CN113720665A - Layer gradual device for blood detection - Google Patents

Abstract

The invention relates to the field of medical treatment, in particular to a laminar gradient device for blood detection. The change of the blood gradient speed in blood detection can be realized. The test tube fixing assembly is connected with the driving assembly, the driving assembly is connected with the power assembly, the driving assembly is connected with the main body support, the power assembly is connected with the main body support, and therefore the third bevel gear and the third bevel gear are in double-meshing transmission, and an upper rotary column is enabled to restore the original steering direction; the upper end rotary column rotates and drives the fixing frame to move, then the upper end sliding column is driven to rotate through the fixing frame, then the upper end sliding column drives the fixing sleeve to move, then the test tube for blood detection clamped in the fixing sleeve is driven to move through the fixing sleeve, and then the upper end sliding column is in turnover movement, so that gradual layering of the test tube for blood detection is realized.

Description

Layer gradual device for blood detection

Technical Field

The invention relates to the field of medical treatment, in particular to a laminar gradient device for blood detection.

Background

For example, patent No. CN202021289242.4 discloses a self-cleaning blood testing machine, which includes a frame assembly, a blood testing machine main body, a mechanical arm and a cleaning assembly. The frame body assembly comprises a base and a support, the support is fixed to the surface of the base, the blood detector main body is installed on the surface of the base and is located in the support, but the technical scheme has the defect that the blood gradual-layering speed can not be changed during blood detection.

Disclosure of Invention

The invention aims to provide a blood detection layer gradient device which can change the speed of blood gradient in blood detection.

The purpose of the invention is realized by the following technical scheme:

the utility model provides a blood detects gradually device with layer, includes test tube fixed subassembly, drive assembly, power component, main part support, the fixed subassembly of test tube is connected with drive assembly, and drive assembly is connected with power component, and drive assembly is connected with the main part support, and power component is connected with the main part support.

As a further optimization of the technical scheme, the invention provides a layer gradual device for blood detection, which comprises a fixed frame, an upper end sliding column, an upper end clamping groove, an upper end sliding sleeve, a first hinged connecting rod, a fixed sleeve, a first inner end clamping rod, a second inner end clamping rod pushing spring and a first inner end clamping rod pushing spring, wherein the upper end sliding column is fixedly connected with the fixed frame, the upper end clamping groove is provided with a plurality of upper end clamping grooves, the upper end sliding sleeve is arranged on the upper end sliding column and is slidably connected with the upper end sliding column, one end of the hinged connecting rod is hinged and connected with the upper end sliding sleeve, the other end of the hinged connecting rod is hinged and connected with the fixed sleeve, the fixed sleeve is rotatably connected with the fixed frame, the first inner end clamping rod is slidably connected with the fixed sleeve, the first inner end clamping rod pushing spring is arranged between the first end clamping rod and the fixed sleeve, and the second inner end clamping rod is matched and connected with the upper end clamping groove, the inner end clamping rod II is connected with the upper end sliding sleeve in a sliding mode, and the inner end clamping rod pushing spring II is arranged between the inner end clamping rod II and the upper end sliding sleeve.

As a further optimization of the technical scheme, the invention relates to a layer gradient device for blood detection, which comprises a driving assembly, an upper end support, an upper end rotary column, a middle end driving disc, a middle end driving column, a side wall sliding chute, a clutch disc I, a driving sliding rod, a driving frame, a bevel gear shaft I, a bevel gear ring I, a bevel gear II, a bevel gear III, a matching clamping rod I, a matching clamping groove, a middle end push spring, a middle end bevel gear sliding rod, a belt I, a clutch disc II, a matching clamping rod push spring II and a matching clamping groove II, wherein the upper end rotary column is rotationally connected with the upper end support, the upper end rotary column is fixedly connected with the middle end driving disc I, the bevel gear ring I is fixedly connected with the middle end driving disc, the bevel gear II is in meshing transmission with the bevel gear ring I, the bevel gear II is rotationally connected with the upper end support, the bevel gear II is in meshing transmission with the bevel gear III, the matching clamping rod I is fixedly connected with the bevel gear, the matching clamping rod I is in matching with the clamping groove, the matching clamping groove is arranged on the middle-end driving disc, the middle-end driving column is rotationally connected with the upper-end support, the side-wall sliding groove is arranged on the middle-end driving column, the driving sliding rod is slidably connected with the side-wall sliding groove, the driving sliding rod is fixedly connected with the driving frame, the driving frame is slidably connected with the upper-end support, the driving frame is in matched connection with the middle end of the middle-end bevel-tooth sliding rod, the middle-end bevel-tooth sliding rod is in matched connection with the upper-end support, the middle-end bevel-tooth sliding rod is fixedly connected with the bevel-tooth shaft I, the bevel-tooth shaft I is slidably connected with the middle-end bevel-tooth sliding rod, the bevel-tooth shaft I is rotationally connected with the upper-end support, the bevel-tooth shaft I is fixedly connected with the bevel-tooth shaft I, the clutch disc II is rotationally connected with the upper-end support, the belt I is connected between the clutch disc II and the bevel-tooth shaft I, the matching clamping rod II is slidably connected with the clutch disc II, the matching clamping rod push spring II is arranged between the matching clamping groove II, the matching clamping groove II is formed in the clutch disc I, the clutch disc I is fixedly connected with the middle-end driving column, the fixing frame is fixedly connected with the upper-end rotating column, and the upper-end support is fixedly connected with the main body support.

