CN205594021U - Full -automatic specific protein analyzer's vertical movement mechanism - Google Patents

Abstract

The utility model relates to a protein analyzer technical field, concretely relates to full -automatic specific protein analyzer's vertical movement mechanism, two of mutual parallel arrangement that locate two backup pads upper ends including two backup pads of mutual parallel arrangement, respectively indulge and move the slide rail, move indulging of slide rail sliding connection and move the sliding seat and be used for the drive to indulge and move gliding the indulging of sliding seat and move actuating mechanism with indulging. This vertical movement mechanism can drive sampling device automatically and accomplish sample presentation work, and the sample presentation is efficient.

Description

A kind of longitudinal moving mechanism of full-automatic specific protein analyser

Technical field

This utility model relates to protein analyzer technical field, is specifically related to the longitudinal moving mechanism of a kind of full-automatic specific protein analyser.

Background technology

nullSpecific protein analyser is mainly used in each laboratory and detects the various albumen in specimen，As detected venous whole、Peripheral blood、Blood plasma、Serum、Urine、Cerebrospinal fluid、Multiple specific protein in saliva，Including: immune globulin、LgG subclass、Complement、C reactive protein (CRP)、Antistreptolysin O (ASO)、Rheumatoid factor (RF)、Glycolated hemoglobin (HbA1c)、Albumin (ALB)、Microdose urine protein (MAB)、κ light chain and lambda light chain、Ceruloplasmin (CER)、Hoptoglobin (HPT)、Light railway albumen (TRF)、C1 inactivation factor (C1IN)、Alpha1 Anti-trypsin (AAT)、Prealbumin、Serum and urinal beta2 microglobulin (BMG)、Apolipoprotein (APO)、Antithrombin Ⅲ (AT3)、α 1 acidoglycoprotein (AAG)、Alpha2 Macroglobulin (AMG) etc..By detecting increasing or lowering of these albumen, the diagnosis to doctor has highly important clinical meaning.Specific protein analyser accuracy is high, reproducible, and the most single sample or great amount of samples all can detect at any time, go out result immediately.But the sample loading alternative that existing specific protein analyser uses when sample carries out sample-adding detection is to first pass through manual sampling, manually sample is delivered to sample mix or detection region again, use such sample presentation mode, need to spend substantial amounts of manpower and materials, also detection process is made to become slow, when great amount of samples needs detection, sample presentation process can be wasted the substantial amounts of time, can be had a strong impact on detection speed.

Summary of the invention

In order to overcome shortcoming and defect present in prior art, the purpose of this utility model is to provide the longitudinal moving mechanism of a kind of full-automatic specific protein analyser, this longitudinal moving mechanism can automatically drive sampler to complete sample presentation work, and sample presentation efficiency is high.

The purpose of this utility model is achieved through the following technical solutions: the longitudinal moving mechanism of a kind of full-automatic specific protein analyser, including two pieces of gripper shoes arranged in parallel, is respectively arranged on vertical shift sliding seat that arranged in parallel two the vertical shift slide rail of two pieces of gripper shoe upper ends is slidably connected with vertical shift slide rail and for the vertical shift drive mechanism driving vertical shift sliding seat to slide.

Wherein, described vertical shift drive mechanism includes vertical shift motor and the vertical shift driven shaft being located therein one piece of gripper shoe, being respectively arranged on the outfan of vertical shift motor and two vertical shift gears of the end of vertical shift driven shaft, be engaged in the vertical shift cingulum of two vertical shift gears, vertical shift cingulum and corresponding vertical shift sliding seat connect；This longitudinal moving mechanism also includes the sampler for sampling, for driving sampler to move in transverse direction and being installed in the horizontal mobile device of vertical shift sliding seat.

Wherein, the top of described gripper shoe is provided with two pieces of spacing block sets, and vertical shift slide rail is located between two pieces of spacing block sets.

Wherein, described vertical shift sliding seat offers the vertical shift through hole arranged along the longitudinal direction, and described vertical shift slide rail is sheathed in vertical shift through hole, is arranged with the wear-resisting body of vertical shift between vertical shift through hole and vertical shift slide rail.

Wherein, the surface of the wear-resisting body of described vertical shift offers spacing draw-in groove, is provided with the annular protrusion matched with spacing draw-in groove in vertical shift through hole.

Wherein, being provided with L-type contiguous block between described vertical shift sliding seat and vertical shift cingulum, the top of L-type contiguous block is connected with vertical shift sliding seat, and the bottom of L-type contiguous block offers vertical shift clip slot, and vertical shift cingulum is connected through vertical shift clip slot with L-type contiguous block.

