CN112591283B

CN112591283B - Rollover prevention stable kit transportation system based on wireless signal transmission

Info

Publication number: CN112591283B
Application number: CN202110057380.2A
Authority: CN
Inventors: 罗利花
Original assignee: Shenzhen Nuclear Huaxi Medical Laboratory
Current assignee: Shenzhen Nuclear Huaxi Medical Laboratory
Priority date: 2021-01-15
Filing date: 2021-01-15
Publication date: 2022-07-05
Anticipated expiration: 2041-01-15
Also published as: CN112591283A

Abstract

The invention discloses a rollover prevention stabilization kit transportation system based on wireless signal transmission, which comprises a shell and a cover shell, wherein the cover shell is rotatably connected to the front wall of the shell; the internal clamping device can sense the reagent boxes placed in the placing groove and perform clamping and fixing work, so that the reagent boxes with different specifications can be fixed in the placing groove, the use range is expanded, the supporting device is arranged in the internal clamping device and can support the moving block when the moving block slides out of the first sliding groove, the bearing of the moving block is increased, the reagent boxes placed in the placing groove are protected, the safety of the reagent boxes when the moving block slides in and out is ensured, the fingerprint touch button is arranged to start the hydraulic pump to lock and open the Kass device according to correct fingerprints, the machine can be used only by correct people, the safety of the internal reagent boxes is ensured, the refrigerating device is arranged to control the temperature in the reagent boxes, and the reagent is prevented from being deteriorated due to the influence of the temperature.

Description

Rollover prevention stable kit transportation system based on wireless signal transmission

Technical Field

The invention relates to the technical field of kits, in particular to a rollover prevention stable kit transportation system based on wireless signal transmission.

Background

The outbreak of the virus can not be predicted by anyone in advance, once the virus outbreak is in the first battle, the kit is used for detecting unknown virus, judging the virus and determining that the virus can be used for prescribing a medicine according to the disease, so the kit is very important for the centralized transportation of the kit after various related information is collected, for example, when the whole reagent transportation box turns over laterally in the transportation process, the reagent in the reagent transportation box can generate violent collision and shake, possibly influence the internal structure of the reagent and influence the subsequent experimental result, the existing reagent transportation box only provides basic protection, and no definite solution is provided for the rollover of the whole box body possibly generated in the transportation process.

Disclosure of Invention

The invention aims to provide a rollover-prevention stable kit transportation system based on wireless signal transmission, which is used for overcoming the defects in the prior art.

According to the invention, the rollover prevention stable kit transportation system based on wireless signal transmission comprises a shell and a cover shell which is rotatably connected to the front wall of the shell, wherein a first rotating cavity with a forward opening is arranged in the shell, a first motor is arranged on the top wall of the first rotating cavity, a first worm which is rotatably connected with the bottom wall of the first rotating cavity is arranged on the bottom wall of the first motor, two groups of stabilizing blocks which are symmetrical in position are fixedly connected on the upper wall and the lower wall of the first rotating cavity, sliding grooves which penetrate through from left to right and have inward openings are arranged in the stabilizing blocks, a first worm wheel is slidably connected between the upper sliding groove and the lower sliding groove, the first worm is matched and connected with the first worm wheel, a fixing groove which penetrates through from front to back is arranged in the first worm wheel, a reagent box shell is fixedly connected in the fixing groove, and three groups of second rotating cavities which are arranged from top to bottom and have forward openings are arranged in the reagent box shell, the inner wall of the second rotating cavity is rotatably connected with a first rotating shaft fixedly connected with the side wall of the rotating block, a second worm wheel is fixedly connected to the first rotating shaft, a second worm meshed with the second worm wheel is rotatably connected between the front wall and the rear wall of the rotating cavity, the front end of the second worm is provided with a second motor fixedly connected with the front wall of the rotating cavity, belt wheels are fixedly connected with the second worm, the left and the right groups of belt wheels are in belt transmission, two groups of induction grooves with symmetrical positions are communicated in the left and the right walls of the second rotating cavity, induction blocks are connected in the induction grooves in a sliding manner, the bottom of each induction groove is communicated with a third slide rail groove, and the bottom wall of the third slide rail groove is fixedly connected with a third electric slide rail capable of driving the induction blocks to move, a moving groove with a forward opening is arranged in the rotating block, a moving block is connected to the bottom wall of the moving groove in a sliding manner, two groups of first sliding rail grooves with symmetrical positions are arranged on the left wall and the right wall of the moving groove, a first electric sliding rail is fixedly connected to the side wall, far away from the moving block, of the first sliding rail groove, a first connecting block fixedly connected with the moving block is mounted on the first electric sliding rail, a plurality of placing grooves with upward openings are formed in the moving block in an array manner, a clamping device capable of clamping a kit is arranged in each placing groove, two groups of stabilizing grooves with symmetrical positions and forward openings are communicated with the bottom wall of the moving groove, a supporting device capable of stabilizing the moving block is mounted in each stabilizing groove, a refrigerating device capable of refrigerating is mounted on the rear wall of the first rotating cavity, and a locking device capable of locking the shell and the cover shell is mounted between the shell and the cover shell, an auxiliary device capable of helping to complete work is installed in the shell.

