 32, wherein an air blowing portion 323 is disposed between the two suction heads 322 on one side, and is used for cleaning the appearance of the product and blowing the magazines on the surface of the product during the process of grabbing the product by the grabbing portion 32; the second temperature sensor 331 is disposed between the two suction heads 322 at the other side, and the second temperature sensor 331 may be an infrared sensor or may be other temperature collecting devices besides an infrared sensor, so long as the second temperature sensor 331 can collect the temperature of the product in real time during the process of grabbing the product by the grabbing portion 32. The suction portion 321 is further provided with a strip-shaped groove 324, and one end of the suction head 322 is movably installed in the strip-shaped groove 324, so that an engineer can adjust the position of the suction head 322 according to actual conditions.

Referring to fig. 1, fig. 2, and fig. 7, the machine 10 may include a first machine 14, a second machine 15, and a third machine 16, where the first machine 14, the second machine 15, and the third machine 16 are sequentially disposed at intervals, and the first machine 14, the second machine 15, and the third machine 16 are respectively connected with a temperature control system 20 in a communication manner, where the temperature control system 20 is configured to detect temperature conditions of products in the first machine 14, the second machine 15, and the third machine 16 in different processing states. In this embodiment, the material taking assemblies 30 are disposed on one sides of the first machine 14, the second machine 15, and the third machine 16, and the material taking assemblies 30 disposed on the first machine 14, the second machine 15, and the third machine 16 may be respectively denoted as a first material taking assembly 34, a second material taking assembly 35, and a third material taking assembly 36. When the grabbing portion 32 of the first material taking assembly 34 grabs the product to be processed into the processing assembly 11 in the first machine 14, the processing assembly 11 of the first machine 14 starts to perform the first processing on the product, and during the first processing on the product, the first temperature collecting assembly 12 in the processing assembly 11 of the first machine 14 collects the temperature of the product at this time, and feeds back the collected temperature information of the product to the temperature control system 20, and the monitoring module 23 of the temperature control system 20 monitors in real time whether the temperature information of the product exceeds the preset temperature range. After the first processing of the product by the processing component 11 in the first machine 14 is completed, and the monitoring module 23 does not monitor that the product sends out abnormal temperature information in the first processing process, the second material taking component 35 grabs the product in the first machine 14 into the processing component 11 in the second machine 15 for performing second product processing. In the process of grabbing the product in the first machine 14 by the second material grabbing assembly 35, the second temperature collecting assembly 33 in the second material grabbing assembly 35 collects the real-time temperature of the grabbed product, so as to prevent the problem that the product temperature possibly drops and exceeds the preset temperature range due to the influence of the outdoor temperature in the grabbing process, so that the subsequent processing of the product does not meet the process standard, and the product qualification rate is reduced. Thereafter, the second processing is performed on the product by the processing component 11 of the second machine 15, and the temperature monitoring process and the product processing process can refer to the first machine 14, which is not described herein.

In the temperature detection and monitoring system 100 of fig. 1 to 7, on the one hand, the temperature of the product during processing is monitored by the first temperature acquisition assembly 12 within the processing assembly 11. On the other hand, the temperature of the gripped product is monitored by the gripping portion 32 during gripping of the product. When the monitoring module 23 monitors that the temperature of the product is abnormal, the alarm module 22 alarms in time to remind an engineer to process the product, and meanwhile, the temperature control system 20 feeds temperature abnormal information back to the machine 10 and the material taking assembly 30, so that the processing assembly 11 of the machine 10 can control the grabbing action of the processing assembly 11 on the product to continue processing and the material taking assembly 30. Therefore, the temperature monitoring process of the processing process of each stage of the product is completed, and when the temperature detection abnormality occurs in the processing process of each stage, the alarm can be given in time to remind engineers to check and process in time. Therefore, the problems of low product qualification rate, high cost and the like caused by the fact that the temperature of the product is not in place in the real-time monitoring process of the product are avoided.

The above embodiments are only for illustrating the technical solution of the present utility model and not for limiting the same, and although the present utility model has been described in detail with reference to the above preferred embodiments, it should be understood by those skilled in the art that modifications and equivalents may be made thereto without departing from the spirit and scope of the technical solution of the present utility model.

Claims (10)

1. The utility model provides a temperature detection monitored control system, includes the board, the board includes processing subassembly, processing subassembly is used for processing the product, its characterized in that still includes:

the processing assembly is provided with a first temperature acquisition assembly, and the first temperature acquisition assembly is used for acquiring the temperature of the product in the processing assembly;

the temperature control system is arranged on one side of the machine table and comprises an alarm module and a monitoring module, the monitoring module is in communication connection with the first temperature acquisition assembly and is used for receiving an acquisition signal of the first temperature acquisition assembly and feeding back a signal to the machine table, and the alarm module is used for sending an alarm signal when the monitoring module monitors that the temperature of the product is not in a preset temperature range;

the material taking assembly comprises a fixing part and a grabbing part, wherein the fixing part is arranged at intervals with the machine table, one end of the grabbing part is connected with the fixing part, the other end of the grabbing part is used for grabbing a product in the processing assembly, a second temperature acquisition assembly is arranged on the grabbing part and is in communication connection with the monitoring module, and the second temperature acquisition assembly is used for acquiring the temperature of the grabbed product and sending an acquisition signal to the monitoring module.

2. The temperature detection monitoring system of claim 1, wherein the temperature control system further comprises a parameter setting module electrically connected to the monitoring module, the parameter setting module configured to set a maximum temperature and a minimum temperature of the preset temperature range.

3. The temperature detection and monitoring system according to claim 1, wherein the processing assembly further comprises a stamping die, the stamping die comprises an upper die and a lower die matched with the upper die, the upper die is provided with a first molding cavity, the lower die is provided with a second molding cavity corresponding to the first molding cavity, the first temperature acquisition assembly comprises a first temperature sensor, the first temperature sensor is arranged at the top of the first molding cavity and/or the bottom of the second molding cavity, and the first temperature sensor is electrically connected with the monitoring module.

4. A temperature detection and monitoring system according to claim 3, wherein a plurality of the first temperature sensors are spaced apart at the top of the first molding cavity and/or at the bottom of the second molding cavity.

5. The temperature detection and monitoring system of claim 1, wherein the second temperature acquisition assembly comprises a second temperature sensor disposed on one side of the grasping portion, the second temperature sensor being coupled to the monitoring module.

6. The temperature detection and monitoring system according to claim 1, further comprising a stock piece, the storage part is positioned on one side of the material taking assembly and is used for temporarily storing products with abnormal temperature detection.

7. The temperature detection and monitoring system according to claim 5, wherein a suction part is arranged at one side of the grabbing part, the suction part comprises a plurality of suction heads, the suction heads are symmetrically distributed at one side of the grabbing part, and the suction heads are used for sucking the product.

8. The temperature detection and monitoring system according to claim 7, wherein the gripping portion is further provided with an air blowing portion, and the air blowing portion is disposed between the two suction heads and opposite to the second temperature acquisition assembly.

9. The temperature detection and monitoring system of claim 1, wherein the temperature control system further comprises a memory module for storing the process data of the product acquired by the first temperature acquisition assembly.

10. The temperature detection and monitoring system according to claim 1, wherein the machine comprises a first machine, a second machine and a third machine, the first machine, the second machine and the third machine are sequentially arranged at intervals, the first machine, the second machine and the third machine are respectively in communication connection with the temperature control system, and the temperature control system is used for respectively detecting the temperature conditions of the products in the first machine, the second machine and the third machine in different processing states.