CN211043410U - Pepsinogen II detection kit - Google Patents

Abstract

The utility model relates to a pepsinogen II detection kit, which effectively solves the problem that the prior pepsinogen detection kit does not have the shaking function; compared with the kit on the market, the kit can uniformly mix the serum which is placed for a long time, and when a user mixes the enzyme conjugate with the serum sample, the kit can fully mix the enzyme conjugate and the serum sample which are mixed together, so that the reaction can be fully carried out, the reliability and the accuracy of an experiment detection result are increased, and the workload of experiment workers is reduced.

Description

Pepsinogen II detection kit

Technical Field

The utility model relates to an antigen detection technical field, concretely relates to pepsinogen II detect reagent box.

Background

Pepsinogen is a precursor of pepsin, which is divided into 2 subgroups according to its biochemical properties and immunogenicity, and 1-5 components have the same immunogenicity, are called pepsinogen I and are mainly secreted by the main cells of the fundus stomach gland and the mucous neck cells; components 6 and 7 are called pepsinogen II, which is produced in addition to secretion by the principal cells of the fundic gland and the mucous cervical cells of the pyloric gland of the cardia and antrum and the upper duodenum;

generally, about 1% of PG enters blood circulation through capillary vessels of gastric mucosa, the PG entering the blood circulation is very stable in blood, the PG I and PG II in serum reflect the number of glands and cells of the gastric mucosa and indirectly reflect the secretion function of different parts of the gastric mucosa, and the content of PG in the serum is changed when the gastric mucosa is pathologically changed, so that the concentration of PG in the serum can be used as a means for monitoring the state of the gastric mucosa;

when a hospital detection department can perform pepsinogen II detection on a patient, the collected blood is usually subjected to centrifugal treatment to obtain a serum sample, because the hospital collects a lot of serum of the patient at one time, the detection cannot be completed in a short time, the serum needs to be stored in an environment of 2-8 ℃ to ensure the activity of the serum, the undetected serum can precipitate along with the detection, the serum needs to be uniformly shaken at the moment, otherwise, the detection result is influenced, and the workload of experimenters is increased undoubtedly when the number of batches of serum is large;

in addition, when the laboratory staff detects the serum, the enzyme conjugate and the serum sample need to be mixed together for reaction, if the enzyme conjugate and the serum are not mixed uniformly, the reaction cannot be carried out fully, the detection result is also influenced, and in view of the above, a pepsinogen II detection kit is designed for solving the above problems.

SUMMERY OF THE UTILITY MODEL

To the above-mentioned condition, for overcoming prior art's defect, the utility model provides a pepsinogen II detect reagent box, this kit can realize carrying out the mixing to the serum of placing for a long time for the kit on the market and when the user of service mixes the enzyme conjugate and the reaction of being in the same place of serum sample, this kit can be with mixing enzyme conjugate and serum sample intensive mixing together for the reaction can fully go on, thereby increased experiment testing result's reliability, accurate nature, also alleviateed experiment staff's work burden simultaneously.

The pepsinogen II detection kit comprises a kit and is characterized in that a shaking seat is transversely connected in the kit in a sliding manner, a plurality of placing cavities are arranged on the shaking seat, a placing cylinder is rotatably arranged in the placing cavity, the bottom of the placing cylinder is connected with a transmission device arranged in the shaking seat, it is equipped with clamping device on the section of thick bamboo to place, and transmission is connected with and sets up second bevel gear group and second bevel gear group in shaking even seat and is connected with the telescopic shaft that rotates to install on shaking even seat lateral wall, and the telescopic shaft is connected with first bevel gear group and first bevel gear group that sets up in the reagent box and is driven by the micro motor who sets up on the kit diapire through first belt pulley group, shakes even seat bottom wall fixedly connected with rectangle tooth frame and rectangle tooth frame cooperation and has through micro motor driven half-gear, the installation is rotated to the kit upper end and is provided with apron and be equipped with sealing device.

Preferably, place a diapire fixedly connected with pivot and rotate through the pivot and install in placing the chamber diapire, transmission includes: the rotating shaft is sleeved with a belt pulley which is matched with a transmission belt, two rotating shafts close to the second bevel gear set are respectively connected with a second belt pulley set, and the two second belt pulley sets are driven by the second bevel gear set.