Optionally, the clamping device includes a sensor arranged on the bottom wall of the placement groove, the side wall of the placement groove is fitted with a ring and provided with four sets of second slide rail grooves communicated with the placement groove, a transmission block is slidably connected in the second slide rail grooves, the bottom wall of the second slide rail grooves is communicated with a third slide rail groove, the bottom wall of the third slide rail grooves is fixedly connected with a second electric slide rail, the second electric slide rail is provided with a second connection block fixedly connected with the transmission block, and the side wall of the transmission block is fixedly connected with an extrusion block.

Optionally, the supporting device includes a first sliding groove formed in the rear wall of the stabilizing groove in a communicating manner, the first sliding groove is connected with two sets of sliding rods symmetrically arranged in the left and right directions in a sliding manner, the sliding rods are fixedly connected with an expansion bracket, the bottom wall of the moving block is provided with two sets of second sliding grooves corresponding to the positions of the stabilizing groove, the front end of the expansion bracket is fixedly connected with two sets of third connecting blocks symmetrically arranged in the left and right directions, and the third connecting blocks are connected in the second sliding grooves in a sliding manner.

Optionally, the locking device including three group arrange from top to bottom set up in lid shell right side wall and opening right push rod groove, push rod inslot sliding connection has the card dead block, pneumatic pump is installed to push rod groove left side wall, pneumatic pump passes through pneumatic tube fixed connection the card dead block left side wall, the shell with the junction of lid shell be equipped with three group with push rod groove position corresponds and opening card dead groove left, touch-control fingerprint button is installed to the shell antetheca.

Optionally, the refrigerating device comprises an annular water pipe fixedly connected to the rear wall of the first rotating cavity, a refrigerating cavity is arranged behind the first rotating cavity, a water circulation refrigerator is installed between the front wall and the rear wall of the refrigerating cavity, and two ends of the annular water pipe extend into the refrigerating cavity and are connected with the water circulation refrigerator.

Optionally, the auxiliary device includes a positioner fixedly mounted on the top wall of the first rotating cavity, a control button is mounted on the reagent box housing and is opposite to the second rotating cavity, a 24GHz radar sensor is mounted on the bottom wall of the housing, and an armrest is fixedly connected to the front wall of the cover housing.

The invention has the beneficial effects that:

firstly, the method comprises the following steps: according to the invention, the clamping devices are arranged in each placing groove, so that the reagent boxes with different specifications can be sensed and clamped and fixed, each reagent box can be stably placed in the placing groove, the reagent box range of the transport case which can be transported is enlarged, and the use efficiency is improved.

Secondly, the method comprises the following steps: the auxiliary device is arranged in the transport case, the motion track of the transport case can be monitored in real time through the positioner in the auxiliary device, the transport case is prevented from being stolen, even if the transport case is stolen, the transport case can be quickly found out, the moving of the moving block can be controlled through the control button, the reagent can be conveniently placed and taken, whether the transport case turns over on one side or not in the transport process can be monitored in real time through the 24GHz radar sensor, if the situation that the inside of the transport case turns over on one side is monitored, automatic correction can be automatically carried out, and the chemical reaction caused by long-time position change of reagent liquid in the reagent case after the reagent liquid turns over on one side is prevented from influencing the experimental result of the reagent liquid.

