CN117989439B - Real-time monitoring device for clinical test data - Google Patents

Abstract

The invention discloses a real-time monitoring device for clinical test data in the field of equipment bases, which comprises an adjusting component, a supporting rod, monitoring equipment, a locking component and the like. When the angle and the height of the monitoring equipment need to be adjusted, the adjusting rod is pulled or pushed to enable the auxiliary bevel gear to be meshed with the first bevel gear or enable the transmission bevel gear to be meshed with the second bevel gear, the adjusting rod is rotated in the forward direction or the reverse direction, the monitoring equipment is driven to rotate in the forward direction or the reverse direction, or the monitoring equipment is driven to move upwards or downwards. When the auxiliary bevel gear is meshed with the first bevel gear, the limiting block is positioned at one limiting cavity, and when the transmission bevel gear is meshed with the second bevel gear, the limiting block is positioned at the other limiting cavity. The limiting block rotates simultaneously when the adjusting rod rotates, the limiting block rotates to throw out the clamping block, the clamping block is always located in the limiting cavity when being thrown out, and the position of the limiting block is limited by the clamping block. From this high-efficient convenient regulation to monitoring devices guarantees the accuracy of clinical real-time monitoring test data to a certain extent.

Description

Real-time monitoring device for clinical test data

Technical Field

The invention belongs to the field of equipment bases, and particularly relates to a real-time monitoring device for clinical test data.

Background

With the continuous development and progress of medical technology, clinical trials have played an increasingly important role in drug development, therapeutic methods, disease research, and the like. The quality and reliability of clinical trial data is critical to the accuracy and reliability of the trial results. In order to ensure the accuracy and reliability of clinical trial data, real-time monitoring of the clinical trial data is required.

In some experiments requiring long-term monitoring, however, the monitoring device may need to frequently adjust its position to maintain accuracy and real-time of the data. In addition, because factors such as the height and sitting posture of test participants also influence the accuracy of data, the monitoring equipment capable of conveniently and efficiently adjusting the height and the angle is particularly important.

When the device for adjusting the monitoring device is conventionally used, the device can be rotationally adjusted, and the monitoring device can be subjected to multi-gear adjustment so as to quickly reach the state required by a user, but when the rotation state is switched, the device is easy to generate displacement and gear shifting phenomena, so that researchers need to spend extra time and effort to recalibrate and adjust the device so as to ensure the accuracy of data, and the efficiency of clinical tests can be reduced. If the equipment is displaced or shifted in the adjusting process, the monitoring device is difficult to adjust to a proper position, and deviation of monitoring data is caused, so that accuracy of a test result is affected. Therefore, the scheme provides a real-time monitoring device for clinical test data.

Disclosure of Invention

In order to solve the problems, the invention provides a real-time monitoring device for clinical test data, which is used for efficiently and conveniently adjusting the monitoring device and ensuring the accuracy of the clinical real-time monitoring test data to a certain extent.

In order to achieve the above object, the technical scheme of the present invention is as follows: the real-time monitoring device for the clinical test data comprises an adjusting component, a supporting rod and monitoring equipment, wherein the supporting rod is arranged on the adjusting component, and the monitoring equipment is fixedly connected to the top of the supporting rod;

The middle part of the supporting rod is sleeved with a fixed gear; the adjusting assembly comprises a box body and an adjusting rod, wherein the adjusting rod is connected with a locking assembly, the supporting rod vertically penetrates through the top of the box body and is in sliding fit with the box body, the adjusting rod transversely penetrates through one side of the box body and is in sliding fit with the box body, the bottom of the supporting rod is connected with a transmission assembly, one side of a fixed gear is connected with a rotating assembly, the adjusting rod is fixedly connected with a moving assembly, the moving assembly can be respectively connected with the transmission assembly and the rotating assembly when the adjusting rod moves, the height of the supporting rod can be adjusted by rotating the adjusting rod when the moving assembly is connected with the transmission assembly, and the angle of the supporting rod can be adjusted by rotating the adjusting rod when the moving assembly is connected with the rotating assembly.