As a further optimization of the technical scheme, the layer gradient device for blood detection is characterized in that the contact surface of the first bevel gear shaft and the middle-end bevel gear slide rod is non-circular.

As a further optimization of the technical scheme, the layer gradual device for blood detection comprises a power assembly, a power bottom plate, output bevel teeth, a first output bevel gear shaft, a first clutch rod, a second clutch rod, a clutch slide rod, a clutch push spring, a transmission rod, a first friction disk, a first transmission bevel gear, a second transmission bevel gear, a third transmission bevel gear, a second friction disk, a middle end friction disk, a fourth transmission bevel gear, a middle end slide frame, an input motor, a spherical clamp rod push spring and a spherical clamping groove, wherein the first output bevel gear shaft is rotatably connected with the power bottom plate, the output bevel teeth are fixedly connected with the first output bevel gear shaft, the first clutch rod is connected with the second clutch rod in a matching manner, the clutch slide rod is rotatably connected with the power bottom plate, the second clutch rod is slidably connected with the clutch slide rod, the clutch push spring is connected with the clutch slide rod in a sleeving manner, the clutch push spring is arranged between the second clutch rod and the clutch slide rod, the clutch slide rod is fixedly connected with the transmission rod, the transmission rod is rotatably connected with the power bottom plate, the transmission bevel gear II and the transmission bevel gear III are rotatably connected with the transmission rod, the transmission bevel gear I is rotatably connected with the transmission rod, the transmission bevel gear IV is rotatably connected with the transmission rod, the transmission bevel gear I is fixedly connected with the friction disk I, the transmission bevel gear IV is fixedly connected with the friction disk II, the friction disk I and the friction disk II are rotatably connected with the power bottom plate, the friction disk I and the friction disk II are in friction transmission with the middle-end friction disk, the middle-end friction disk is fixedly connected with an output shaft of an input motor, the input motor is fixedly connected with the middle-end sliding frame, the middle-end sliding frame is slidably connected with the power bottom plate, the spherical clamping groove is arranged on the power bottom plate, the spherical clamping rod is matched and connected with the spherical clamping groove, the spherical clamping rod is slidably connected with the middle-end sliding frame, the spherical clamping rod pushing spring is arranged between the spherical clamping rod and the middle-end sliding frame, and the bevel gear I is engaged and transmitted with the output bevel gear, the power bottom plate is fixedly connected with the main body bracket.

The layer gradual device for blood detection has the beneficial effects that:

according to the layer gradual device for blood detection, the driving slide rod is returned to the original position along with the driving of the side wall sliding groove, so that the first matching clamping rod is separated from the matching clamping groove, the third bevel gear and the third bevel gear are in double-meshing transmission, and the upper rotating column is returned to the original direction; the upper end rotary column rotates and drives the fixing frame to move, then the upper end sliding column is driven to rotate through the fixing frame, then the upper end sliding column drives the fixing sleeve to move, then the test tube for blood detection clamped in the fixing sleeve is driven to move through the fixing sleeve, and then the upper end sliding column is in turnover movement, so that gradual layering of the test tube for blood detection is realized.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a first general structural diagram of the present invention;

FIG. 2 is a second overall structural schematic of the present invention;

FIG. 3 is a first schematic view of the test tube holding assembly 1 of the present invention;

FIG. 4 is a schematic structural view II of the test tube holding assembly 1 of the present invention;

FIG. 5 is a third schematic view of the test tube holding assembly 1 of the present invention;

FIG. 6 is a first schematic structural diagram of the driving assembly 2 of the present invention;

FIG. 7 is a second schematic structural view of the driving assembly 2 of the present invention;

FIG. 8 is a schematic view of the structure of the drive assembly 2 of the present invention;

FIG. 9 is a fourth schematic structural view of the driving assembly 2 of the present invention;

FIG. 10 is a first schematic structural view of the power assembly 3 of the present invention;

FIG. 11 is a second schematic structural view of the power assembly 3 of the present invention;

fig. 12 is a third structural schematic diagram of the power assembly 3 of the present invention.

