CN210727766U - Intelligent CT bulb tube system - Google Patents
Intelligent CT bulb tube system Download PDFInfo
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- CN210727766U CN210727766U CN201920875503.1U CN201920875503U CN210727766U CN 210727766 U CN210727766 U CN 210727766U CN 201920875503 U CN201920875503 U CN 201920875503U CN 210727766 U CN210727766 U CN 210727766U
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Abstract
The utility model relates to a radiodiagnosis instrument technical field, concretely relates to intelligence CT bulb system. It includes: a bulb body; the monitoring assembly is arranged on the bulb tube body and used for monitoring the running state of the bulb tube system in real time; and the control platform is connected with the monitoring assembly and used for recording data measured by the monitoring assembly, judging whether the data is in a preset range or not, and judging that a fault occurs when the data exceeds the preset range. Various running states in the CT bulb tube system can be monitored in real time, and when a fault occurs, the bulb tube can be subjected to power-off protection in time, maintenance in time is guaranteed, and irreversible damage to the bulb tube caused by fault running is avoided.
Description
Technical Field
The utility model relates to a radiodiagnosis instrument technical field, concretely relates to intelligence CT bulb system.
Background
Ct (computed tomography), that is, electronic computed tomography, uses a precisely collimated X-ray beam together with a highly sensitive detector to perform cross-sectional scanning one by one around a certain part of a human body, and has the characteristics of fast scanning time, clear image, and the like.
The CT bulb tube is one of the most core components in the CT equipment as an X-ray signal source of the CT equipment, and the performance of the CT bulb tube directly influences the image quality and the service life of the CT equipment. With the technical development of multi-layer spiral CT, continuous scanning is required, the X-ray dosage requirement is higher and higher, and therefore the CT bulb tube is required to have higher heat capacity. The increase in thermal capacity requires the bulb material, and the structure of the rotating anode is constantly improved and enhanced. Small (micro) focus, large capacity, high frequency, high voltage and stability, high-speed rotating anode (low noise), filament emission consistency and the like become the development directions of the bulb tube.
The CT bulb tube has various problems of multiple failure reasons, easy failure, poor self-protection capability, unpredictable service life and the like. Present CT bulb product does not possess the monitoring capability of various real-time running state, and the product intelligent degree is very low, can not master the operational aspect of each part in the CT bulb in real time, leads to can only know after the CT bulb breaks down, in case break down not only has great economic loss, can influence patient's treatment owing to longer machine-halt maintenance duration moreover.
SUMMERY OF THE UTILITY MODEL
Therefore, the to-be-solved technical problem of the utility model lies in overcoming the monitoring capability that the CT bulb product among the prior art does not possess various real-time running state, the very low defect of product intelligent degree to a CT bulb system that can carry out real-time supervision to each running state is provided.
In order to solve the technical problem, the utility model provides a pair of intelligence CT bulb system, include: a bulb body; the monitoring assembly is arranged on the bulb tube body and used for monitoring the running state of the bulb tube system in real time; and the control platform is connected with the monitoring assembly and used for recording data measured by the monitoring assembly, judging whether the data is in a preset range or not, and judging that a fault occurs when the data exceeds the preset range.
Preferably, the monitoring assembly comprises a temperature sensor assembly, and the temperature sensor assembly is connected with the control platform and used for monitoring the thermal state of the running of the bulb tube body.
Preferably, the bulb body comprises a bulb shell, the bulb shell is provided with a window for transmitting X-rays, and the temperature sensor assembly comprises a window temperature sensor arranged near the window.
Preferably, the ball tube body is internally provided with an anode, the anode comprises a target surface, the target surface is arranged on a rotating shaft, the rotating shaft is perpendicular to the target surface, the target surface rotates by taking the rotating shaft as a shaft, the rotating shaft is provided with a bearing, and the temperature sensor assembly comprises a bearing temperature sensor arranged at the bearing.
Preferably, the method further comprises the following steps: the pipe sleeve is used for installing the ball pipe body in the pipe sleeve; the cooling assembly comprises a radiator arranged outside the pipe sleeve, the radiator is connected with a cooling liquid pipeline, and the cooling liquid pipeline is used for introducing cooling liquid into the pipe sleeve; the temperature sensor assembly further comprises an oil inlet temperature sensor arranged at an inlet of the radiator and an oil outlet temperature sensor arranged at an outlet of the cooling liquid pipeline.