Wherein, described L-type contiguous block offers at least two locking screw pit, the built-in clamping screw that is provided with of locking screw pit, and the front end face of clamping screw abuts with described vertical shift cingulum.

Wherein, described sampler includes being located at the sampling substrate of described horizontal mobile device, the probe tube being located at sampling substrate and puddler and for the sampling drive mechanism driving probe tube and puddler to move up and down；Described sampling drive mechanism includes the sampling motor being respectively arranged on described sampling substrate top and bottom and sampling driven shaft and for the sampling cingulum driving probe tube and puddler to move up and down, the outfan of sampling motor and the end of sampling driven shaft connect sampling gear, and sampling cingulum is engaged on sampling gear；Described sampler also includes sampling slide rail and the stirring slide rail being located at sampling substrate, sampling slide rail and stirring slide rail are arranged in parallel, sampling slide rail slidably connects sampling slide block, the side of described sampling cingulum is connected with sampling slide block, described probe tube is installed in sampling slide block, stirring slide rail slidably connects stirring slide block, and the opposite side of sampling cingulum is connected with stirring slide block, and described puddler is installed in stirring slide block.

Wherein, it is provided with positioning slide between described sampling slide rail and stirring slide rail, positioning slide is parallel with sampling slide rail, the right side opening of described sampling slide block is provided with sampling arc groove, the left side of described stirring slide block offers stirring arc groove, sampling arc groove and stirring arc groove and all abuts with the surface of positioning slide；Described sampling slide block offers sampling clip slot, and described sampling cingulum is connected through sampling clip slot with sampling slide block；Described stirring slide block offers stirring clip slot, and sampling cingulum is connected through stirring clip slot with stirring slide block；The upper surface of described sampling slide block offers sampling groove, offers sampling installing hole, be equiped with sampling latch segment in sampling groove in sampling groove, and the lower end of probe tube from top to bottom sequentially passes through sampling latch segment and sampling installing hole removably connects with sampling slide block.

Wherein, the upper surface of described stirring slide block offers stirring groove, offering stirring installing hole in stirring groove, be equiped with stirring latch segment in stirring groove, the lower end of puddler from top to bottom sequentially passes through stirring latch segment and stirring installing hole removably connects with stirring slide block；The upper end of described probe tube connects suction pipe；The both sides of described sampling substrate are equipped with rib, and rib is vertically arranged with sampling substrate, and the surface of rib offers multiple rib through hole.

Of the present utility model actually used during, after sampler completes sampling, start horizontal mobile device and drive sampler transverse shifting, arrival specific bit postpones, starting vertical shift drive mechanism drives vertical shift sliding seat to move along the longitudinal direction, vertical shift sliding seat drives horizontal mobile device and sampler to arrive sample addition region simultaneously, and sample is joined sample and adds region, completes sample presentation by sampler.

The beneficial effects of the utility model are: this utility model drives vertical shift sliding seat to move along the longitudinal direction by vertical shift drive mechanism automatically, and drive sampler to move along the longitudinal direction by vertical shift sliding seat, completing the sample presentation gone up the along the longitudinal direction work of sample, the shortest, sample presentation efficiency is high.

Accompanying drawing explanation

Fig. 1 is axonometric chart of the present utility model.

Fig. 2 is decomposing schematic representation of the present utility model.

Fig. 3 is the decomposing schematic representation of sampler of the present utility model.

Reference is: 1 gripper shoe, 2 vertical shift slide rails, 3 vertical shift sliding seats, 4 vertical shift motors, 5 vertical shift cingulums, 6 horizontal mobile devices, 7 spacing block sets, the 8 wear-resisting bodies of vertical shift, 9 spacing draw-in grooves, 10 L-type contiguous blocks, 11 samplers, 12 sampling substrates, 13 probe tubes, 14 puddlers, 15 sampling motors, 16 sampling cingulums, 17 sampling slide rails, 18 stirring slide rails, 19 sampling slide blocks, 20 sampling arc grooves, 21 stirring slide blocks, 22 stirring arc grooves, 23 positioning slides, 24 sampling grooves, 25 sampling latch segments, 26 stirring grooves, 27 stirring latch segments, 28 suction pipes, 29 ribs.

Detailed description of the invention

For the ease of the understanding of those skilled in the art, being further described this utility model below in conjunction with embodiment and accompanying drawing 1-Fig. 3, the content that embodiment is mentioned is not to restriction of the present utility model.