Thirdly, the method comprises the following steps: the invention can remotely monitor the working state of the transport case by utilizing the transmission and reception of wireless signals, can make emergency measures in the first time when an emergency occurs, and ensures the stability and safety of the reagents in the transport case.

Drawings

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention; it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments, and all other embodiments obtained by those skilled in the art without any inventive work are within the scope of the present invention.

FIG. 1 is a schematic structural diagram of a rollover prevention stabilization kit transportation system based on wireless signal transmission according to the invention;

FIG. 2 is a schematic view of the internal structure of FIG. 1;

FIG. 3 is a schematic view of the second rotating chamber of FIG. 2;

FIG. 4 is a schematic view of the structure at A-A in FIG. 2;

FIG. 5 is a schematic top view of the stabilizer slot of FIG. 3;

FIG. 6 is a schematic bottom view of the annular water tube of FIG. 4;

FIG. 7 is a schematic bottom view of the trough of FIG. 4;

FIG. 8 is a schematic view of the structure of the induction tank of FIG. 3;

fig. 9 is a schematic bottom view of the locking device of fig. 4.

Detailed Description

In the description of the present invention, it should be noted that the terms "upper", "lower", "inner", "outer", "top/bottom", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

Referring to fig. 1 to 9, the rollover prevention and stabilization reagent kit transportation system based on wireless signal transmission according to the embodiment of the present invention includes a housing 11 and a cover housing 12 rotatably connected to a front wall of the housing 11, a first rotating cavity 15 with a forward opening is provided in the housing 11, a first motor 19 is installed on a top wall of the first rotating cavity 15, a first worm 18 rotatably connected to a bottom wall of the first rotating cavity 15 is installed on a bottom wall of the first motor 19, two sets of stabilizing blocks 75 with symmetrical positions are fixedly connected to upper and lower walls of the first rotating cavity 15, a sliding slot 76 with a left-right penetrating opening and an inward opening is provided in each stabilizing block 75, a first worm wheel 16 is slidably connected between the upper and lower sliding slots 76, the first worm 18 is connected to the first worm wheel 16 in a matching manner, a fixing slot 53 with a front-back penetrating manner is provided in the first worm wheel 16, a reagent kit housing 17 is fixedly connected to the fixing slot 53, the reagent box comprises a reagent box shell 17, wherein three groups of second rotating cavities 21 which are arranged up and down and have forward openings are arranged in the reagent box shell 17, a rotating block 29 is rotationally connected in each second rotating cavity 21, the left wall and the right wall of each second rotating cavity 21 are respectively communicated with two groups of rotating grooves 62 which are symmetrical in position, the inner wall of each rotating groove 62 is rotationally connected with a first rotating shaft 26 which is fixedly connected with the side wall of each rotating block 29, a second worm wheel 27 is fixedly connected on each first rotating shaft 26, a second worm 28 which is meshed with the second worm wheel 27 is rotationally connected between the front wall and the rear wall of each rotating groove 62, the front end of the second worm is provided with a second motor 37 which is fixedly connected with the front wall of each rotating groove 62, a belt wheel 41 is fixedly connected on the second worm, the left wall and the right wall of each rotating cavity 21 are communicated with two groups of induction grooves 61 which are symmetrical in position, an induction block 24 is connected in the induction groove 61 in a sliding manner, a third slide rail groove 22 is communicated with the bottom of the induction groove 61, a third electric slide rail 23 capable of driving the induction block 24 to move is fixedly connected to the bottom wall of the third slide rail groove 22, a moving groove 30 with a forward opening is arranged in the rotating block 29, a moving block 31 is connected to the bottom wall of the moving groove 30 in a sliding manner, two groups of first slide rail grooves 36 with symmetrical positions are arranged on the left wall and the right wall of the moving groove 30, a first electric slide rail 43 is fixedly connected to the side wall, far away from the moving block 31, of the first slide rail groove 36, a first connecting block 66 fixedly connected with the moving block 31 is installed on the first electric slide rail 43, a plurality of placing grooves 32 with upward openings are arranged on the moving block 31 in an array manner, a clamping device 101 capable of clamping a reagent kit is arranged in the placing groove 32, two groups of stabilizing grooves 34 with symmetrical positions and forward openings are communicated with the bottom wall of the moving groove 30, a supporting device 102 capable of stabilizing the moving block 31 is installed in the stabilizing groove 34, a refrigerating device 104 capable of refrigerating is installed on the rear wall of the first rotating cavity 15, a locking device 103 capable of locking the housing 11 and the cover housing 12 is installed between the housing 11 and the cover housing 12, and an auxiliary device 105 capable of helping to complete work is installed in the housing 11.