In the figure: a test tube fixing assembly 1; a fixed frame 1-1; an upper end sliding column 1-2; 1-3 of an upper end clamping groove; upper end sliding sleeves 1-4; 1-5 of a first hinged connecting rod; fixing the sleeve 1-6; the inner end clamping rod I is 1-7; the inner end is clamped by a second rod 1-8; a second push spring 1-9 of the inner end clamping rod; the inner end clamping rod pushes the spring 1-10; a drive assembly 2; an upper end bracket 2-1; an upper end rotary column 2-2; a middle driving disc 2-3; 2-4 of a middle driving column; 2-5 side wall chutes; 2-6 parts of a clutch disc I; driving the slide bar 2-7; 2-8 of a driving frame; 2-9 parts of a bevel gear shaft I; 2-10 parts of a first bevel gear; 2-11 parts of a bevel gear ring I; 2-12 parts of a second bevel gear; 2-13 parts of bevel gear III; 2-14 of a first matching clamping rod; 2-15 of a matching clamping groove; middle end push spring 2-16; 2-17 middle-end bevel-tooth slide bars; 2-18 parts of a first belt; 2-19 parts of a clutch plate II; 2-20 parts of a second matching clamping rod; 2-21 of a second push spring matched with the clamping rod; 2-22 of a second matching clamping groove; a power assembly 3; a power bottom plate 3-1; output bevel teeth 3-2; the output bevel gear shaft I is 3-3; 3-4 parts of a clutch lever I; 3-5 parts of a clutch lever II; 3-6 of a clutch slide bar; 3-7 of a clutch push spring; 3-8 of a transmission rod; 3-9 parts of a first friction disc; 3-10 parts of a first transmission bevel gear; 3-11 parts of a second transmission bevel gear; 3-12 parts of transmission bevel gear III; 3-13 parts of a second friction disc; 3-14 of middle friction disc; driving bevel gears four 3-15; 3-16 of a middle sliding frame; inputting motors 3-17; 3-18 parts of a spherical clamping rod; 3-19 parts of a spherical clamping rod push spring; 3-20 parts of spherical clamping groove; a main body support 4.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

The fixed connection in the device is realized by fixing in modes of welding, thread fixing and the like, and different fixing modes are used in combination with different use environments; the rotary connection means that the bearing is arranged on the shaft in a drying mode, a spring retainer ring groove is formed in the shaft or the shaft hole, and the elastic retainer ring is clamped in the retainer ring groove to achieve axial fixation of the bearing and achieve rotation; the sliding connection refers to the connection through the sliding of the sliding block in the sliding groove or the guide rail, and the sliding groove or the guide rail is generally in a step shape, so that the sliding block is prevented from falling off in the sliding groove or the guide rail; the hinge joint is a movable connection mode on connecting parts such as a hinge, a pin shaft, a short shaft and the like; the required sealing positions are sealed by sealing rings or O-shaped rings.

The first embodiment is as follows:

the present embodiment will be described with reference to fig. 1 to 12, and a layer gradient device for blood detection includes a test tube fixing assembly 1, a driving assembly 2, a power assembly 3, and a main body support 4, where the test tube fixing assembly 1 is connected to the driving assembly 2, the driving assembly 2 is connected to the power assembly 3, the driving assembly 2 is connected to the main body support 4, and the power assembly 3 is connected to the main body support 4.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1-12, and the embodiment further describes the first embodiment, where the test tube fixing assembly 1 includes a fixing frame 1-1, an upper end slide column 1-2, an upper end clamping groove 1-3, an upper end slide sleeve 1-4, a hinge connecting rod 1-5, a fixing sleeve 1-6, an inner end clamping rod 1-7, an inner end clamping rod two 1-8, an inner end clamping rod push spring two 1-9, and an inner end clamping rod push spring one 1-10, the upper end slide column 1-2 is fixedly connected to the fixing frame 1-1, the upper end clamping groove 1-3 is provided with a plurality of upper end clamping grooves 1-3, and the upper end slide sleeve 1-4 is slidably connected to the upper end slide column 1-2, one end of the hinge connecting rod 1-5 is hingedly connected to the upper end slide sleeve 1-4, the other end of the first hinged connecting rod 1-5 is hinged to the fixed sleeve 1-6, the fixed sleeve 1-6 is rotatably connected with the fixed frame 1-1, the first inner end clamping rod 1-7 is slidably connected with the fixed sleeve 1-6, the first inner end clamping rod push spring 1-10 is arranged between the first end clamping rod 1-7 and the fixed sleeve 1-6, the second inner end clamping rod 1-8 is connected with the upper end clamping groove 1-3 in a matched mode, the second inner end clamping rod 1-8 is slidably connected with the upper end sliding sleeve 1-4, and the second inner end clamping rod push spring 1-9 is arranged between the second inner end clamping rod 1-8 and the upper end sliding sleeve 1-4;