Preferably, the telescopic shaft is rotatably installed on a transmission shaft close to one side wall of the first bevel gear set in the shaking seat, the transmission shaft is arranged in the shaking seat, one end of the transmission shaft is connected with the second bevel gear set, and the transmission shaft is arranged outside the shaking seat and is axially and slidably connected with a driving shaft connected with the first bevel gear set.

Preferably, the clamping device comprises arc-shaped clamping plates arranged on two axial sides in the placing barrel, the arc-shaped clamping plates are fixedly connected with a sliding rod and are connected to the placing barrel wall through the sliding rod in a sliding mode, one end of the sliding rod outside the placing barrel is fixed with a compression spring coaxially, and the other end of the compression spring is fixed on the placing barrel.

Preferably, an organic whole is connected with rectangle chamber and the vertical both sides wall in rectangle chamber on the apron and is equipped with the spout of horizontal extension, and sealing device includes: vertical sliding connection has the slide rail of horizontal extension and horizontal sliding connection has to support the clamp plate between two slide rails in the spout, support the clamp plate diapire and rotate install and place a corresponding drum and drum in axial sliding connection have the round bar, the round bar bottom is fixed with between butt plate and round bar and the drum diapire through supporting pressing spring coupling, support the clamp plate under the terminal surface be fixed with the actuating lever of vertical extension and shake even be equipped with actuating lever matched with jack on the seat, two slide rails are by setting up the elevating gear drive on the rectangle chamber.

Preferably, the lifting device is in threaded fit with the slide rail by rotating a screw rod arranged on the bottom wall of one of the slide grooves, a limit column is connected to the side wall of one of the slide rails in a sliding manner, the limit column is connected with the slide rail by a reset spring, and a convex arc shape is arranged at one end, matched with the limit column, of the abutting plate.

Preferably, the bottom wall of the abutting plate is fixedly provided with a damping sheet.

Preferably, the upper end of the rectangular cavity is provided with a handle, and one lateral side of the kit is fixedly provided with a lock catch matched with the cover plate.

The beneficial effects of the technical scheme are as follows:

compared with the kit on the market, the kit can uniformly mix the serum which is placed for a long time, and when a user mixes the enzyme conjugate with the serum sample, the kit can fully mix the enzyme conjugate and the serum sample (antigen and antibody combined reaction) which are mixed together, so that the reaction can be fully performed, the reliability and the accuracy of an experiment detection result are improved, the workload of experiment workers is reduced, and the experiment workers can apply more energy to work experiments.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the internal structure of the reagent kit according to the present invention after longitudinal cross-sectional view from one side;

FIG. 3 is a schematic view of the present invention with the kit removed;

FIG. 4 is a schematic structural view of the utility model with the reagent kit and the shaking seat removed;

FIG. 5 is a schematic view of the kit according to the present invention from the back;

FIG. 6 is a schematic view of the connection relationship between a plurality of placement cylinders and a transmission device according to the present invention;

FIG. 7 is a schematic sectional view of the cover plate, the leveling cavity, and the shaking seat of the present invention;

FIG. 8 is a schematic sectional view of the cylinder of the present invention;

fig. 9 is a schematic structural view of the slide rail and the pressing plate of the present invention after being cut away;

in the figure: the kit comprises a kit 1, a shaking seat 2, a placing cavity 3, a placing barrel 4, a first bevel gear set 5, a telescopic shaft 6, a second bevel gear set 7, a first belt pulley set 8, a micro motor 9, a rectangular toothed frame 10, a half gear 11, a cover plate 12, a rotating shaft 13, a belt pulley 14, a transmission belt 15, a second belt pulley set 16, a transmission shaft 17, a driving shaft 18, an arc-shaped clamping plate 19, a sliding rod 20, a compression spring 21, a rectangular cavity 22, a sliding groove 23, a sliding rail 24, a pressing plate 25, a cylinder 26, a round rod 27, a butt plate 28, a pressing spring 29, a connecting rod 30, a jack 31, a screw rod 32, a limiting column 33, a limiting hole 34, a handle 35, a lock catch 36 and a reset spring 37.

Detailed Description

The foregoing and other technical matters, features and effects of the present invention will be apparent from the following detailed description of the embodiments, which is to be read in connection with the accompanying drawings of fig. 1 to 9. The structural contents mentioned in the following embodiments are all referred to the attached drawings of the specification.