Preferably, the clamping device 101 includes an inductor 52 disposed on the bottom wall of the placing groove 32, four sets of second slide rail grooves 50 corresponding in position and communicating with the placing groove 32 are annularly disposed on the side wall of the placing groove 32, a driving block 48 is slidably connected in the second slide rail grooves 50, a third slide rail groove 68 is communicated with the bottom wall of the second slide rail grooves 50, a second electric slide rail 51 is fixedly connected to the bottom wall of the third slide rail groove 68, a second connecting block 67 fixedly connected with the driving block 48 is mounted on the second electric slide rail 51, a squeezing block 47 is fixedly connected to the side wall of the driving block 48, the second electric slide rail 51 is started to drive the driving block 48 to move, the driving block 48 drives the squeezing block 47 to move, reagent cartridges placed in the placing groove 32 can be induced by the clamping device 101, and clamping and fixing operations can be performed, reagent cartridges of different sizes can be stabilized in the placing groove 32, the application range is enlarged.

Preferably, the supporting device 102 includes a first sliding groove 30 disposed in communication with a rear wall of the stabilizing groove 34, two sets of sliding rods 71 symmetrically positioned left and right are slidably connected in the first sliding groove 30, an expansion bracket 70 is fixedly connected to the sliding rods 71, two sets of second sliding grooves 69 corresponding to the stabilizing groove 34 are disposed on a bottom wall of the moving block 31, two sets of third connecting blocks 33 symmetrically positioned left and right are fixedly connected to a front end of the expansion bracket 70, the third connecting blocks 33 are slidably connected in the second sliding grooves 69, the moving block 31 moves to drive the expansion bracket 70 to extend, the expansion bracket 70 drives the sliding rods 71 to move, the expansion bracket 70 drives the third connecting blocks 33 to move at the same time, the supporting device 102 can support the moving block 31 when the moving block 31 slides out of the first sliding groove 30, so that the bearing of the moving block 31 is increased, and the reagent boxes disposed in the disposing groove 32 are protected, the safety of the reagent cartridge is ensured when the moving block 31 slides in and out.

Preferably, the locking device 103 includes three sets of push rod slots 56 arranged up and down on the right wall of the cover housing 12 and having a right opening, a locking block 59 is slidably connected in the push rod slot 56, a pneumatic pump 57 is installed on the left wall of the push rod slot 56, the pneumatic pump 57 is fixedly connected to the left wall of the locking block 59 through a pneumatic tube 58, three sets of locking slots 55 corresponding to the push rod slots 56 and having a left opening are arranged at the joint of the housing 11 and the cover housing 12, a touch fingerprint button 14 is installed on the front wall of the housing 11, the pneumatic tube 58 is extended by starting the hydraulic pump 59, the pneumatic tube 58 drives the locking block 59 to move, the housing 11 and the cover housing 12 can be locked through the locking device 103, the touch button 14 can start the pneumatic pump 57 to lock and unlock the locking device 104 according to a correct fingerprint, so as to ensure that only a correct person can use the machine, the safety of the internal kit is guaranteed.

Preferably, the refrigerating device 104 comprises an annular water pipe 44 fixedly connected to the rear wall of the first rotating cavity 15, a refrigerating cavity 45 is arranged behind the first rotating cavity 15, a water circulation refrigerator 46 is installed between the front wall and the rear wall of the refrigerating cavity 45, two ends of the annular water pipe 44 extend into the refrigerating cavity 45 and are connected with the water circulation refrigerator 46, the water circulation refrigerator 46 is started for refrigerating, the temperature of the environment where the reagent kit can be placed through the refrigerating device 104 is controlled, and it is ensured that the reagent in the reagent kit is not affected by the temperature and goes bad.