The principle and the beneficial effect of the scheme are adopted: when the device is used, the monitoring device is used for carrying out real-time monitoring on clinical test data, when the angle and the height of the monitoring device need to be adjusted, the adjusting rod is pulled or pushed, the moving assembly can be connected with the transmission assembly or the rotating assembly, when the moving assembly is connected with the transmission assembly, the rotating adjusting rod can adjust the height of the supporting rod, and when the moving assembly is connected with the rotating assembly, the rotating adjusting rod can adjust the angle of the supporting rod. Thereby adjusting at the same position, the direction and the height of the monitoring device can be adjusted at the same time. Meanwhile, the height and the angle of the monitoring equipment can be quickly and accurately adjusted through the adjusting rod, the tedious process of repeated adjustment in the traditional mode is avoided, and the accuracy of clinical real-time monitoring test data is guaranteed to a certain extent.

Further, the transmission assembly comprises an auxiliary rod rotationally connected with the bottom of the supporting rod; the rotating assembly comprises a bracket fixedly connected with the inner wall of the box body, a first rotating shaft is rotatably connected to the bracket, a main gear is coaxially and fixedly connected to the first rotating shaft, a slave gear is meshed with the main gear, the slave gear is meshed with the fixed gear, and a first bevel gear is coaxially and fixedly connected to one side of the main gear;

The support is rotationally connected with a disc, a connecting rod is fixedly connected to the disc, one end, away from the disc, of the connecting rod is rotationally connected with the bottom of the auxiliary rod, and a second bevel gear is coaxially and fixedly connected to the disc; the moving assembly comprises an auxiliary bevel gear and a transmission bevel gear which are coaxially and fixedly connected with the adjusting rod, the auxiliary bevel gear can be meshed with the first bevel gear, and the transmission bevel gear can be meshed with the second bevel gear;

One side in the box body is fixedly connected with an auxiliary block, an adjusting rod penetrates through the auxiliary block and is in sliding fit with the auxiliary block, an auxiliary chamber is arranged in the auxiliary block, a limiting block is fixedly connected to the adjusting rod, a limiting component is arranged on the limiting block and used for throwing out a clamping block when the limiting block rotates, the limiting block is positioned in the auxiliary chamber and is in sliding fit with the side wall of the auxiliary chamber, and the auxiliary chamber is communicated with two limiting chambers;

the limiting assembly comprises a plurality of rotating rods and clamping blocks, a plurality of grooves are formed in the limiting block, the clamping blocks are fixedly connected to one ends of the rotating rods respectively, one ends of the rotating rods, which are far away from the clamping blocks, are rotationally connected to the grooves, tension springs are fixedly connected to one sides of the clamping blocks, and one ends of the tension springs, which are far away from the clamping blocks, are fixedly connected to the grooves.

The beneficial effects are that: when the auxiliary bevel gear is meshed with the first bevel gear, the limiting block is positioned at one limiting cavity, and when the transmission bevel gear is meshed with the second bevel gear, the limiting block is positioned at the other limiting cavity. When the adjusting rod rotates, the limiting blocks rotate simultaneously, the limiting blocks are thrown out when the limiting blocks rotate, the limiting blocks are always located in the limiting cavities when being thrown out, and the positions of the limiting blocks are limited by the aid of the limiting blocks. The phenomenon that the device is difficult to displace and shift when the limiting block and the adjusting rod rotate is avoided, and the phenomenon that the device is difficult to displace and shift when the rotating state is switched is avoided, so that researchers are required to spend extra time and energy to recalibrate and adjust the device, and the accuracy of data is ensured. From this high-efficient convenient regulation to monitoring devices guarantees the accuracy of clinical real-time monitoring test data to a certain extent.

Further, the bottom of the box body is fixedly connected with a support, and the bottom of the support is in a truncated cone shape.

The beneficial effects are that: the round table-shaped support bottom can be better suitable for uneven ground or test tables, stability of equipment is improved, and equipment is prevented from tilting or toppling in the use process. The bottom of the truncated cone-shaped support can be suitable for test tables or floors with different shapes and sizes, and the application range of the equipment is enlarged.

Further, be connected with drive assembly on adjusting the pole, drive assembly is connected with the gas-supply subassembly, and the support bottom is the fretwork state, and the gas-supply subassembly is used for absorbing the gas of support bottom and carries to the monitoring facilities bottom when adjusting the pole and rotate.