See Fig. 1-Fig. 3, the longitudinal moving mechanism of a kind of full-automatic specific protein analyser, including two pieces of gripper shoes 1 arranged in parallel, is respectively arranged on vertical shift sliding seat 3 that arranged in parallel two the vertical shift slide rail 2 of two pieces of gripper shoe 1 upper ends is slidably connected with vertical shift slide rail 2 and for the vertical shift drive mechanism driving vertical shift sliding seat 3 to slide.

This utility model drives vertical shift sliding seat 3 to move along the longitudinal direction by vertical shift drive mechanism automatically, and drives sampler 11 to move along the longitudinal direction by vertical shift sliding seat 3, completes the sample presentation gone up the along the longitudinal direction work of sample, and the shortest, sample presentation efficiency is high.

Wherein, described vertical shift drive mechanism includes vertical shift motor 4 and the vertical shift driven shaft being located therein one piece of gripper shoe 1, being respectively arranged on the outfan of vertical shift motor 4 and two vertical shift gears of the end of vertical shift driven shaft, be engaged in the vertical shift cingulum 5 of two vertical shift gears, vertical shift cingulum 5 connects with corresponding vertical shift sliding seat 3；This longitudinal moving mechanism also includes the sampler 11 for sampling, for driving sampler 11 to move in transverse direction and being installed in the horizontal mobile device 6 of vertical shift sliding seat 3.Specifically, it is arranged with vertical shift bearing between end and the vertical shift gear of vertical shift driven shaft.Drive vertical shift cingulum 5 to move by vertical shift motor 4, then drive vertical shift sliding seat 3 to move by vertical shift cingulum 5, thus realize the vertical shift of the horizontal mobile device 6 being installed on vertical shift sliding seat 3, and then drive sampler 11 vertical shift, completing longitudinal sample presentation work, automaticity is high, and sample presentation efficiency is high；Use vertical shift motor 4 as power set, it is simple to control the stroke of vertical shift；Using vertical shift cingulum 5 to drive the vertical shift sliding seat 3 motion belt that compares to have more preferable transmission promptness, the control accuracy of stroke is high.

Wherein, the top of described gripper shoe 1 is provided with two pieces of spacing block sets 7, and vertical shift slide rail 2 is located between two pieces of spacing block sets 7.Spacing block set 7 plays the effect of the range limiting vertical shift sliding seat 3.

Wherein, described vertical shift sliding seat 3 offers the vertical shift through hole arranged along the longitudinal direction, and described vertical shift slide rail 2 is sheathed in vertical shift through hole, is arranged with the wear-resisting body of vertical shift 8 between vertical shift through hole and vertical shift slide rail 2.The setting of the wear-resisting body of vertical shift 8 can be effectively prevented from vertical shift sliding seat 3 and be worn and damage the dimensional stability of vertical shift sliding seat 3.

Wherein, the surface of the wear-resisting body of described vertical shift 8 offers spacing draw-in groove 9, is provided with the annular protrusion matched with spacing draw-in groove 9 in vertical shift through hole.Using spacing draw-in groove 9 and the wear-resisting body of annular protrusion location and installation vertical shift 8, the connective stability of the wear-resisting body of vertical shift 8 and vertical shift sliding seat 3 is good, is difficult to loosen.

Wherein, being provided with L-type contiguous block 10 between described vertical shift sliding seat 3 and vertical shift cingulum 5, the top of L-type contiguous block 10 is connected with vertical shift sliding seat 3, and the bottom of L-type contiguous block 10 offers vertical shift clip slot, and vertical shift cingulum 5 is connected through vertical shift clip slot with L-type contiguous block 10.L-type contiguous block 10 is connected by vertical shift clip slot with vertical shift cingulum 5, and connective stability is good, is difficult to loosen.

Wherein, described L-type contiguous block 10 offers at least two locking screw pit, the built-in clamping screw that is provided with of locking screw pit, and the front end face of clamping screw abuts with described vertical shift cingulum 5.Locking vertical shift cingulum 5 by clamping screw, vertical shift cingulum 5 is good with the connective stability of L-type contiguous block 10, is difficult to loosen, and dismounting and change vertical shift cingulum 5 is efficient and convenient.