Preferably, the monitoring assembly further comprises a vibration sensor, and the vibration sensor is connected with the control platform and used for monitoring a vibration signal, a noise signal or a rotating speed signal of the bearing.
As a preferable scheme, the vibration sensor further comprises a fixing support for fixing the vibration sensor, the fixing support is arranged on the tube shell of the bulb tube body, a window for transmitting X rays is arranged on the tube shell, and the fixing support avoids the window.
Preferably, the monitoring assembly further comprises a vacuum gauge, and the vacuum gauge is installed in the bulb tube body, connected with the control platform and used for collecting the vacuum degree in the bulb tube body.
Preferably, a cathode and an anode are arranged in the bulb tube body, the anode comprises a target surface, the cathode comprises an emission end, the emission end emits electrons to the target surface, and the installation position of the vacuum gauge avoids the movement path of the electrons.
Preferably, the tube shell of the bulb tube body is provided with a through hole, the vacuum gauge is arranged at the through hole in the tube shell, an electrode of the vacuum gauge is led out through the through hole, and the vacuum gauge is in airtight connection with the tube shell.
Preferably, the vacuum gauge comprises a resistance gauge and an ionization gauge with different measuring ranges, and the measuring range is 105Pa-10-8Pa。
As a preferred scheme, the control platform further comprises an alarm device for judging whether the monitoring data is in a preset range in real time, and giving an alarm prompt if the monitoring data exceeds the preset range.
As a preferred scheme, the bulb tube body is powered by a power supply, the control platform is connected with the power supply, and if the control platform judges that a fault occurs, the power supply is controlled to be powered off.
Preferably, the control platform comprises a wireless data transmission module, and is used for transmitting the data collected by the monitoring component to a cloud server and receiving an instruction sent by the cloud server.
The utility model discloses technical scheme has following advantage:
1. the utility model provides an intelligence CT bulb system, include: a bulb body; the monitoring assembly is arranged on the bulb tube body and used for monitoring the running state of the bulb tube system in real time; the control platform is connected with the monitoring assembly and used for recording data measured by the monitoring assembly, judging whether the data is in a preset range or not, and judging that a fault occurs when the data exceeds the preset range; the utility model provides a possess the intelligent CT bulb system of various running states in the real-time supervision bulb, overcome prior art product intelligent degree very low, can't carry out the defect monitored to each real-time running state of bulb.
2. The utility model provides an intelligent CT bulb tube system, the monitoring component comprises a temperature sensor component, which is connected with the control platform and is used for monitoring the thermal state of the running bulb tube body; because overload heat is concentrated or heat dissipation can not be in time to lead to the bulb to break down, temperature sensor can in time accurately judge the excessive temperature fault mode that probably appears in the bulb.
3. The utility model provides an intelligence CT bulb system is equipped with the window that sees through X ray on the tube of bulb body, and the temperature sensor subassembly is including installing near window temperature sensor of window because the produced a large amount of heats of bulb scattered electron and X ray energy loss all gather window department, window temperature sensor carry out real-time supervision to the window, avoid the window heat dissipation not in time to cause the window to break.
4. The utility model provides an intelligent CT bulb tube system, the anode is arranged in the bulb tube body, the target surface of the anode is vertically arranged on the rotating shaft, the target surface rotates by taking the rotating shaft as the shaft, the bearing is arranged on the rotating shaft, and the temperature sensor component comprises a bearing temperature sensor arranged at the bearing; the bearing is overheated to influence its life-span, can lead to the bearing even, and direct card is dead, and bearing temperature sensor carries out real-time supervision to the special oil cooling pipeline of bearing, avoids oil cooling pipeline trouble makes the bearing department overheated and causes the bearing inefficacy.
5. The utility model provides an intelligence CT bulb system still includes: the ball tube body is arranged in the tube sleeve; the cooling assembly comprises a radiator arranged outside the pipe sleeve, the radiator is connected with a cooling liquid pipeline, and the cooling liquid pipeline leads cooling liquid into the pipe sleeve; the temperature sensor also comprises an oil inlet temperature sensor arranged at the inlet of the radiator and an oil outlet temperature sensor arranged at the outlet of the cooling liquid pipeline; the running state of the radiator is monitored in real time through the oil inlet temperature sensor and the oil outlet temperature sensor, and the influence on the normal work of the bulb tube caused by sudden failure of the radiator is avoided.