the upper end rotary column 2-2 rotates to drive the fixing frame 1-1 to move, the upper end sliding column 1-2 is driven to rotate through the fixing frame 1-1, the fixing sleeve 1-6 is driven to move through the upper end sliding column 1-2, the test tube clamped in the fixing sleeve 1-6 for blood detection is driven to move through the fixing sleeve 1-6, and then the upper end sliding column 1-2 rotates to move, so that gradual layering of the test tube for blood detection is realized, and detection is convenient.

The third concrete implementation mode:

the first embodiment is further described with reference to fig. 1-12, and the driving assembly 2 includes an upper end bracket 2-1, an upper end rotary column 2-2, a middle end driving disk 2-3, a middle end driving column 2-4, a side wall sliding slot 2-5, a clutch disc I2-6, a driving slide rod 2-7, a driving frame 2-8, a bevel gear shaft I2-9, a bevel gear I2-10, a bevel gear ring I2-11, a bevel gear II 2-12, a bevel gear III 2-13, a matching clamping rod I2-14, a matching clamping groove 2-15, a middle end push spring 2-16, a middle end bevel gear slide rod 2-17, a belt I2-18, a clutch disc II 2-19, a matching clamping rod II 2-20, and a matching clamping rod push spring II 2-21, A matching clamping groove II 2-22, the upper end rotary column 2-2 is rotationally connected with an upper end support 2-1, the upper end rotary column 2-2 is fixedly connected with a middle end driving disc 2-3, a bevel gear ring I2-11 is fixedly connected with a middle end driving disc 2-3, a bevel gear II 2-12 is in meshing transmission with the bevel gear ring I2-11, a bevel gear II 2-12 is rotationally connected with an upper end support 2-1, a bevel gear II 2-12 is in meshing transmission with a bevel gear III 2-13, a matching clamping rod I2-14 is fixedly connected with a bevel gear III 2-13, a matching clamping rod I2-14 is in matching connection with a matching clamping groove 2-15, a matching clamping groove 2-15 is arranged on the middle end driving disc 2-3, a middle end driving column 2-4 is rotationally connected with the upper end support 2-1, a side wall sliding groove 2-5 is arranged on the middle end driving column 2-4, a driving slide bar 2-7 is connected with a side wall chute 2-5 in a sliding way, a driving slide bar 2-7 is fixedly connected with a driving frame 2-8, the driving frame 2-8 is connected with an upper end bracket 2-1 in a sliding way, the driving frame 2-8 is connected with the middle end of a middle end bevel gear slide bar 2-17 in a matching way, the middle end bevel gear slide bar 2-17 is connected with an upper end bracket 2-1 in a matching way, the middle end bevel gear slide bar 2-17 is connected with a bevel gear III 2-13 in a fixed way, a bevel gear shaft I2-9 is connected with a middle end bevel gear slide bar 2-17 in a sliding way, a bevel gear shaft I2-9 is connected with the upper end bracket 2-1 in a rotating way, a bevel gear I2-10 is fixedly connected with a bevel gear shaft I2-9, a clutch disc II 2-19 is connected with the upper end bracket 2-1 in a rotating way, a belt I2-18 is connected between the clutch disc II 2-19 and the bevel gear shaft I2-9, the second matched clamping rod 2-20 is in sliding connection with the second clutch disc 2-19, the second matched clamping rod push spring 2-21 is arranged between the second matched clamping rod 2-20 and the second clutch disc 2-19, the second matched clamping rod 2-20 is in matched connection with the second matched clamping groove 2-22, the second matched clamping groove 2-22 is arranged on the first clutch disc 2-6, the first clutch disc 2-6 is fixedly connected with the middle-end driving column 2-4, the fixed frame 1-1 is fixedly connected with the upper-end rotating column 2-2, and the upper-end bracket 2-1 is fixedly connected with the main body bracket 4;