Wherein, described sampler 11 includes being located at the sampling substrate 12 of described horizontal mobile device 6, the probe tube 13 being located at sampling substrate 12 and puddler 14 and for the sampling drive mechanism driving probe tube 13 and puddler 14 to move up and down；Described sampling drive mechanism includes the sampling motor 15 being respectively arranged on described sampling substrate 12 top and bottom and sampling driven shaft and for the sampling cingulum 16 driving probe tube 13 and puddler 14 to move up and down, the outfan of sampling motor 15 and the end of sampling driven shaft connect sampling gear, and sampling cingulum 16 is engaged on sampling gear；Described sampler 11 also includes sampling slide rail 17 and the stirring slide rail 18 being located at sampling substrate 12, sampling slide rail 17 and stirring slide rail 18 are arranged in parallel, sampling slide rail 17 slidably connects sampling slide block 19, the side of described sampling cingulum 16 is connected with sampling slide block 19, described probe tube 13 is installed in sampling slide block 19, stirring slide rail 18 slidably connects stirring slide block 21, and the opposite side of sampling cingulum 16 is connected with stirring slide block 21, and described puddler is installed in stirring slide block 21.Specifically, it is arranged with sampling bearing between end and the sampling gear of sampling driven shaft.This utility model drives probe tube 13 and puddler 14 to complete sampling and stirring work by sampling cingulum 16, probe tube 13 and puddler 14 is driven to work respectively without setting up two bar sampling cingulums 16 separately, simple in construction, it is beneficial to the Miniaturization Design of protein analyzer, and sample and stirring automation mechanized operation, work efficiency is high；

Wherein, it is provided with positioning slide 23 between described sampling slide rail 17 and stirring slide rail 18, positioning slide 23 is parallel with sampling slide rail 17, the right side opening of described sampling slide block 19 is provided with sampling arc groove 20, the left side of described stirring slide block 21 offers stirring arc groove 22, sampling arc groove 20 and stirring arc groove 22 surface all with positioning slide 23 and abuts；Described sampling slide block 19 offers sampling clip slot, and described sampling cingulum 16 is connected through sampling clip slot with sampling slide block 19；Described stirring slide block 21 offers stirring clip slot, and sampling cingulum 16 is connected through stirring clip slot with stirring slide block 21；The upper surface of described sampling slide block 19 offers sampling groove 24, sampling installing hole is offered in sampling groove 24, being equiped with sampling latch segment 25 in sampling groove 24, the lower end of probe tube 13 from top to bottom sequentially passes through sampling latch segment 25 and sampling installing hole removably connects with sampling slide block 19.By positioning slide 23 location sampling slide block 19 and stirring slide block 21, sampling slide block 19 and the good stability of stirring slide block 21, will not shake；Sampling slide block 19 and stirring slide block 21 are connected with sampling cingulum 16 by sampling clip slot and stirring clip slot respectively, and connective stability is good.

Wherein, the upper surface of described stirring slide block 21 offers stirring groove 26, stirring installing hole is offered in stirring groove 26, being equiped with stirring latch segment 27 in stirring groove 26, the lower end of puddler 14 from top to bottom sequentially passes through stirring latch segment 27 and stirring installing hole removably connects with stirring slide block 21；The upper end of described probe tube 13 connects suction pipe 28；The both sides of described sampling substrate 12 are equipped with rib 29, and rib 29 is vertically arranged with sampling substrate 12, and the surface of rib 29 offers multiple rib 29 through hole.Fixedly mounting puddler 14 by stirring latch segment 27, the mounting stability of puddler 14 is good, is difficult to loosen, and puddler 14 removably connects with stirring slide block 21, it is simple to change puddler 14；The setting of rib 29 can protect the miscellaneous part of sampling mechanism well, it is to avoid damages, and rib 29 through hole can be as standby hole, it is simple to be connected with miscellaneous part.

Above-described embodiment is this utility model preferably implementation, and in addition, this utility model can realize with alternate manner, and the most any obvious replacement is all within protection domain of the present utility model.

Claims (10)

1. the longitudinal moving mechanism of a full-automatic specific protein analyser, it is characterised in that: include arranged in parallel two piece gripper shoe, be respectively arranged on vertical shift sliding seat that arranged in parallel two the vertical shift slide rail of two pieces of gripper shoe upper ends is slidably connected with vertical shift slide rail and for the vertical shift drive mechanism driving vertical shift sliding seat to slide.