The beneficial effects are that: the design that support bottom is the fretwork state can adapt to test bench or the ground of different shapes and sizes better, increases stability and the adaptability of equipment. The gas transmission assembly is used for absorbing gas at the bottom of the support and conveying the gas to the bottom of the monitoring equipment when the adjusting rod rotates, so that the bottom of the support forms a negative pressure state when absorbing the gas at the bottom of the support, and the hollowed-out position of the support is in a vacuum state, so that the support is more attached to the ground or the test bed. When gas is conveyed to the bottom of the monitoring equipment, the monitoring equipment can be cooled, and stable operation of the monitoring equipment is ensured to a certain extent.

Further, the transmission assembly comprises a first gear and a second gear, the first gear is coaxially and fixedly connected to the adjusting rod, the second gear is meshed with the first gear, the second gear is rotatably connected to the support, and the gas transmission assembly is connected with the second gear.

The beneficial effects are that: through using two gears to carry out the transmission, can more high-efficient transfer the rotary motion of adjusting the pole to the gas-supply subassembly on, improve transmission's efficiency and response speed.

Further, the gas transmission assembly comprises a crank, a connecting rod, a sliding block and a gas cylinder, wherein the crank is rotationally connected to one side of the second gear, the crank is hinged to the connecting rod, one end of the connecting rod, which is far away from the crank, is rotationally connected with the sliding block, the sliding block is positioned in the gas cylinder and is in sliding fit with the gas cylinder, the gas cylinder is fixedly connected in the box, one side of the gas cylinder, which is far away from the connecting rod, is provided with a gas inlet and a gas outlet, the gas inlet is communicated with a gas inlet pipe, the gas outlet is communicated with a gas outlet pipe, the gas inlet pipe is communicated with a gas inlet one-way valve, the gas outlet pipe is communicated with the hollowed-out part of the support, one end of the gas cylinder is far away from the gas inlet pipe, and one end of the gas cylinder is fixedly connected below the monitoring equipment.

The beneficial effects are that: through the design of the air inlet check valve and the air outlet check valve, the flow and the direction of the inlet air and the outlet air can be accurately controlled, and the stability and the accuracy in the adjusting process are ensured.

Further, the bottom of the support is fixedly connected with a rubber layer.

The beneficial effects are that: the rubber layer can increase the friction force at the bottom of the support, prevent the equipment from sliding or toppling over in the use process, and increase the stability of the equipment.

Further, one end of the adjusting rod positioned outside the box body is fixedly connected with a fixing rod, one end of the fixing rod is rotationally connected with a handle, and anti-skid patterns are arranged on the handle.

The beneficial effects are that: through the design of dead lever and handle, operating personnel can more easily adjust dead lever's position and angle, improves convenience and the efficiency of regulation.

Further, the locking assembly comprises a locking rod and a plurality of bayonets, the locking rod is connected to the fixing rod in a sliding mode, the bayonets are located on one side, close to the fixing rod, of the box body, and the bayonets are circumferentially arranged along the adjusting rod.

The beneficial effects are that: through the design of the locking assembly, the stability of the fixing rod can be further enhanced, and the phenomenon of sliding or shifting in the adjusting process is avoided. The bayonet is designed to prevent the position of the fixing rod from moving due to misoperation in the adjusting process, so that the safety and stability of operation are improved.

Drawings

Fig. 1 is a schematic diagram of a real-time monitoring device for clinical test data according to an embodiment of the present invention.

Fig. 2 is a cross-sectional view of a real-time clinical trial data monitoring device according to an embodiment of the present invention.

Fig. 3 is a side view of a gas delivery assembly according to an embodiment of the present invention.

Fig. 4 is a cross-sectional view of an auxiliary block according to an embodiment of the present invention.