6. The utility model provides an intelligence CT bulb tube system, monitoring subassembly still include vibration sensor, vibration sensor is connected with control platform, is used for the monitoring vibration signal, noise signal or the rotational speed signal of bearing avoid bearing stall or rotational speed to use the exposure under the condition of crossing low still, lead to the positive pole target surface to melt the evaporation in the twinkling of an eye to lead to more the causing trouble of bulb tube appearance, take place to burst even.
7. The utility model provides an intelligence CT bulb pipe system still includes the fixed bolster of fixed vibration sensor, locates on the tube of bulb body, and avoids being equipped with the window department that sees through X ray on the tube, avoids influencing X ray's normal exposure.
8. The utility model provides an intelligence CT bulb system, monitoring subassembly still include the vacuum gauge, and the vacuum gauge is installed in the bulb originally internally to be connected with control platform, be used for the collection the inside vacuum of bulb body, the dynamic change of the inside vacuum of real-time supervision bulb have overcome the problem of the unable real-time detection CT bulb inside vacuum state among the prior art.
9. The utility model provides an intelligence CT bulb system, this internal negative pole and the positive pole of being equipped with of bulb, positive pole include the target surface, and the negative pole includes the transmitting terminal, and the transmitting terminal is to target surface transmission electron, the motion route of electron is avoided to the mounted position of vacuum gauge, avoids influencing bulb focus size and shape position.
10. The utility model provides an intelligence CT bulb pipe system, the tube of bulb body are equipped with the through-hole, and the vacuum gage is located through-hole department in the tube, the electrode of vacuum gage is drawn through the through-hole, and the vacuum gage carries out airtight connection with the tube, because CT bulb inside need keep absolute airtight, arranges like this and to make airtight vacuum system and external can pass through electrode transmission signal.
11. The utility model provides an intelligence CT bulb system, vacuum gauge include resistance gauge and ionization gauge that the range is different, and measuring range is 105Pa-10-8Pa covers all the possible vacuum degree ranges in the bulb, thereby being beneficial to mastering various fault conditions of the related vacuum degree.
12. The utility model provides an intelligence CT bulb tube system, control platform still include alarm device for judge in real time whether monitoring data is in the scope of predetermineeing, if surpass the scope of predetermineeing and then make the suggestion of reporting to the police, avoid equipment or user because the proruption trouble that vacuum descends to produce brings irreversible loss in the bulb.
13. The utility model provides an intelligence CT bulb system, bulb body pass through mains operated, and control platform is connected with the power, if control platform judges when breaking down, then controls the power outage to in time power-off protection is carried out to the bulb, and can in time maintain, avoid the trouble operation to cause irreversible damage to the bulb.
14. The utility model provides an intelligence CT bulb pipe system, control platform include wireless data transmission module for data transmission to the high in the clouds server with monitoring assembly collection, and the instruction that receives the high in the clouds server and send, if data transmission breaks down, need maintain data transmission module, can find out the reason fast, and recovery circuit normal operating makes the plant maintenance realize more easily. Whether the running state of the bulb tube is normal or not is judged through the collection of monitoring data and the analysis of a failure model, early warning is carried out on possible faults, effective self-protection is carried out in time, and the follow-up service life of the bulb tube is predicted according to the analysis and the judgment of the running state. The data acquisition and analysis results have very important values for hospitals, equipment manufacturers and equipment maintenance services, and can bring brand new experience to users.
Drawings
In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the embodiments or the technical solutions in the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.
Fig. 1 is a schematic diagram of the internal structure of the CT bulb system of the present invention.
Description of reference numerals:
1. a heat sink; 2. a vibration sensor; 3. fixing a bracket; 4. a window temperature sensor; 5. a transmitting end; 6. a bulb body; 7. an oil inlet temperature sensor; 8. a bearing temperature sensor; 9. pipe sleeve; 10. a bearing; 11. a rotating shaft; 12 an anode; 13. a window; 14. a pipe shell; 15. a target surface; 16. a vacuum gauge; 17. a through hole; 18. a cathode; 19. an oil outlet temperature sensor; 20. and a coolant pump.