Preferably, the auxiliary device 105 includes a positioner 54 fixedly mounted on the top wall of the first rotating cavity 15, the reagent box housing 17 is mounted with a control button 20 opposite to the second rotating cavity 21, the bottom wall of the housing 11 is mounted with a 24GHz radar sensor 60, the front wall of the cover housing 12 is fixedly connected with a handrail 13, the first electric slide rail 43 is started by pressing the button 20, the first electric slide rail 43 drives the moving block 31 to move, the moving block 31 drives the placing groove 32 to move, the movement track of the transport box can be monitored in real time by the positioner 54 in the auxiliary device 105, so as to prevent theft, even if the transport box is stolen, the transport box can be recovered, the movement of the moving block 31 can be controlled by the control button 20, so as to facilitate the placement and the taking of reagents, the 24GHz radar sensor 60 can monitor whether the transport box is turned on its side in the transportation process in real time, if monitoring that the inside of the turned on side can be automatically corrected, the chemical reaction caused by long-time position change of the reagent liquid in the reagent box after the reagent box is turned over is prevented, and the influence on the experiment result of the reagent liquid is prevented.

In the initial state, the first motor 19 is turned off, the second motor 37 is turned off, the first electric slide rail 43 is turned off, the second electric slide rail 51 is turned off, the sensor 52 is turned off, the 24GHz radar sensor 60 is turned off, the third electric slide rail 23 is turned off, the expansion bracket 70 is in the normal state, the water circulation refrigerator 46 is turned off, and the hydraulic pump 59 is turned off.

When a reagent box needs to be placed, the water circulation refrigerator 46 is started to refrigerate the inside of the shell 11, the cover shell 12 is opened after the temperature is proper, the control button 20 is pressed to start the first electric sliding rail 43 to drive the moving block 31 to slide out, the reagent box is placed in the placing groove 32 and clamped tightly, and after the reagent box is placed completely, the control button 20 is pressed again to start the first electric sliding rail 43 to slide the moving block 31 inwards, and the cover shell 12 is closed.

When the whole box body is laterally overturned and the reagent position needs to be corrected, the 24GHz radar sensor 60 senses that the box body is laterally overturned, the first motor 19 is started to drive the first worm 18 to rotate, the first worm 18 drives the first worm wheel 16 to rotate, the first worm wheel 16 drives the reagent box shell 17 to rotate so as to correct the laterally overturned reagent, when the 24GHz radar sensor 60 senses that the box body is laterally overturned, the third electric slide rail 23 is started to drive the induction block 24 to move and retract, the second motor 37 is started to drive the left second worm 28 to rotate, the left second worm 28 drives the right second worm 28 to rotate through the belt wheel 41 and the belt 42, the second worm 28 drives the second worm wheel 27 to rotate, the second worm 27 drives the first rotating shaft 26 to rotate, and the left and right first rotating shafts 26 drive the rotating block 29 to rotate, so as to correct the laterally overturned reagent.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims

1. The utility model provides a prevent stabilizing kit conveyor system that turns on one's side based on wireless signal transmission, include the shell and rotate connect in the lid shell of shell antetheca, its characterized in that: a first rotating cavity with a forward opening is arranged in the shell, a first motor is arranged on the top wall of the first rotating cavity, a first worm rotatably connected with the bottom wall of the first rotating cavity is arranged on the bottom wall of the first motor, two groups of stabilizing blocks with symmetrical positions are fixedly connected with the upper wall and the lower wall of the first rotating cavity, sliding grooves which penetrate left and right and have inward openings are arranged in the stabilizing blocks, a first worm wheel is slidably connected between the upper group of sliding grooves and the lower group of sliding grooves, the first worm is in fit connection with the first worm wheel, a fixing groove which penetrates front and back is arranged in the first worm wheel, a reagent box shell is fixedly connected in the fixing groove, three groups of second rotating cavities which are arranged up and down and have forward openings are arranged in the reagent box shell, a rotating block is rotatably connected in the second rotating cavity, and two groups of rotating grooves with symmetrical positions are respectively communicated with the left wall and the right wall of the second rotating cavity, the inner wall of the rotating groove is rotationally connected with a first rotating shaft fixedly connected with the side wall of the rotating block, a second worm wheel is fixedly connected onto the first rotating shaft, a second worm meshed with the second worm wheel is rotationally connected between the front wall and the rear wall of the rotating groove, a second motor fixedly connected with the front wall of the rotating groove is mounted at the front end of the second worm on the left side, belt wheels are fixedly connected onto the second worm, the left and right belt wheels are driven by a belt, two groups of sensing grooves with symmetrical positions are communicated in the left and right walls of the second rotating cavity, a sensing block is connected in the sensing groove in a sliding manner, a third slide rail groove is communicated with the bottom of the sensing groove, a third electric slide rail capable of driving the sensing block to move is fixedly connected onto the bottom wall of the third slide rail groove, a moving groove with a forward opening is arranged in the rotating block, and a moving block is connected onto the bottom wall of the moving groove in a sliding manner, the movable block is characterized in that two sets of first sliding rail grooves with symmetrical positions are arranged on the left wall and the right wall of the movable block, first electric sliding rails are fixedly connected to the side walls of the movable block and far away from the first sliding rail grooves, first connecting blocks fixedly connected with the movable block are mounted on the first electric sliding rails, a plurality of placing grooves with upward openings are formed in the movable block in an array mode, clamping devices capable of clamping a kit are arranged in the placing grooves, two sets of stabilizing grooves with symmetrical positions and forward openings are formed in the bottom wall of the movable block in a communicating mode, supporting devices capable of stabilizing the movable block are mounted in the stabilizing grooves, a refrigerating device capable of refrigerating is mounted on the rear wall of a first rotating cavity, locking devices capable of locking a shell and a cover shell are mounted between the shell and the cover shell, and auxiliary devices capable of helping to complete work are mounted in the shell.

2. The rollover prevention stabilization kit transportation system based on wireless signal transmission as claimed in claim 1, wherein: clamping device including set up in the inductor of standing groove diapire, the standing groove lateral wall fit with a contraceptive ring be equipped with four group's position correspondence and with the second slide rail groove of standing groove intercommunication, sliding connection has the transmission piece in the second slide rail groove, second slide rail groove diapire intercommunication is equipped with the third slide rail groove, the electronic slide rail of third slide rail groove diapire fixedly connected with second, the electronic slide rail of second install with transmission piece fixed connection's second connecting block, transmission piece lateral wall fixedly connected with extrusion piece.

3. The rollover prevention stabilization kit transportation system based on wireless signal transmission as claimed in claim 1, wherein: the supporting device comprises a first sliding groove formed in the rear wall of the stabilizing groove in a communicated mode, two groups of sliding rods which are symmetrical in left and right positions are connected in the first sliding groove in a sliding mode, an expansion bracket is fixedly connected to the sliding rods, two groups of second sliding grooves corresponding to the positions of the stabilizing groove are formed in the bottom wall of the moving block, two groups of third connecting blocks which are symmetrical in left and right positions are fixedly connected to the front end of the expansion bracket, and the third connecting blocks are connected in the second sliding grooves in a sliding mode.

4. The rollover prevention stabilization kit transportation system based on wireless signal transmission as claimed in claim 1, wherein: the device of dying includes that three group arrange from top to bottom set up in lid shell right side wall and opening push rod groove to the right, push rod inslot sliding connection has the card dead block, pneumatic pump is installed to push rod groove left side wall, pneumatic pump passes through pneumatic tube fixed connection the card dead block left side wall, the shell with the junction of lid shell be equipped with three groups with the dead groove of card that the push rod trench position corresponds and opening left, touch-control fingerprint button is installed to the shell antetheca.

5. The rollover prevention stabilization kit transportation system based on wireless signal transmission as claimed in claim 1, wherein: the refrigerating device comprises an annular water pipe fixedly connected to the rear wall of the first rotating cavity, a refrigerating cavity is arranged behind the first rotating cavity, a water circulation refrigerator is installed between the front wall and the rear wall of the refrigerating cavity, and two ends of the annular water pipe extend to the refrigerating cavity and are connected with the water circulation refrigerator.

6. The rollover prevention stabilization kit transportation system based on wireless signal transmission as claimed in claim 1, wherein: the auxiliary device comprises a positioner fixedly installed on the top wall of the first rotating cavity, a control button opposite to the second rotating cavity is installed on the outer shell of the reagent box, a 24GHz radar sensor is installed on the bottom wall of the outer shell, and a handrail is fixedly connected to the front wall of the outer shell.