CN203981539U - A kind of blood viscoelastic power monitoring device - Google Patents

Abstract

The utility model discloses a kind of blood viscoelastic power monitoring device, comprise back up pad, detection agency, concussion mechanism and survey cup, in described detection agency, be provided with generating laser and angular displacement sensor, on probe, be provided with minute surface; Described concussion mechanism comprises guide rod, change, drive unit, glass stand and cup chamber; The described cup of surveying comprises a glass body, cup head and is embedded at the pouring weight in described cup head; Described detection agency outer cover is equipped with rolling bearing, and described change is anchored on described rolling bearing.The blood viscoelastic power monitoring device that the utility model provides, carries out rule concussion by concussion mechanism to the blood sample of surveying in cup, with thrombotic physiological environment in analogue body; By optical lever method, detect and substitute traditional electromagnetic measurement method, measuring accuracy and sensitivity are significantly improved; This apparatus structure is simple and practical, mechanism's friction is little, probe positioning is accurate, measuring accuracy is high, can meet the requirement that clinical Hemostasis examination is analyzed now.

Description

A kind of blood viscoelastic power monitoring device

Technical field

The utility model relates to clinical coagulation analysis technical field, particularly a kind of blood viscoelastic power monitoring device.

Background technology

Blood coagulation is blood clotting, refer to that blood is become the process of gel state that can not be mobile by flowing liquid state, be the important step of physiological hemostasis, to be exactly that soluble fibrin in blood plasma is former become insoluble fibrinous process to the essence of blood clotting.

Thrombelastogram instrument for clinical examination, is one of important tool detecting blood coagulation, existing blood viscoelastic power monitoring device, and cup head is not easy to be kept upright while putting into glass body, while causing probe in inserting cup head, is difficult for aiming at, and is unfavorable for that cup operates; In addition, testing process need be carried out specific rule concussion to the blood sample of surveying in cup conventionally, with thrombotic physiological environment in analogue body; Electromagnetic measurement method measuring accuracy in traditional monitoring device is low, sensitivity is not high; To sum up, existing blood viscoelastic power monitoring device cannot meet the demand that clinical Hemostasis examination is analyzed now.

Utility model content

For the weak point existing in above-mentioned technology, the utility model provide a kind of rational in infrastructure, simple operation, probe positioning accurately, measuring accuracy blood viscoelastic power monitoring device accurately and reliably.

The technical solution adopted in the utility model is: a kind of blood viscoelastic power monitoring device, it is characterized in that, and comprising: back up pad, on it, offer annular distance, described annular distance surrounding offers bar hole; Detection agency, its outside is provided with end cap, flange support, upper flange, lower flange and housing from top to bottom successively coaxially, the inside of described detection agency is provided with a holder, torsion wire and probe from top to bottom successively coaxially, the top of described lower flange is provided with generating laser placed side by side and angular displacement sensor, described probe top is provided with minute surface, and described minute surface and described generating laser and angular displacement sensor are placed in homonymy; Concussion mechanism, it comprise run through described bar hole guide rod, be anchored on described guide rod one end change, drive drive unit, the glass stand that is arranged at the described guide rod other end that described change rotates, be arranged at the cup chamber in described glass stand; Survey cup, it is coaxially embedded in described cup chamber, and described survey cup comprises a glass body, be placed in cup head in described cup body coaxially, be coaxially embedded at the pouring weight of a described cup inner bottom; Wherein, described lower flange is placed in described annular distance, and is anchored in described back up pad, and described lower flange outer cover is equipped with rolling bearing, and described change is anchored on the outside of described rolling bearing.

Preferably, outer wall one side of described housing offers mutual vertically disposed test trough and moves back a glass groove, described enclosure interior is provided with overhead cam and the lower cam being coaxially affixed up and down, described lower cam inside is provided with the ring being coaxially affixed up and down and moves back cup ring, on described ring, be provided with driving lever, described driving lever is placed in described test trough and moves back in glass groove, described moving back between glass top end face of ring and the bottom face of described housing is provided with lower stage clip, the opposite side of described housing outer wall offers translot, in described translot, be provided with guider screw, described guider screw and described driving lever are symmetricly set in described ring both sides.