Detailed Description
The technical solution of the present invention will be described clearly and completely with reference to the accompanying drawings, and obviously, the described embodiments are some, but not all embodiments of the present invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.
In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.
In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.
Furthermore, the technical features mentioned in the different embodiments of the invention described below can be combined with each other as long as they do not conflict with each other.
The intelligent CT bulb tube system provided by the embodiment comprises a bulb tube body 6, a monitoring assembly and a control platform.
As shown in fig. 1, the bulb body 6 is enclosed within a sleeve 9; a cathode 18 and an anode 12 are arranged in the bulb tube body 6, a target surface 15 of the anode 12 is vertically arranged on the rotating shaft 11 and rotates by taking the rotating shaft 11 as an axis, an emission end 5 of the cathode 18 emits electrons to the target surface 15, the target surface 15 of the anode 12 receives electron bombardment to generate X rays, and the X rays are exposed from a window 13 arranged on the bulb tube 14; because the high-energy electrons bombard the target surface 15, high heat is generated, the cooling pipeline arranged in the ball tube system feeds cooling liquid into the pipe sleeve 9 to cool the ball tube system, the cooling pipeline is connected with the radiator 1, and the cooling liquid in the pipe sleeve 9 is pumped out through the cooling liquid 20 on the pipeline and enters the radiator 1 for cooling.
The bulb body 6 can cause bulb faults due to overload heat concentration or untimely heat dissipation, such as jamming caused by overheating of the bearing 10, cracking caused by overheating of the window 13 of the X-ray, bulb breakage caused by overheating and the like; in order to effectively and comprehensively monitor the thermal state in the bulb in time, four temperature sensors are added in the bulb system according to different possible thermal failure modes of the bulb, and the four temperature sensors are connected with the control platform and used for monitoring the thermal state of the operation of the bulb body 6, accurately judging the possible over-temperature failure mode in the bulb in time and taking corresponding protective measures.
As shown in fig. 1, a window temperature sensor 4 is installed on the tube shell near the window 13 of the X-ray, and is used for monitoring the cooling pipeline special for the window in real time, so as to avoid window breakage caused by untimely heat dissipation of the window due to sudden failure of the cooling pipeline; a bearing temperature sensor 8 is arranged at a bearing 10 arranged on the rotating shaft 11 and used for monitoring a cooling pipeline special for the bearing in real time, so that the bearing 10 is prevented from being overheated due to faults of the cooling pipeline to cause failure of the bearing 10; an oil inlet temperature sensor 7 is installed on a cooling pipeline at the inlet of the radiator 1, an oil outlet temperature sensor 19 is installed at the outlet of a cooling liquid pipeline, the running state of the radiator is monitored in real time through the oil inlet temperature sensor 7 and the oil outlet temperature sensor 19, and the phenomenon that the normal work of a bulb tube is influenced due to sudden failure of the radiator is avoided.
In the process of bulb tube working, the working conditions of the bearing 10 are very harsh, and the temperature reaches about 400 ℃; the bearing 10 can be grasped in time in the process of working, the wear, the speed drop, the sudden stop and other faults can be avoided, and the danger caused by instant melting and evaporation of the target surface 15 of the anode 12 and even the burst of the bulb tube in serious conditions caused by the exposure when the faults occur can be avoided.
As shown in fig. 1, the vibration sensor 2 is mounted at the tube shell 14 through the fixed bracket 3 and avoids the window 13 of the X-ray so as not to affect the normal exposure of the X-ray; meanwhile, the vibration sensor 2 is connected with the control platform, and the running state of the bearing 10, namely a vibration signal, a noise signal or a rotating speed signal of the bearing 10 is directly reflected through the analysis of a vibration frequency spectrum in a time domain and a frequency domain; wherein the vibration amplitude is an important parameter for identifying abnormal vibration of the bearing. With frequency-based analysis, the time-domain vibration signal can be converted into frequency components by fourier transform (FFT), which is a typical spectrogram of CT tube operation. The typical dominant frequency is 50Hz, with corresponding harmonic components. When the rotating speed of the ball tube bearing is reduced or the bearing works abnormally, main frequency spectral lines on a frequency spectrogram shift or stray frequency spectrums appear.