Detailed Description

The following is a further detailed description of the embodiments:

Reference numerals in the drawings of the specification include: the device comprises an adjusting component 1, a supporting rod 2, a monitoring device 3, a fixed gear 4, a box 5, an adjusting rod 6, an auxiliary rod 7, a bracket 8, a first rotating shaft 9, a main gear 10, a driven gear 11, a first bevel gear 12, a disc 13, a connecting rod 14, a second bevel gear 15, an auxiliary bevel gear 16, a transmission bevel gear 17, an auxiliary block 18, an auxiliary chamber 19, a limiting block 20, a limiting component 21, a clamping block 22, a limiting chamber 23, a rotating rod 24, a groove 25, a tension spring 26, a support 27, a rubber layer 28, a transmission component 29, an air delivery component 30, a first gear 31, a second gear 32, a crank, a connecting rod 34, a sliding block 35, an air cylinder 36, an air inlet 37, an air outlet 38, an air inlet pipe 39, an air outlet pipe 40, an air inlet check valve 41, an air outlet check valve 42, a fixed rod 43, a handle 44, an anti-skid pattern 45, a clamping rod 46 and a bayonet 47.

Example 1

An example is substantially as shown in figures 1,2, 3 and 4:

The utility model provides a clinical trial data real-time supervision device, includes adjusting part 1, bracing piece 2 and monitoring facilities 3, and bracing piece 2 sets up on adjusting part 1, and monitoring facilities 3 fixed connection is in bracing piece 2 top. The middle part of the supporting rod 2 is sleeved with a fixed gear 4; the adjusting assembly 1 comprises a box body 5 and an adjusting rod 6, a locking assembly is connected to the adjusting rod 6, the supporting rod 2 vertically penetrates through the top of the box body 5 and is in sliding fit with the box body 5, the adjusting rod 6 transversely penetrates through one side of the box body 5 and is in sliding fit with the box body 5, a transmission assembly 29 is connected to the bottom of the supporting rod 2, a rotating assembly is connected to one side of the fixed gear 4, a moving assembly is fixedly connected to the adjusting rod 6, the moving assembly can be connected with the transmission assembly 29 and the rotating assembly respectively when the adjusting rod 6 moves, the height of the supporting rod 2 can be adjusted by rotating the adjusting rod 6 when the moving assembly is connected with the transmission assembly 29, and the angle of the supporting rod 2 can be adjusted by rotating the adjusting rod 6 when the moving assembly is connected with the rotating assembly.

The transmission assembly 29 comprises an auxiliary rod 7 rotatably connected with the bottom of the support rod 2; the rotating assembly comprises a bracket 8 fixedly connected with the inner wall of the box body 5, a first rotating shaft 9 is rotatably connected to the bracket 8, a main gear 10 is coaxially and fixedly connected to the first rotating shaft 9, a slave gear 11 is meshed with the main gear 10, the slave gear 11 is meshed with the fixed gear 4, and a first bevel gear 12 is coaxially and fixedly connected to one side of the main gear 10.

The support 8 is rotationally connected with a disc 13, the disc 13 is fixedly connected with a connecting rod 14, one end of the connecting rod 14 away from the disc 13 is rotationally connected with the bottom of the auxiliary rod 7, and the disc 13 is coaxially and fixedly connected with a second bevel gear 15; the moving assembly comprises an auxiliary bevel gear 16 and a transmission bevel gear 17 which are fixedly connected with the adjusting rod 6 coaxially, wherein the auxiliary bevel gear 16 can be meshed with the first bevel gear 12, and the transmission bevel gear 17 can be meshed with the second bevel gear 15.

One side fixedly connected with auxiliary block 18 in the box 5 adjusts pole 6 run through auxiliary block 18 and with auxiliary block 18 sliding fit, is equipped with auxiliary chamber 19 in the auxiliary block 18, adjusts pole 6 on fixedly connected with stopper 20, is equipped with spacing subassembly 21 on the stopper 20, and spacing subassembly 21 is used for throwing away fixture block 22 when stopper 20 rotates, and stopper 20 is located auxiliary chamber 19 and with auxiliary chamber 19 lateral wall sliding fit, auxiliary chamber 19 intercommunication has two spacing chambers 23.

The limiting assembly 21 comprises a plurality of rotating rods 24 and clamping blocks 22, a plurality of grooves 25 are formed in the limiting block 20, the clamping blocks 22 are fixedly connected to one ends of the rotating rods 24 respectively, one ends of the rotating rods 24, which are far away from the clamping blocks 22, are rotatably connected into the grooves 25, tension springs 26 are fixedly connected to one sides of the clamping blocks 22, and one ends, which are far away from the clamping blocks 22, of the tension springs 26 are fixedly connected into the grooves 25.