the rotation of the output bevel gear 3-2 drives the bevel gear I2-10 to move, the bevel gear shaft I2-9 is driven by the bevel gear I2-10 to move, the middle end bevel gear slide bar 2-17 is driven by the bevel gear shaft I2-9 to move, the bevel gear III 2-13 is driven by the middle end bevel gear slide bar 2-17 to move, the bevel gear II 2-12 is driven by the bevel gear III 2-13 to move, the bevel gear ring I2-11 is driven by the bevel gear II 2-12 to move, the middle end driving disc 2-3 is driven by the bevel gear ring I2-11 to rotate, the upper end rotary column 2-2 is driven by the middle end driving disc 2-3 to rotate, and the power output is facilitated.

The fourth concrete implementation mode:

the first embodiment is further explained by referring to fig. 1-12, and the contact surface between the first bevel gear shaft 2-9 and the middle bevel gear slide bar 2-17 is non-circular.

The fifth concrete implementation mode:

the first embodiment is further described with reference to fig. 1-12, the power assembly 3 includes a power bottom plate 3-1, output bevel teeth 3-2, output bevel gear shafts 3-3, clutch rods 3-4, clutch rods 3-5, clutch slide rods 3-6, clutch push springs 3-7, transmission rods 3-8, friction disks one 3-9, transmission bevel teeth one 3-10, transmission bevel teeth two 3-11, transmission bevel teeth three 3-12, friction disks two 3-13, middle end friction disks 3-14, transmission bevel teeth four 3-15, middle end slide frames 3-16, input motors 3-17, spherical clamping rods 3-18, spherical clamping rod push springs 3-19, and spherical clamping grooves 3-20, the output bevel gear shafts 3-3 are rotatably connected with the power bottom plate 3-1, the output bevel gear 3-2 is fixedly connected with the output bevel gear shaft I3-3, the clutch rod I3-4 is connected with the clutch rod II 3-5 in a matching way, the clutch slide rod 3-6 is rotatably connected with the power bottom plate 3-1, the clutch rod II 3-5 is slidably connected with the clutch slide rod 3-6, the clutch push spring 3-7 is connected with the clutch slide rod 3-6 in a sleeved way, the clutch push spring 3-7 is arranged between the clutch rod II 3-5 and the clutch slide rod 3-6, the clutch slide rod 3-6 is fixedly connected with the transmission rod 3-8, the transmission rod 3-8 is rotatably connected with the power bottom plate 3-1, the transmission bevel gear II 3-11 and the transmission bevel gear III 3-12 are rotatably connected with the transmission rod 3-8, the transmission bevel gear I3-10 is rotationally connected with the transmission rod 3-8, the transmission bevel gear IV 3-15 is rotationally connected with the transmission rod 3-8, the transmission bevel gear I3-10 is fixedly connected with the friction disk I3-9, the transmission bevel gear IV 3-15 is fixedly connected with the friction disk II 3-13, the friction disk I3-9 and the friction disk II 3-13 are rotationally connected with the power bottom plate 3-1, the friction disk I3-9 and the friction disk II 3-13 are in friction transmission with the middle end friction disk 3-14, the middle end friction disk 3-14 is fixedly connected with an output shaft of the input motor 3-17, the input motor 3-17 is fixedly connected with the middle end slide frame 3-16, the middle end slide frame 3-16 is slidably connected with the power bottom plate 3-1, and the spherical clamping groove 3-20 is arranged on the power bottom plate 3-1, the spherical clamping rods 3-18 are connected with the spherical clamping grooves 3-20 in a matched mode, the spherical clamping rods 3-18 are connected with the middle end sliding frames 3-16 in a sliding mode, the spherical clamping rod push springs 3-19 are arranged between the spherical clamping rods 3-18 and the middle end sliding frames 3-16, the first conical teeth 2-10 are in meshed transmission with the output conical teeth 3-2, and the power bottom plate 3-1 is fixedly connected with the main body support 4;

the input motor 3-17 is driven, the middle friction disk 3-14 is driven by the input motor 3-17 to move, the friction disk 3-14 and the friction disk 3-9 are driven by the middle friction disk 3-14 to move simultaneously, the transmission bevel gear 3-10 is driven by the friction disk 3-9 to move, the transmission bevel gear four 3-15 is driven by the friction disk two 3-13 to move, the transmission bevel gear two 3-11 and the transmission bevel gear three 3-12 are driven by the transmission bevel gear one 3-10 and the transmission bevel gear four 3-15 to move simultaneously, the transmission rod 3-8 is driven to move, the clutch slide rod 3-6 is driven by the transmission rod 3-8 to move, and the clutch slide rod 3-6 is driven to move the clutch slide rod two 3-5 by the clutch slide rod 3-6, and then the clutch rod I3-4 is driven to move by the clutch rod II 3-5, the bevel gear shaft I3-3 is driven to move by the clutch rod I3-4, and the output bevel gear 3-2 is driven to move by the bevel gear shaft I3-3, so that the power output is convenient.