The whole process of X-ray generation depends on the high vacuum degree environment in the bulb tube, and the damage of the vacuum degree causes the service life of the filament to be reduced and even the filament to be blown, so that the bulb tube is invalid to bring irreversible loss to users, and the real-time monitoring of the vacuum degree is particularly important.
As shown in fig. 1, the vacuum gauge 16 is arranged at a through hole 17 in the tube shell 14, an electrode of the vacuum gauge 16 is led out through the through hole 17, the vacuum gauge 16 is in airtight connection with the tube shell 14, so that a vacuum system and the outside can transmit signals through the electrode, wherein the installation position of the vacuum gauge 16 avoids a movement path of electrons emitted by the cathode 18, and the size and the shape position of a focus of the bulb tube are prevented from being influenced; in addition, the vacuum gauge 16 is connected with an alarm device and used for judging whether the vacuum degree signal is in a preset range in real time, and giving an alarm prompt if the vacuum degree signal exceeds the preset range.
The vacuum gauge 16 integrates two gauges of resistance gauge and ionization gauge, wherein a resistance wire is supported between two electrodes of the resistance gauge, and the measuring range of the resistance gauge is 105Pa-10-1Pa; the ionization gauge adopts a B-A gauge structure and is provided with three electrodes of a cathode, a collector and a grid, and the measuring range is 10-1Pa~10-8Pa, the filaments are arranged at two sides of the grid and symmetrically installed, and work one by oneFor use. Thus the vacuum gauge can monitor the bulb from 105Pa~ 10-8Pa the whole range of possible vacuum degrees.
In the process of monitoring the vacuum degree by the vacuum gauge 16, the resistance gauge is always in a working state, the ionization gauge is in a closed state during X-ray exposure, and the ionization gauge is only opened in an X-ray exposure gap, so that the influence of the strong energy of X-rays on the weak ion flow measured by the ionization gauge is avoided, and the measurement accuracy of the ionization gauge is ensured.
Data collected by the window temperature sensor 4, the bearing temperature sensor 8, the oil inlet temperature sensor 7, the oil outlet temperature sensor 19, the vibration sensor 2 and the vacuum gauge 16 are all transmitted to the main control module, the main control module analyzes the data, and whether faults occur is judged according to alarm data set values corresponding to various fault modes. If the bulb tube is judged to have a fault, the protection module is controlled to control a protection signal for the power supply, and the power supply is timely operated (such as filament cutting, high-voltage power supply cutting and the like) to protect the bulb tube. All the collected data information and the early warning signals display the real-time running state of the bulb tube through the display terminal. The data are transmitted to an internet cloud server through a wireless data transmission module.
As an alternative embodiment, the rotation speed of the bearing 10 may be directly measured by a photoelectric sensor, and this monitoring may also reflect to some extent whether the bearing is working normally; it is also possible to use a bearing noise sensor to indirectly measure the condition of the bearing 10.
As an alternative embodiment, the gauge combined with the ionization gauge is not limited to a resistance gauge only, and the measurement range of the gauge satisfies 105Pa-10-1Pa is needed.
As an alternative embodiment, regarding the wireless transmission mode of the collected signal, only the wireless transmission module is described, but a specific technical path may adopt Wifi, bluetooth, Zigbee and other forms.
It should be understood that the above examples are only for clarity of illustration and are not intended to limit the embodiments. Other variations and modifications will be apparent to persons skilled in the art in light of the above description. And are neither required nor exhaustive of all embodiments. And obvious variations or modifications can be made without departing from the scope of the invention.
Claims (14)
1. An intelligent CT bulb system, comprising:
a bulb body (6);
the monitoring assembly is arranged on the bulb tube body (6) and used for monitoring the running state of the bulb tube system in real time;
and the control platform is connected with the monitoring assembly and used for recording data measured by the monitoring assembly, judging whether the data is in a preset range or not, and judging that a fault occurs when the data exceeds the preset range.
2. The intelligent CT bulb system of claim 1, wherein the monitoring assembly comprises a temperature sensor assembly connected with the control platform for monitoring a thermal state of the bulb body (6) operation.