Exemplary embodiments of the present invention will be described below with reference to the accompanying drawings.

The first embodiment of the kit for detecting pepsinogen II comprises a kit 1 and is characterized in that a shaking seat 2 is connected in the kit 1 in a transverse sliding manner, a plurality of placing cavities 3 are arranged on the shaking seat 2, a placing barrel 4 is rotationally installed in the placing cavity 3, the bottom of the placing barrel 4 is connected with a transmission device arranged in the shaking seat 2, a clamping device is arranged on the placing barrel 4, the transmission device is connected with a second bevel gear set 7 arranged in the shaking seat 2, the second bevel gear set 7 is connected with a telescopic shaft 6 rotationally installed on the side wall of the shaking seat 2, the telescopic shaft 6 is connected with a first bevel gear set 5 arranged in the kit 1, the first bevel gear set 5 is driven by a micro motor 9 arranged on the bottom wall of the kit 1 through a first belt pulley set 8, a rectangular gear frame 10 is fixedly connected to the bottom wall of the shaking seat 2, and the rectangular gear frame 10 is matched with a semi-gear 11 driven by the, the upper end of the kit 1 is rotatably provided with a cover plate 12, and the cover plate 12 is provided with a sealing device.

In the embodiment, referring to the attached drawing 2, a shaking seat 2 is connected in a kit 1 in a transverse sliding manner, a plurality of placing cavities 3 are arranged in the shaking seat 2, an experimenter places test tubes with serum samples in a placing cylinder 4, firstly, the experimenter opens a cover plate 12 and places the test tubes in the placing cylinder 4, the test tubes are clamped and positioned by a clamping device arranged on the placing cylinder 4, relative movement between the test tubes and the placing cylinder 4 is prevented, the experimenter drives a half gear 11 to rotate (as shown in the attached drawing 5) through a micro motor, and then drives a rectangular gear frame 10 to do reciprocating circular motion, because the rectangular gear frame 10 is fixedly connected with the bottom wall of the shaking seat 2 and further drives the shaking seat 2 to do transverse reciprocating motion in a reagent chamber, the micro motor drives the shaking seat 2 to move and simultaneously drives a first bevel gear group 5 arranged in the reagent chamber to rotate (as shown in the attached drawing 2) through a first belt gear group 8, the first bevel gear set 5 drives the second bevel gear set 7 arranged in the shaking seat 2 to rotate through the telescopic shaft 6, the second bevel gear set drives the placing cylinders 4 which are rotatably arranged in the placing cavity 3 to rotate through a transmission device connected with the second bevel gear set, namely, the micro motor drives the shaking seat 2 to do reciprocating circular motion in the reagent, and simultaneously drives the placing cylinders 4 to rotate in the placing cavity 3 through the transmission device, so that the clamping device is positioned on test tubes in the placing cylinders 4, and the test tubes also transversely reciprocate along with the shaking seat 2 during rotation, so that a serum sample and an enzyme conjugate in the test tubes are mixed more uniformly, and the experimental detection result is more reliable and accurate;

preferably, a sealing device is arranged on the cover plate 12, when an experimenter places the test tube in the placing cylinder 4, the cover plate 12 is closed and the sealing device simultaneously carries out sealing treatment on the test tube placed in the placing cylinder 4, so that a serum sample and enzyme conjugates (antigens and antibodies) in the test tube are prevented from splashing out of the test tube during the process of autorotation, shaking and transverse reciprocating motion of the test tube.

Second, on the basis of first embodiment, place a 4 diapire fixedly connected with pivot 13 of section of thick bamboo and rotate through pivot 13 and install in placing 3 diapalls of chamber, transmission includes: a belt pulley 14 is fixedly sleeved on the rotating shaft 13, a transmission belt 15 is matched with the belt pulley 14, two rotating shafts 13 close to the second bevel gear set 7 are respectively connected with a second belt pulley set 16, and the two second belt pulley sets 16 are driven by the second bevel gear set 7.