The invention relates to a layer gradient device for blood detection, which has the working principle that:

when in use, the input motor 3-17 is started, the input motor 3-17 drives the middle friction disk 3-14 to move, the middle friction disk 3-14 drives the friction disk one 3-9 and the friction disk two 3-13 to move simultaneously, the friction disk one 3-9 drives the transmission bevel gear one 3-10 to move, the friction disk two 3-13 drives the transmission bevel gear four 3-15 to move, the transmission bevel gear one 3-10 and the transmission bevel gear four 3-15 drive the transmission bevel gear two 3-11 and the transmission bevel gear three 3-12 to move simultaneously, the transmission rod 3-8 is driven to move, the transmission rod 3-8 drives the clutch slide rod 3-6 to move, and the clutch slide rod 3-6 drives the clutch rod two 3-5 to move, the clutch rod I3-4 is driven to move by the clutch rod II 3-5, the bevel gear shaft I3-3 is driven to move by the clutch rod I3-4, and the output bevel gear 3-2 is driven to move by the bevel gear shaft I3-3, so that power output is facilitated; simultaneously, the middle end sliding frame 3-16 slides along the power bottom plate 3-1, the position of the input motor 3-17 is adjusted through the middle end sliding frame 3-16, the use position of the middle end friction disc 3-14 is changed, the difference value between the contact position of the friction disc I3-9 and the friction disc II 3-13 and the contact position of the middle end friction disc 3-14 is changed, and the output speed through the output bevel gear 3-2 is changed; meanwhile, the middle end sliding frames 3-16 are positioned by matching and connecting the spherical clamping rods 3-18 and the spherical clamping grooves 3-20; the rotation of the output bevel gear 3-2 drives the bevel gear I2-10 to move, further drives the bevel gear shaft I2-9 to move through the bevel gear I2-10, further drives the middle bevel gear slide bar 2-17 to move through the bevel gear shaft I2-9, further drives the bevel gear III 2-13 to move through the middle bevel gear slide bar 2-17, further drives the bevel gear II 2-12 to move through the bevel gear III 2-13, further drives the bevel gear ring I2-11 to move through the bevel gear ring I2-11, further drives the middle end drive disk 2-3 to rotate through the bevel gear ring I2-11, further drives the upper end rotary column 2-2 to rotate through the middle end drive disk 2-3, further facilitates the power output, and simultaneously, drives the belt I2-18 to move through the bevel gear shaft I2-9, then the belt I2-18 drives the clutch disc II 2-19 to move, further the clutch disc II 2-19 drives the matching clamping rod II 2-20 to move, further the matching clamping rod II 2-20 drives the matching clamping groove II 2-22 to move, further the matching clamping groove II 2-22 drives the clutch disc I2-6 to move, further the clutch disc I2-6 drives the middle driving post 2-4 to rotate, further the middle driving post 2-4 drives the side wall sliding groove 2-5 to move, further the side wall sliding groove 2-5 drives the driving slide bar 2-7 to move, further the driving slide bar 2-7 drives the driving frame 2-8 to move, further the driving frame 2-8 drives the driving slide bar 2-7 to move, further the driving slide bar 2-7 drives the bevel gear III 2-13 to move, further separating the third bevel gear 2-13 from the second bevel gear 2-12, further connecting the first matching clamping rod 2-14 with the matching clamping groove 2-15 in a matching manner, further driving the middle driving disc 2-3 to rotate through the matching clamping groove 2-15, enabling the upper rotating column 2-2 to rotate reversely, meanwhile, enabling the driving slide rod 2-7 to return to the original position along with the driving of the side wall sliding groove 2-5, further separating the first matching clamping rod 2-14 from the matching clamping groove 2-15, further enabling the third bevel gear 2-13 and the second bevel gear 2-12 to be in meshing transmission again, and further enabling the upper rotating column 2-2 to return to the original rotation direction; the upper end rotary column 2-2 rotates to drive the fixed frame 1-1 to move, the upper end sliding column 1-2 is driven to rotate by the fixed frame 1-1, the fixed sleeve 1-6 is driven to move by the upper end sliding column 1-2, the test tube for blood detection clamped in the fixed sleeve 1-6 is driven to move by the fixed sleeve 1-6, and the test tube for blood detection is gradually layered by the upper end sliding column 1-2 in a circulating manner, so that the detection is convenient; through the reciprocating turnover motion of the upper end rotary column 2-2, the upper end sliding column 1-2 is further made to reciprocate, and the gradual layer of the test tube for blood detection is further accelerated.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (5)