3. An intelligent CT bulb system according to claim 2, wherein the bulb body (6) comprises a tube shell (14), the tube shell (14) is provided with a window (13) for transmitting X-rays, and the temperature sensor assembly comprises a window temperature sensor (4) mounted near the window (13).
4. The intelligent CT bulb system as claimed in claim 2, wherein an anode (12) is arranged in the bulb body (6), the anode comprises a target surface (15), the target surface (15) is arranged on a rotating shaft (11), the rotating shaft (11) is perpendicular to the target surface (15), the target surface rotates around the rotating shaft (11), a bearing (10) is arranged on the rotating shaft (11), and the temperature sensor assembly comprises a bearing temperature sensor (8) arranged at the bearing (10).
5. The intelligent CT bulb system of claim 2, further comprising:
the pipe sleeve (9), the bulb body (6) is installed in the pipe sleeve (9);
the cooling assembly comprises a radiator (1) arranged outside the pipe sleeve (9), the radiator (1) is connected with a cooling liquid pipeline, and the cooling liquid pipeline is used for introducing cooling liquid into the pipe sleeve (9);
the temperature sensor assembly further comprises an oil inlet temperature sensor (7) arranged at an inlet of the radiator (1) and an oil outlet temperature sensor (19) arranged at an outlet of the cooling liquid pipeline.
6. The intelligent CT bulb system of claim 4, characterized in that the monitoring assembly further comprises a vibration sensor (2), the vibration sensor (2) being connected with the control platform for monitoring a vibration signal, a noise signal or a rotational speed signal of the bearing (10).
7. The intelligent CT bulb tube system as claimed in claim 6, further comprising a fixing bracket (3) for fixing the vibration sensor (2), wherein the fixing bracket is arranged on a tube shell (14) of the bulb tube body (6), the tube shell (14) is provided with a window (13) for transmitting X-rays, and the fixing bracket (3) is arranged to avoid the window (13).
8. The intelligent CT bulb system as recited in any one of claims 1-5, characterized in that the monitoring assembly further comprises a vacuum gauge (16), the vacuum gauge (16) is mounted within the bulb body (6) and connected with the control platform for acquiring the vacuum degree inside the bulb body (6).
9. The intelligent CT bulb system as recited in claim 8, wherein a cathode (18) and an anode (12) are arranged in the bulb body (6), the anode (12) comprises a target surface (15), the cathode (18) comprises an emission end (5), the emission end (5) emits electrons to the target surface (15), and the installation position of the vacuum gauge (16) avoids the movement path of the electrons.
10. The intelligent CT bulb system as claimed in claim 9, wherein a tube shell (14) of the bulb body (6) is provided with a through hole (17), the vacuum gauge (16) is arranged at the through hole (17) in the tube shell, an electrode of the vacuum gauge (16) is led out through the through hole (17), and the vacuum gauge (16) is in airtight connection with the tube shell (14).
11. The smart CT bulb system of claim 9, wherein the vacuum gauge (16) includes a resistance gauge and an ionization gauge having different ranges, and the measurement range is 105Pa-10-8Pa。
12. The intelligent CT bulb tube system of claim 1, wherein the control platform further comprises an alarm device for judging whether the monitoring data is within a preset range in real time, and giving an alarm prompt if the monitoring data is beyond the preset range.
13. The intelligent CT bulb tube system as claimed in claim 1, wherein the bulb tube body (6) is powered by a power supply, the control platform is connected with the power supply, and if the control platform judges that a fault occurs, the power supply is controlled to be powered off.
14. The intelligent CT bulb system of claim 1, wherein the control platform comprises a wireless data transmission module configured to transmit data collected by the monitoring component to a cloud server and receive commands from the cloud server.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201920875503.1U CN210727766U (en) | 2019-06-11 | 2019-06-11 | Intelligent CT bulb tube system |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201920875503.1U CN210727766U (en) | 2019-06-11 | 2019-06-11 | Intelligent CT bulb tube system |
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| Publication Number | Publication Date |
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| CN210727766U true CN210727766U (en) | 2020-06-12 |
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| CN201920875503.1U Active CN210727766U (en) | 2019-06-11 | 2019-06-11 | Intelligent CT bulb tube system |
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| Country | Link |
|---|---|
| CN (1) | CN210727766U (en) |
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2019
- 2019-06-11 CN CN201920875503.1U patent/CN210727766U/en active Active
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