When the embodiment is used, as shown in the attached drawing 2, the bottom of the placing cylinder 4 is fixedly connected with a rotating shaft 13 and is installed on the bottom wall of the placing cavity 3 through the rotating shaft 13 in a rotating mode, the plurality of rotating shafts 13 are all sleeved with the inherent belt pulleys 14, the belt pulleys 14 are matched with the driving belts 15, as shown in the attached drawings 4 and 6, the two driving belts 15 are vertically arranged at intervals, each driving belt 15 is matched with the three belt pulleys 14 and drives the three placing cylinders 4 to rotate, the bottom of each placing cylinder 4 close to the second bevel gear set 7 is respectively connected with the second belt pulley set 16 through the rotating shaft 13, the second belt pulley set 16 is driven through the second bevel gear set 7, the two placing cylinders 4 close to the second bevel gear set 7 rotate, and then drive the other placing cylinders 4 to synchronously rotate through the driving belts 15, and the effect of driving.

In the third embodiment, on the basis of the first embodiment, the telescopic shaft 6 includes a transmission shaft 17 rotatably installed on the shaking seat 2 near one side wall of the first bevel gear set 5, the transmission shaft 17 is disposed in the shaking seat 2, one end of the transmission shaft 17 is connected with the second bevel gear set 7, and one end of the transmission shaft 17 disposed outside the shaking seat 2 is axially slidably connected with a driving shaft 18 connected with the first bevel gear set 5.

When the embodiment is used, referring to the attached drawing 3, a transmission shaft 17 is rotatably installed on one lateral wall of the shaking seat 2, one end of the transmission shaft 17 in the shaking seat 2 is connected with the second bevel gear set 7, referring to the attached drawing 2, one end of the transmission shaft 17 outside the shaking seat 2 is axially and slidably connected with a driving shaft 18, the driving shaft 18 is connected with the first bevel gear set 5, and when the micro motor drives the half gear 11 to drive the shaking seat 2 to do transverse reciprocating motion in the reagent kit 1, the shaking seat 2 drives the transmission shaft 17 to axially slide along the driving shaft 18 on the lateral wall of the reagent kit 1 in a rotating mode, so that real-time transmission of power is realized.

In a fourth embodiment, on the basis of the first embodiment, the clamping device includes arc-shaped clamping plates 19 disposed on two axial sides in the placing cylinder 4, two of the arc-shaped clamping plates 19 are fixedly connected with a sliding rod 20 and slidably connected to the wall of the placing cylinder 4 through the sliding rod 20, the sliding rod 20 is disposed at one end outside the placing cylinder 4 and is coaxially fixed with a compression spring 21, and the other end of the compression spring 21 is fixed on the placing cylinder 4.

When the embodiment is used, referring to fig. 6, we are connected with the arc clamping plate 19 in a sliding manner on two axial sides of the upper end of the placing cylinder 4, the arc clamping plate 19 is connected with the wall of the placing cylinder 4 through the sliding rod 20 fixedly connected with the arc clamping plate 19 in a sliding manner, when an experimenter places a test tube in the placing cylinder 4, the arc clamping plate 19 connected with the wall of the placing cylinder 4 in an axial sliding manner clamps and positions the test tube, when the experiment experimenter sets up the test tube, a friction damping sheet is fixed on the inner arc surface of the arc clamping plate 19 to increase the friction resistance between the arc clamping plate 19 and the wall of the test tube, so that when the placing cylinder 4 rotates under the driving of the micro motor, the test tube cannot move relative to the placing cylinder 4.

Fifth embodiment, on the basis of the first embodiment, a rectangular cavity 22 is integrally connected to the cover plate 12, and two longitudinal side walls in the rectangular cavity 22 are provided with sliding grooves 23 extending transversely, and the sealing device includes: vertical sliding connection has horizontal extension's slide rail 24 and horizontal sliding connection has to support clamp plate 25 between two slide rails 24 in the spout 23, support clamp plate 25 diapire rotate install with place a section of thick bamboo 4 corresponding drum 26 and drum 26 in axial sliding connection have a round bar 27, round bar 27 bottom is fixed with butt plate 28 and round bar 27 and drum 26 diapire between support the pressure spring 29 and be connected, support clamp plate 25 lower terminal surface is fixed with vertical extension's connecting rod 30 and shake even seat 2 and be equipped with actuating lever matched with jack 31, two slide rails 24 are by setting up the elevating gear drive on rectangular cavity 22.