1. The utility model provides a blood detects gradually device with layer, includes test tube fixed subassembly (1), drive assembly (2), power component (3), main part support (4), its characterized in that: the test tube fixing assembly (1) is connected with the driving assembly (2), the driving assembly (2) is connected with the power assembly (3), the driving assembly (2) is connected with the main body support (4), and the power assembly (3) is connected with the main body support (4).

2. The layer-gradient device for blood test according to claim 1, wherein: the test tube fixing component (1) comprises a fixing frame (1-1), an upper end sliding column (1-2), an upper end clamping groove (1-3), an upper end sliding sleeve (1-4), a hinged connecting rod I (1-5), a fixing sleeve (1-6), an inner end clamping rod I (1-7), an inner end clamping rod II (1-8), an inner end clamping rod push spring II (1-9) and an inner end clamping rod push spring I (1-10), wherein the upper end sliding column (1-2) is fixedly connected with the fixing frame (1-1), a plurality of upper end clamping grooves (1-3) are arranged, the plurality of upper end clamping grooves (1-3) are all arranged on the upper end sliding column (1-2), the upper end sliding sleeve (1-4) is slidably connected with the upper end sliding column (1-2), one end of the hinged connecting rod I (1-5) is hinged to the upper end sliding sleeve (1-4), the other end of the hinged connecting rod I (1-5) is hinged to a fixed sleeve (1-6), the fixed sleeve (1-6) is rotatably connected with the fixed frame (1-1), the inner end clamping rod I (1-7) is connected with the fixed sleeve (1-6) in a sliding mode, the inner end clamping rod push spring I (1-10) is arranged between the end clamping rod I (1-7) and the fixed sleeve (1-6), the inner end clamping rod II (1-8) is connected with the upper end clamping groove (1-3) in a matching mode, the inner end clamping rod II (1-8) is connected with the upper end sliding sleeve (1-4) in a sliding mode, and the inner end clamping rod push spring II (1-9) is arranged between the inner end clamping rod II (1-8) and the upper end sliding sleeve (1-4).

3. The layer-gradient device for blood test according to claim 1, wherein: the driving assembly (2) comprises an upper end support (2-1), an upper end rotating column (2-2), a middle end driving disc (2-3), a middle end driving column (2-4), a side wall sliding groove (2-5), a clutch disc I (2-6), a driving sliding rod (2-7), a driving frame (2-8), a bevel gear shaft I (2-9), a bevel gear I (2-10), a bevel gear I (2-11), a bevel gear II (2-12), a bevel gear III (2-13), a matching clamping rod I (2-14), a matching clamping groove (2-15), a middle end pushing spring (2-16), a middle end bevel gear sliding rod (2-17), a belt I (2-18), a clutch disc II (2-19), a matching clamping rod II (2-20), and a matching clamping rod pushing spring II (2-21), The upper end rotary column (2-2) is rotatably connected with the upper end support (2-1), the upper end rotary column (2-2) is fixedly connected with the middle end driving disk (2-3), the bevel gear ring (2-11) is fixedly connected with the middle end driving disk (2-3), the bevel gear ring (2-12) is in meshing transmission with the bevel gear ring (2-11), the bevel gear ring (2-12) is rotatably connected with the upper end support (2-1), the bevel gear ring (2-12) is in meshing transmission with the bevel gear ring (2-13), the matching clamping rod (2-14) is fixedly connected with the bevel gear ring (2-13), the matching clamping rod (2-14) is in matching connection with the matching clamping groove (2-15), and the matching clamping groove (2-15) is arranged on the middle end driving disk (2-3), a middle-end driving column (2-4) is rotationally connected with an upper-end support (2-1), a side-wall sliding groove (2-5) is arranged on the middle-end driving column (2-4), a driving sliding rod (2-7) is in sliding connection with the side-wall sliding groove (2-5), the driving sliding rod (2-7) is fixedly connected with a driving frame (2-8), the driving frame (2-8) is in sliding connection with the upper-end support (2-1), the driving frame (2-8) is in matching connection with the middle end of a middle-end conical tooth sliding rod (2-17), the middle-end conical tooth sliding rod (2-17) is in matching connection with the upper-end support (2-1), the middle-end conical tooth sliding rod (2-17) is fixedly connected with a conical tooth third (2-13), a conical tooth shaft I (2-9) is in sliding connection with the middle-end conical tooth sliding rod (2-17), a first bevel gear shaft (2-9) is rotationally connected with an upper end bracket (2-1), a first bevel gear (2-10) is fixedly connected with the first bevel gear shaft (2-9), a second clutch disc (2-19) is rotationally connected with the upper end bracket (2-1), a first belt (2-18) is connected between the second clutch disc (2-19) and the first bevel gear shaft (2-9), a second matching clamping rod (2-20) is in sliding connection with the second clutch disc (2-19), a second matching clamping rod pushing spring (2-21) is arranged between the second matching clamping rod (2-20) and the second clutch disc (2-19), the second matching clamping rod (2-20) is in matching connection with the second matching clamping groove (2-22), the second matching clamping groove (2-22) is arranged on the first clutch disc (2-6), and the first clutch disc (2-6) is fixedly connected with a middle end driving column (2-4), the fixed mount (1-1) is fixedly connected with the upper end rotary column (2-2), and the upper end support (2-1) is fixedly connected with the main body support (4).