The specific implementation process is as follows: when the device is used, the monitoring device 3 is used for monitoring clinical test data in real time. When the angle of the monitoring device 3 needs to be adjusted, the adjusting rod 6 is pulled leftwards, the auxiliary bevel gear 16 is meshed with the first bevel gear 12, at the moment, the adjusting rod 6 is rotated forwards or reversely, the adjusting rod 6 is rotated to drive the auxiliary bevel gear 16 to rotate, the auxiliary bevel gear 16 is rotated to drive the first bevel gear 12 to rotate, the first bevel gear 12 is rotated to drive the main gear 10 to rotate on the first rotating shaft 9, the main gear 10 is rotated to drive the auxiliary gear 11 to rotate, the auxiliary gear 11 is rotated to drive the fixed gear 4 to rotate, and accordingly the supporting rod 2 is driven to rotate leftwards or rightwards, and the angle of the monitoring device 3 is adjusted.

When the height of the monitoring device 3 needs to be adjusted, the adjusting rod 6 is pushed rightward to enable the transmission bevel gear 17 to be meshed with the second bevel gear 15, the auxiliary bevel gear 16 is separated from the first bevel gear 12 to be meshed, at the moment, the adjusting rod 6 is rotated in the forward direction or the reverse direction, the transmission bevel gear 17 is driven to rotate by the rotation of the adjusting rod 6, the second bevel gear 15 is driven to rotate by the rotation of the transmission bevel gear 17, the disc 13 is driven to rotate by the rotation of the second bevel gear 15, the connecting rod 14 is driven to rotate by the rotation of the disc 13, and the auxiliary rod 7 is pushed upward or pulled downward by the connecting rod 14 when the connecting rod 14 rotates, so that the adjusting rod 6 moves upward or moves downward, and the height of the monitoring device 3 is adjusted. After the height and angle of the monitoring device 3 are adjusted, the adjusting rod 6 is fixed by using a locking assembly.

When the auxiliary bevel gear 16 is completely meshed with the first bevel gear 12 and the transmission bevel gear 17 is completely meshed with the second bevel gear 15, the limiting blocks 20 are respectively located in the two limiting chambers 23, the rotation of the adjusting rod 6 drives the auxiliary block 18 to rotate at the moment, the clamping blocks 22 are thrown out due to centrifugal effect when the auxiliary block 18 rotates, the thrown clamping blocks 22 are located in the limiting chambers 23, the limiting chambers 23 limit the clamping blocks 22, and the displacement of the adjusting rod 6 at the moment is avoided. When the adjusting lever 6 stops rotating, the tension spring 26 pulls the rotating lever 24 and the clamping block 22 back into the groove 25 due to the action of the tension spring 26, and the limiting chamber 23 does not limit the rotating lever, so that the auxiliary block 18 can move in the auxiliary chamber 19.

Example two

The difference between this embodiment and the above embodiment is that: the bottom of the box body 5 is fixedly connected with a support 27, and the bottom of the support 27 is in a truncated cone shape. The bottom of the support 27 is fixedly connected with a rubber layer 28. The adjusting rod 6 is connected with a transmission assembly 29, the transmission assembly 29 is connected with a gas transmission assembly 30, the bottom of the support 27 is in a hollowed-out state, and the gas transmission assembly 30 is used for absorbing gas at the bottom of the support 27 and transmitting the gas to the bottom of the monitoring device 3 when the adjusting rod 6 rotates. The transmission assembly 29 comprises a first gear 31 and a second gear 32, the first gear 31 is coaxially and fixedly connected to the adjusting rod 6, the second gear 32 is meshed with the first gear 31, the second gear 32 is rotatably connected to the bracket 8, and the gas transmission assembly 30 is connected with the second gear 32.