When the embodiment is used, in an initial state, namely, when an experimenter places a test tube stored with a serum sample in the placing cylinder 4 and closes the cover plate 12, the plurality of grounding plates are positioned above the upper port of the test tube and are not in contact with the test tube, and the connecting rod 30 fixedly connected to the lower end face of the pressing plate 25 is positioned right above the jack 31; referring to fig. 7, a rectangular cavity 22 is integrally connected with a cover plate 12, sliding grooves 23 are formed in two sides of the rectangular cavity 22, sliding rails 24 are respectively and vertically and slidably connected into the corresponding sliding grooves 23, a pressing plate 25 is slidably connected between the two sliding rails 24, the lower end face of the pressing plate 25 is connected with a round rod 27 which is axially and slidably matched with a cylinder 26 through a pressing spring 29, a pressing plate 28 is fixedly connected to the bottom of the round rod 27, when shaking is needed, an experimenter controls the two sliding rails 24 to move downwards along the sliding grooves 23 through a lifting device, and the lower end face of the pressing plate 28 is pressed against an upper port of a test tube to seal the test tube, and at the moment, a connecting rod 30 fixedly connected to the pressing plate 25 is inserted into a jack 31 arranged on the shaking seat;

when the micro motor drives the shaking seat 2 to do a transverse reciprocating motion in the reagent kit 1, the pressing plate 25 is driven by the connecting rod 30 and the jack 31 which are matched with each other to synchronously perform a transverse reciprocating motion along the two slide rails 24, the pressing plate 25 and the shaking seat 2 synchronously perform a reciprocating motion in the reagent kit 1, the placing barrel 4 rotates in the placing cavity 3 at the moment, the test tube synchronously rotates along with the placing barrel 4 under the action of the two arc-shaped clamping plates 19, the cylinder 26 is driven to rotate on the pressing plate 25 because the pressing plate 28 abuts against the upper port of the test tube and the pressing plate 28 is axially and slidably connected to the cylinder 26 (the cylinder 26 is rotatably arranged on the lower end surface of the pressing plate 25), an experimenter can control the downward moving distance of the pressing plate 25 by screwing the screw 32 to further control the extrusion force of the pressing plate 28 to the upper port of the test tube (the pressing plate 28 is connected with the bottom wall of the cylinder 26 through the sliding rod 20 which, the more the abutting spring 29 is compressed, the larger the extrusion force of the abutting plate 28 to the upper port of the test tube is, so that the larger the frictional resistance between the abutting plate 28 and the upper port of the test tube is), so that the abutting plate 28 and the upper port of the test tube do not move relatively, and the real-time sealing of the test tube is realized;

it should be noted here that, since the serum sample and the enzyme conjugate are only mixed uniformly in the test tube, how fast the placing cylinder 4 rotates and how fast the shaking seat 2 reciprocates, we can control the rotation speed of the micro motor through the motor controller.

Sixth embodiment, on the basis of fifth embodiment, the lifting device includes a screw 32 rotatably installed on the bottom wall of one of the sliding grooves 23, the screw 32 is in threaded fit with the sliding rail 24, a limiting column 33 is slidably connected to the side wall of one of the sliding rails 24, the limiting column 33 is connected with the sliding rail 24 through a return spring 3737, a limiting hole 34 matched with the limiting column 33 is formed in the pressing plate 25, and one end of the pressing plate, where the limiting column 33 is matched with the limiting hole 34, is set to be a convex arc shape.

In the use of this embodiment, referring to fig. 7, a vertically extending screw 32 is rotatably installed on one of the chutes 23, when the experimenter closes the cover plate 12, the pressing plate 25 is required to be moved downward to drive the pressing plate 28 to move downward and make the lower end surface of the pressing plate 28 abut against the upper port of the test tube, at this time, the screw 32 is screwed to drive the slide rail 24 in threaded fit therewith to move vertically along the chute 23, because the two slide rails 24 are vertically and slidably connected to the chutes 23 arranged in the rectangular cavity 22, the screw 32 is screwed to drive the two slide rails 24 to move downward along the chutes 23 in threaded fit therewith, and the pressing plate 25 is driven to move downward, so as to make the lower end surface of the pressing plate 28 abut against the upper port of the test tube placed in the placing tube 4, to seal the test tube, and prevent the test tube from rotating and from making a transverse reciprocating motion in the reagent kit 1 along with the shaking seat 2, the serum sample and the enzyme conjugate in the test tube are splashed outwards;