4. The gradation device for blood test according to claim 3, wherein: the contact surface between the first bevel gear shaft (2-9) and the middle-end bevel gear sliding rod (2-17) is non-circular.

5. The layer-gradient device for blood test according to claim 1, wherein: the power component (3) comprises a power bottom plate (3-1), output bevel gears (3-2), a first output bevel gear shaft (3-3), a first clutch rod (3-4), a second clutch rod (3-5), a clutch slide rod (3-6), a clutch push spring (3-7), a transmission rod (3-8), a first friction disc (3-9), a first transmission bevel gear (3-10), a second transmission bevel gear (3-11), a third transmission bevel gear (3-12), a second friction disc (3-13), a middle-end friction disc (3-14), a fourth transmission bevel gear (3-15), a middle-end sliding frame (3-16), an input motor (3-17), spherical clamping rods (3-18), spherical clamping rod push springs (3-19) and spherical clamping grooves (3-20), the output bevel gear shaft I (3-3) is rotationally connected with the power bottom plate (3-1), the output bevel gear (3-2) is fixedly connected with the output bevel gear shaft I (3-3), the clutch rod I (3-4) is connected with the clutch rod II (3-5) in a matching way, the clutch slide rod (3-6) is rotationally connected with the power bottom plate (3-1), the clutch rod II (3-5) is connected with the clutch slide rod (3-6) in a sliding way, the clutch push spring (3-7) is connected with the clutch slide rod (3-6) in a sleeved way, the clutch push spring (3-7) is arranged between the clutch rod II (3-5) and the clutch slide rod (3-6), the clutch slide rod (3-6) is fixedly connected with the transmission rod (3-8), the transmission rod (3-8) is rotationally connected with the power bottom plate (3-1), the transmission bevel gear II (3-11) and the transmission bevel gear III (3-12) are rotationally connected with the transmission rod (3-8), the transmission bevel gear I (3-10) is rotationally connected with the transmission rod (3-8), the transmission bevel gear IV (3-15) is rotationally connected with the transmission rod (3-8), the transmission bevel gear I (3-10) is fixedly connected with the friction disc I (3-9), the transmission bevel gear IV (3-15) is fixedly connected with the friction disc II (3-13), the friction disc I (3-9) and the friction disc II (3-13) are rotationally connected with the power bottom plate (3-1), the friction disc I (3-9) and the friction disc II (3-13) are in friction transmission with the middle friction disc (3-14), the middle friction disc (3-14) is fixedly connected with an output shaft of the input motor (3-17), the input motor (3-17) is fixedly connected with the middle sliding frame (3-16), the middle sliding frame (3-16) is slidably connected with the power bottom plate (3-1), the spherical clamping groove (3-20) is formed in the power bottom plate (3-1), the spherical clamping rod (3-18) is connected with the spherical clamping groove (3-20) in a matched mode, the spherical clamping rod (3-18) is slidably connected with the middle sliding frame (3-16), the spherical clamping rod push spring (3-19) is arranged between the spherical clamping rod (3-18) and the middle sliding frame (3-16), the first conical tooth (2-10) is in meshing transmission with the output conical tooth (3-2), and the power bottom plate (3-1) is fixedly connected with the main body support (4).

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