The gas transmission assembly 30 comprises a crank 33, a connecting rod 34, a sliding block 35 and a gas cylinder 36, wherein the crank 33 is rotationally connected to one side of the second gear 32, the crank 33 is hinged to the connecting rod 34, one end of the connecting rod 34, far away from the crank 33, is rotationally connected with the sliding block 35, the sliding block 35 is positioned in the gas cylinder 36 and is in sliding fit with the gas cylinder 36, the gas cylinder 36 is fixedly connected in the box 5, one side of the gas cylinder 36, far away from the connecting rod 34, is provided with a gas inlet 37 and a gas outlet 38, the gas inlet 37 is communicated with a gas inlet pipe 39, the gas outlet 38 is communicated with a gas outlet pipe 40, the gas inlet 39 is communicated with a gas inlet one-way valve 41, the gas outlet pipe 40 is communicated with a gas outlet one-way valve 42, one end of the gas inlet pipe 39, far away from the gas cylinder 36, is fixedly connected to the lower part of the monitoring equipment 3.

The specific implementation process is as follows: the support 27 at the bottom of the box body 5 is used for supporting the box body 5, when the adjusting rod 6 rotates, the first gear 31 is driven to rotate, the first gear 31 rotates to drive the second gear 32 to rotate, the crank 33 is pulled to rotate around the second gear 32 when the second gear 32 rotates, the connecting rod 34 is pulled to move back and forth, and the sliding block 35 is pulled or pushed when the connecting rod 34 moves back and forth, so that the sliding block 35 moves left and right in the air cylinder 36.

When the slide block 35 moves to the side close to the connecting rod 34, the other side of the air cylinder 36 sucks the air at the bottom of the support 27 into the air cylinder 36 through the air inlet 37, the air inlet pipe 39 and the air inlet one-way valve 41, so that the suction force of the support 27 to the ground or the experiment table surface is increased, and the stability of the device is improved. When the slide block 35 moves to one side of the principle connecting rod 34, the other side of the air cylinder 36 outputs the air in the air cylinder 36 to the bottom of the monitoring device 3 through the air outlet 38, the air outlet pipe 40 and the air outlet one-way valve 42, and the bottom of the monitoring device 3 is cooled.

Example III

The difference between this embodiment and the above embodiment is that: one end of the adjusting rod 6 positioned outside the box body 5 is fixedly connected with a fixing rod 43, one end of the fixing rod 43 is rotatably connected with a handle 44, and the handle 44 is provided with anti-skid patterns 45. The locking assembly comprises a locking rod 46 and a plurality of bayonets 47, the locking rod 46 is connected to the fixed rod 43 in a sliding mode, the bayonets 47 are located on one side, close to the fixed rod 43, of the box body 5, and the bayonets 47 are circumferentially arranged along the adjusting rod 6.

The specific implementation process is as follows: the fixing rod 43 is rotated by holding the handle 44, thereby driving the adjusting rod 6 to rotate, and the adjusting rod 6 can be fixed by pushing the locking rod 46 into the bayonet 47.

The foregoing is merely exemplary of the present application and the specific structures and/or characteristics of the present application that are well known in the art have not been described in detail herein. It should be noted that modifications and improvements can be made by those skilled in the art without departing from the structure of the present application, and these should also be considered as the scope of the present application, which does not affect the effect of the implementation of the present application and the utility of the patent. The protection scope of the present application is subject to the content of the claims, and the description of the specific embodiments and the like in the specification can be used for explaining the content of the claims.

Claims (3)

1. The utility model provides a clinical trial data real-time supervision device which characterized in that: the device comprises an adjusting assembly, a supporting rod and monitoring equipment, wherein the supporting rod is arranged on the adjusting assembly, and the monitoring equipment is fixedly connected to the top of the supporting rod;

The middle part of the supporting rod is sleeved with a fixed gear; the adjusting assembly comprises a box body and an adjusting rod, the adjusting rod is connected with a locking assembly, the supporting rod vertically penetrates through the top of the box body and is in sliding fit with the box body, the adjusting rod transversely penetrates through one side of the box body and is in sliding fit with the box body, the bottom of the supporting rod is connected with a transmission assembly, one side of a fixed gear is connected with a rotating assembly, the adjusting rod is fixedly connected with a moving assembly, when the adjusting rod moves, the moving assembly can be respectively connected with the transmission assembly and the rotating assembly, when the moving assembly is connected with the transmission assembly, the height of the supporting rod can be adjusted by rotating the adjusting rod, and when the moving assembly is connected with the rotating assembly, the angle of the supporting rod can be adjusted by rotating the adjusting rod;