preferably, a limiting hole 34 is arranged at the center of the other side of the pressing plate 25, as shown in fig. 9, a limiting post 33 is slidably connected to the middle position of the side wall of the slide rail 24 matching with the limiting hole 34, a return spring 37 is connected between the limiting post 33 and the side wall of the slide rail 24, when shaking is performed, the micro motor arranged at the bottom in the reagent kit 1 drives the shaking seat 2 to do a transverse reciprocating motion in the reagent kit 1 and drives the plurality of placing cylinders 4 to rotate in the placing cavity 3, when the micro motor stops working, the shaking seat 2 is stopped at the middle position of the reagent kit 1 (the micro motor is electrically connected with a motor controller, the motor controller is an integrated circuit which controls the motor to work according to the set direction, speed, angle and response time through active working, and the above effects are realized by setting parameters for the motor controller), that is, as shown in fig. 2, as the initial position is the same, the pressing plate 25 is also stopped at the middle position of the reagent kit 1 along with the shaking-up base 2, at this time, the limiting post 33 slidably connected to the middle position of the side wall of the slide rail 24 is just inserted into the limiting hole 34 arranged on the pressing plate 25 under the action of the return spring 37, so as to realize the positioning effect of the pressing plate 25, and when the cover plate 12 is punched, the pressing plate 25 slides back and forth between the two slide rails 24;

it should be noted here that when the micro motor drives the shaking seat 2 to reciprocate horizontally in the reagent kit 1, the pressing plate 25 also reciprocates between the two slide rails 24 synchronously, and when the setting is performed, the matching part of the limiting post 33 and the limiting hole 34 is set to be a convex arc shape, as shown in fig. 9, so that the pressing plate 25 can extrude the limiting post 33 out of the limiting hole 34 and cross the limiting post 33 under the driving of the micro motor.

Seventh, on the basis of the first embodiment, the bottom wall of the abutting plate 28 is fixedly provided with a damping fin.

This embodiment is when using, better, we are fixed on the butt plate 28 diapire and are provided with the damping fin, make to contradict in placing the up end of the test tube in section of thick bamboo 4 when butt plate 28 lower terminal surface, butt plate 28 produces certain holding down force to test tube upper end, make butt plate 28 and test tube up end have great frictional resistance, make to drive drum 26 and rotate around butt plate 25 through butt plate 28 with it butt when the test tube is along with placing section of thick bamboo 4 pivoted (the setting of damping fin is in order to prevent that the test tube from along with placing section of thick bamboo 4 pivoted in, produce relative movement between butt plate 28 and the test tube upper end), realize the sealed effect to the test tube.

In the eighth embodiment, on the basis of the first embodiment, a handle 35 is arranged at the upper end of the rectangular cavity 22, and a lock catch 36 matched with the cover plate 12 is fixedly arranged at one lateral side of the reagent kit 1.

When the kit is used, a handle 35 is fixed to the upper end of the rectangular cavity 22, so that the experimenter can transfer and carry the kit 1 conveniently, and a lock catch 36 is fixedly arranged at the matching position of the cover plate 12 and the kit 1, so that the cover plate 12 and the kit 1 are fixedly connected.

Compared with the kit 1 on the market, the kit 1 can uniformly mix the serum which is placed for a long time, and when a user mixes the enzyme conjugate with the serum sample, the kit 1 can fully mix the enzyme conjugate mixed together with the serum sample (antigen and antibody combined reaction), so that the reaction can be fully performed, the reliability and the accuracy of an experimental detection result are improved, and the workload of experimental workers is reduced.

In the scheme, the reagent kit 1 can seal the reagent bottle in the process of shaking the serum sample and the mixture of the serum sample and the enzyme conjugate uniformly, so that the serum sample and the enzyme conjugate in the reagent bottle are prevented from splashing out of the reagent bottle in the shaking process, and the reagent kit 1 is higher in practicability and reliability.

The above description is only for the purpose of illustration, and it should be understood that the present invention is not limited to the above embodiments, and various modifications conforming to the spirit of the present invention are within the scope of the present invention.