Preferably, between the upper end of described silk holder and the bottom face on described flange support top, be provided with compression spring, the top end face of the upper end of described end cap and described silk holder offsets.

Preferably, the top end face junction of the bottom face of described upper flange and described lower flange is provided with bent axle nail, and described bent axle nail rotates and drives described upper flange to rotate.

Preferably, be provided with vertically disposed two holding screws and two plungers each other on described flange support, described two holding screws and described two plungers are all in same level.

Preferably, the top of described housing offers two stopper slots that are mutually symmetrical and arrange, and the middle part of described probe is connected with bearing pin, and the two ends of described bearing pin are placed in respectively described two stopper slots.

Preferably, the top of described lower flange offers two locating slots that are mutually symmetrical and arrange, and the top of described probe offers through hole, and during original state, the central shaft of described two locating slots and the central shaft of described through hole coaxially arrange.

Preferably, in described back up pad, be provided with fixed block, the outer wall of described change offers at least two change square holes, the cam that described drive unit comprises drive motor, be connected with the driving shaft of described drive motor, keep tangent Slave Block with described cam outer wall, one end of the fork that is connected with described Slave Block, the other end of described fork is arranged in described change square hole, the middle part of described fork is fixed with one end of extension spring, and the other end of described extension spring is affixed to described fixed block.

Preferably, the bottom of described glass stand is provided with collet, the center place of described collet is equipped with moves back a glass bar, described in to move back the top of glass bar bonded to each other with the upper surface bottom described cup chamber, the upper surface of described collet and described in move back between the lower surface of glass bar and be provided with stage clip.

Preferably, the inwall opening part of described cup body is offered porose shoulder and cup body guiding slope successively, the inner bottom of described cup body is the circular-arc of outside stretching, extension, described cup head is the hollow circular cylinder of T-shape shape, the inwall opening part of described cup head is provided with cup head guiding slope, the bottom of described cup head is circular-arc, and the bottom of the inner bottom of described cup body and described cup head is tangent.

Compared with prior art, its beneficial effect is the utility model: the blood viscoelastic power monitoring device that the utility model provides,

(1) pouring weight arranging by a cup inner bottom, makes to survey cup and forms tumbler device, is convenient to cup and probe and inserts smoothly in cup head;

(2) by concussion mechanism, the blood sample of surveying in cup is carried out to rule concussion, with thrombotic physiological environment in analogue body, thereby guarantee assay accurately and reliably;

(3) by detection agency, probe is carried out to position adjustments, make the measurement and positioning of probe more accurate, by optical lever method, detect and substitute traditional electromagnetic measurement method, measuring accuracy and sensitivity are significantly improved;

(4) by rolling bearing, concussion mechanism and detection agency are bound organically in to one, make package unit practicality rational in infrastructure, greatly reduce the friction and wear that concussion brings;

(5) simple and practical, the simple operation of this apparatus structure, measuring accuracy accurately and reliably, can meet the requirement that clinical Hemostasis examination is analyzed now, have good application value.

Accompanying drawing explanation

Fig. 1 is the structural representation of blood viscoelastic power monitoring device described in the utility model;

Fig. 2 is the structural representation of detection agency described in the utility model;

Fig. 3 is the cut-open view of detection agency described in the utility model;

Fig. 4 is the structural representation of the detection agency without flange support and upper flange described in the utility model;

Fig. 5 is the structural representation of housing described in the utility model;

Fig. 6 is the structural representation of overhead cam described in the utility model and lower cam;

Fig. 7 is the structural representation of back up pad described in the utility model;

Fig. 8 is the structural representation that shakes mechanism described in the utility model;

Fig. 9 is that survey cup described in the utility model is loaded in the cut-open view in glass chamber;

Figure 10 is the structural representation of surveying cup described in the utility model;

Figure 11 is the cut-open view of surveying cup described in the utility model;