The transmission assembly comprises an auxiliary rod rotationally connected with the bottom of the supporting rod; the rotating assembly comprises a bracket fixedly connected with the inner wall of the box body, a first rotating shaft is rotatably connected to the bracket, a main gear is coaxially and fixedly connected to the first rotating shaft, a slave gear is meshed with the main gear, the slave gear is meshed with the fixed gear, and a first bevel gear is coaxially and fixedly connected to one side of the main gear;

The support is rotationally connected with a disc, a connecting rod is fixedly connected to the disc, one end, away from the disc, of the connecting rod is rotationally connected with the bottom of the auxiliary rod, and a second bevel gear is coaxially and fixedly connected to the disc; the moving assembly comprises an auxiliary bevel gear and a transmission bevel gear which are coaxially and fixedly connected with the adjusting rod, the auxiliary bevel gear can be meshed with the first bevel gear, and the transmission bevel gear can be meshed with the second bevel gear;

One side in the box body is fixedly connected with an auxiliary block, an adjusting rod penetrates through the auxiliary block and is in sliding fit with the auxiliary block, an auxiliary chamber is arranged in the auxiliary block, a limiting block is fixedly connected to the adjusting rod, a limiting component is arranged on the limiting block and used for throwing out a clamping block when the limiting block rotates, the limiting block is positioned in the auxiliary chamber and is in sliding fit with the side wall of the auxiliary chamber, and the auxiliary chamber is communicated with two limiting chambers;

The limiting assembly comprises a plurality of rotating rods and clamping blocks, the limiting blocks are provided with a plurality of grooves, the clamping blocks are respectively fixedly connected to one ends of the rotating rods, which are far away from the clamping blocks, are rotationally connected into the grooves, one sides of the clamping blocks are fixedly connected with tension springs, and one ends of the tension springs, which are far away from the clamping blocks, are fixedly connected into the grooves;

the bottom of the box body is fixedly connected with a support, and the bottom of the support is in a truncated cone shape;

The adjusting rod is connected with a transmission assembly, the transmission assembly is connected with a gas transmission assembly, the bottom of the support is in a hollowed-out state, and the gas transmission assembly is used for absorbing gas at the bottom of the support and transmitting the gas to the bottom of the monitoring equipment when the adjusting rod rotates;

the transmission assembly comprises a first gear and a second gear, the first gear is coaxially and fixedly connected to the adjusting rod, the second gear is meshed with the first gear, the second gear is rotatably connected to the bracket, and the gas transmission assembly is connected with the second gear;

The air delivery assembly comprises a crank, a connecting rod, a sliding block and an air cylinder, wherein the crank is rotationally connected to one side of the second gear, the crank is hinged with the connecting rod, one end of the connecting rod, far away from the crank, is rotationally connected with the sliding block, the sliding block is positioned in the air cylinder and is in sliding fit with the air cylinder, the air cylinder is fixedly connected in the box body, one side of the air cylinder, far away from the connecting rod, is provided with an air inlet and an air outlet, the air inlet is communicated with an air inlet pipe, the air outlet is communicated with an air outlet pipe, the air inlet pipe is communicated with an air inlet one-way valve, the air outlet pipe is communicated with an air outlet one-way valve, one end of the air inlet pipe, far away from the air cylinder, is communicated with the hollowed-out part of the support, and one end of the air outlet pipe, far away from the air cylinder, is fixedly connected below the monitoring equipment;

the bottom of the support is fixedly connected with a rubber layer.

2. The real-time clinical trial data monitoring device according to claim 1, wherein: one end of the adjusting rod positioned outside the box body is fixedly connected with a fixing rod, one end of the fixing rod is rotationally connected with a handle, and anti-skid patterns are arranged on the handle.

3. The real-time clinical trial data monitoring device according to claim 2, wherein: the locking assembly comprises a locking rod and a plurality of bayonets, the locking rod is connected to the fixed rod in a sliding mode, the bayonets are located on one side, close to the fixed rod, of the box body, and the bayonets are circumferentially arranged along the adjusting rod.