Claims (8)

1. The pepsinogen II detection kit comprises a kit (1) and is characterized in that a shaking seat (2) is connected in the kit (1) in a transverse sliding manner, a plurality of placing cavities (3) are arranged on the shaking seat (2), a placing barrel (4) is rotatably arranged in the placing cavity (3), the bottom of the placing barrel (4) is connected with a transmission device arranged in the shaking seat (2), a clamping device is arranged on the placing barrel (4), the transmission device is connected with a second bevel gear set (7) arranged in the shaking seat (2), the second bevel gear set (7) is connected with a telescopic shaft (6) rotatably arranged on the side wall of the shaking seat (2), the telescopic shaft (6) is connected with a first bevel gear set (5) arranged in the kit (1), the first bevel gear set (5) is driven by a micro motor (9) arranged on the bottom wall of the kit (1) through a first belt pulley set (8), shake even seat (2) diapire fixedly connected with rectangle cingulum (10) and rectangle cingulum (10) cooperation have through micro motor (9) driven semi-gear (11), the installation is rotated to kit (1) upper end is provided with apron (12) and is equipped with sealing device on apron (12).

2. The pepsinogen II detection kit as claimed in claim 1, wherein said bottom wall of said placing cylinder (4) is fixedly connected with a rotating shaft (13) and is rotatably mounted on the bottom wall of said placing cavity (3) via said rotating shaft (13), and said driving device comprises: the rotating shaft (13) is sleeved with a belt pulley (14), the belt pulley (14) is matched with a transmission belt (15), the two rotating shafts (13) close to the second bevel gear set (7) are respectively connected with a second belt pulley set (16), and the two second belt pulley sets (16) are driven by the second bevel gear set (7).

3. The pepsinogen II detection kit according to claim 1, wherein the telescopic shaft (6) comprises a transmission shaft (17) rotatably installed on the shaking seat (2) near one side wall of the first bevel gear set (5), the transmission shaft (17) is arranged in the shaking seat (2) and one end of the transmission shaft is connected with the second bevel gear set (7), and the transmission shaft (17) is arranged outside the shaking seat (2) and is axially and slidably connected with a driving shaft (18) connected with the first bevel gear set (5).

4. The pepsinogen II detection kit according to claim 1, wherein the clamping device comprises arc-shaped clamping plates (19) which are arranged on two axial sides in the placing cylinder (4), two arc-shaped clamping plates (19) are fixedly connected with a sliding rod (20) and are connected to the wall of the placing cylinder (4) in a sliding manner through the sliding rod (20), one end of the sliding rod (20) which is arranged outside the placing cylinder (4) is coaxially fixed with a compression spring (21), and the other end of the compression spring (21) is fixed on the placing cylinder (4).

5. The pepsinogen II detection kit as claimed in claim 1, wherein said cover plate (12) is integrally connected with a rectangular cavity (22) and two longitudinal side walls in the rectangular cavity (22) are provided with sliding grooves (23) extending transversely, and the sealing device comprises: vertical sliding connection has horizontal extension's slide rail (24) and between two slide rail (24) in spout (23) horizontal sliding connection has to support clamp plate (25), support clamp plate (25) diapire rotate install with place a drum (26) and drum (26) corresponding axial sliding connection have round bar (27), round bar (27) bottom is fixed with support board (28) and round bar (27) and drum (26) diapire between through supporting pressure spring (29) to be connected, support clamp plate (25) lower terminal surface is fixed with vertical extension connecting rod (30) and shake even seat (2) and be equipped with jack (31) with actuating lever matched with, two slide rail (24) are by setting up the elevating gear drive on rectangular cavity (22).

6. The pepsinogen II detection kit according to claim 5, wherein the lifting device comprises a screw rod (32) rotatably mounted on the bottom wall of one of the slide grooves (23), the screw rod (32) is in threaded fit with the slide rail (24), the side wall of one of the slide rails (24) is slidably connected with a limiting column (33), the limiting column (33) is connected with the slide rail (24) through a return spring (37), the pressing plate (25) is provided with a limiting hole (34) matched with the limiting column (33), and one end of the limiting column (33) matched with the limiting hole (34) is provided with a convex circular arc shape.

7. The pepsinogen II detection kit as claimed in claim 5, wherein a damping sheet is fixedly arranged on the bottom wall of the abutting plate (28).

8. The pepsinogen II detection kit as claimed in claim 5, wherein a handle (35) is arranged at the upper end of the rectangular cavity (22), and a lock catch (36) matched with the cover plate (12) is fixedly arranged at one lateral side of the kit (1).

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