The longitudinal moving mechanism of a kind of full-automatic specific protein analyser the most according to claim 1, it is characterized in that: described vertical shift drive mechanism includes being located therein vertical shift motor and the vertical shift driven shaft of one piece of gripper shoe, being respectively arranged on the outfan of vertical shift motor and two vertical shift gears of the end of vertical shift driven shaft, be engaged in the vertical shift cingulum of two vertical shift gears, vertical shift cingulum and corresponding vertical shift sliding seat connect；This longitudinal moving mechanism also includes the sampler for sampling, for driving sampler to move in transverse direction and being installed in the horizontal mobile device of vertical shift sliding seat.

The longitudinal moving mechanism of a kind of full-automatic specific protein analyser the most according to claim 1, it is characterised in that: the top of described gripper shoe is provided with two pieces of spacing block sets, and vertical shift slide rail is located between two pieces of spacing block sets.

The longitudinal moving mechanism of a kind of full-automatic specific protein analyser the most according to claim 1, it is characterized in that: described vertical shift sliding seat offers the vertical shift through hole arranged along the longitudinal direction, described vertical shift slide rail is sheathed in vertical shift through hole, is arranged with the wear-resisting body of vertical shift between vertical shift through hole and vertical shift slide rail.

The longitudinal moving mechanism of a kind of full-automatic specific protein analyser the most according to claim 4, it is characterised in that: the surface of the wear-resisting body of described vertical shift offers spacing draw-in groove, is provided with the annular protrusion matched with spacing draw-in groove in vertical shift through hole.

The longitudinal moving mechanism of a kind of full-automatic specific protein analyser the most according to claim 2, it is characterized in that: between described vertical shift sliding seat and vertical shift cingulum, be provided with L-type contiguous block, the top of L-type contiguous block is connected with vertical shift sliding seat, the bottom of L-type contiguous block offers vertical shift clip slot, and vertical shift cingulum is connected through vertical shift clip slot with L-type contiguous block.

The longitudinal moving mechanism of a kind of full-automatic specific protein analyser the most according to claim 6, it is characterized in that: described L-type contiguous block offers at least two locking screw pit, the built-in clamping screw that is provided with of locking screw pit, the front end face of clamping screw abuts with described vertical shift cingulum.

The longitudinal moving mechanism of a kind of full-automatic specific protein analyser the most according to claim 2, it is characterised in that: described sampler includes being located at the sampling substrate of described horizontal mobile device, the probe tube being located at sampling substrate and puddler and for the sampling drive mechanism driving probe tube and puddler to move up and down；Described sampling drive mechanism includes the sampling motor being respectively arranged on described sampling substrate top and bottom and sampling driven shaft and for the sampling cingulum driving probe tube and puddler to move up and down, the outfan of sampling motor and the end of sampling driven shaft connect sampling gear, and sampling cingulum is engaged on sampling gear；Described sampler also includes sampling slide rail and the stirring slide rail being located at sampling substrate, sampling slide rail and stirring slide rail are arranged in parallel, sampling slide rail slidably connects sampling slide block, the side of described sampling cingulum is connected with sampling slide block, described probe tube is installed in sampling slide block, stirring slide rail slidably connects stirring slide block, and the opposite side of sampling cingulum is connected with stirring slide block, and described puddler is installed in stirring slide block.

The longitudinal moving mechanism of a kind of full-automatic specific protein analyser the most according to claim 8, it is characterized in that: between described sampling slide rail and stirring slide rail, be provided with positioning slide, positioning slide is parallel with sampling slide rail, the right side opening of described sampling slide block is provided with sampling arc groove, the left side of described stirring slide block offers stirring arc groove, sampling arc groove and stirring arc groove and all abuts with the surface of positioning slide；Described sampling slide block offers sampling clip slot, and described sampling cingulum is connected through sampling clip slot with sampling slide block；Described stirring slide block offers stirring clip slot, and sampling cingulum is connected through stirring clip slot with stirring slide block；The upper surface of described sampling slide block offers sampling groove, offers sampling installing hole, be equiped with sampling latch segment in sampling groove in sampling groove, and the lower end of probe tube from top to bottom sequentially passes through sampling latch segment and sampling installing hole removably connects with sampling slide block.

The longitudinal moving mechanism of a kind of full-automatic specific protein analyser the most according to claim 8, it is characterized in that: the upper surface of described stirring slide block offers stirring groove, stirring installing hole is offered in stirring groove, being equiped with stirring latch segment in stirring groove, the lower end of puddler from top to bottom sequentially passes through stirring latch segment and stirring installing hole removably connects with stirring slide block；The upper end of described probe tube connects suction pipe；The both sides of described sampling substrate are equipped with rib, and rib is vertically arranged with sampling substrate, and the surface of rib offers multiple rib through hole.