In figure: 100 detection agencies; 101 end caps; 102 holders; 103 flange supports; 104 compression springs; 105 torsion wires; 106 upper flanges; 107 holding screws; 108 plungers; 109 clips; 110 probes; 1101 grooves; 1102 through holes; 111 bearing pins; 112 lower flanges; 1121 locating slots; 113 bent axle nails; 114 housings; 1141 initial bit; 1142 test bits; 1143 move back cup position; 1144 stopper slots; 1145 test trough; 1146 move back a glass groove; 1147 translots; 115 overhead cams; 116 times cams; 117 rings; 118 driving levers; 119 guider screws; 120 move back cup ring; 121 times stage clips; 122 minute surfaces; 123 generating lasers; 124 angular displacement sensors; 200 concussion mechanisms; 201 cams; 202 Slave Blocks; 203 forks; 204 drive motor; 205 changes; 2051 change square holes; 206 guide rods; 207 linear bearings; 208 glass stands; 209 glasss of chambeies; 210 rolling bearings; 211 extension springs; 212 move back a glass bar; 213 collets; 214 stage clips; 300 survey cup; 310 glasss of heads; 311 glasss of muscle; 312 glasss of head guiding slopes; 320 glasss of bodies; 321 glasss of body muscle; 322 hole shoulders; 323 glasss of body guiding slopes; 330 pouring weights; 400 back up pads; 401 annular distances; 402 bar holes; 403 fixed blocks.

Embodiment

Below in conjunction with accompanying drawing, the utility model is described in further detail, to make those skilled in the art can implement according to this with reference to instructions word.

As shown in Figure 1, the utility model provides a kind of blood viscoelastic power monitoring device, comprising: back up pad 400, detection agency 100, concussion mechanism 200 and survey cup 300.

Back up pad 400 (as shown in Figure 7), offers annular distance 401 and fixed block 403 on it, described annular distance 401 surroundings offer two bar holes 402.

Detection agency 100 (as shown in Fig. 2 mono-Fig. 4), it is through described annular distance 401, and is anchored in described back up pad 400, and described detection agency 100 comprises:

Flange support 103, its place, center offers prop hole (not shown), on described flange support 103, be also provided with vertical each other two plungers 108 and two holding screws 107, described two plungers 108 and two uniform being distributed in same level of holding screw 107, the top of described flange support 103 is equipped with end cap 101;

Silk holder 102, its upper end offers V-shaped groove, the lower end of described silk holder 102 is run through described prop hole coaxially, the place, center of described silk holder 102 offers a hole (not shown), between the upper end of described silk holder 102 and the bottom face on described flange support 103 tops, be provided with compression spring 104, the top end face of the upper end of described end cap 101 and described silk holder 102 offsets;

Torsion wire 105, its top is placed in described V-shaped groove, and the bottom of described torsion wire 105 is run through described silk hole coaxially;

Upper flange 106, its upper end be fixed in described flange support 103 under;

Lower flange 112, the lower end of its upper end and described upper flange 106 is fastening, the top end face junction of the bottom face of described upper flange 106 and described lower flange 112 is provided with bent axle nail 113, described bent axle nail 113 rotates and drives described upper flange 106 to rotate, the top of described lower flange 112 offers two locating slots 1121 that are mutually symmetrical and arrange, and the top of described lower flange 112 is provided with generating laser placed side by side 123 and angular displacement sensor 124;

Housing 114 (as shown in Figure 5), it is embedded at the bottom of described lower flange 112, the top of described housing 114 offers symmetrically arranged two stopper slots 1144, outer wall one side of described housing 114 offers test trough 1145 and moves back glass groove 1146, the opposite side of described housing 114 outer walls offers translot 1147, in described translot 1147, be provided with guider screw 119, described housing 114 inside are provided with overhead cam 115 and the lower cam 116 (as shown in Figure 6) being coaxially affixed up and down, described lower cam 116 inside are provided with the ring 117 being coaxially affixed up and down and move back cup ring 120, described ring 117 1 sides are provided with driving lever 118, described driving lever 118 is placed in described test trough 1145 and moves back in glass groove 1146, described driving lever 118 and described guider screw 119 are symmetricly set in described ring 117 both sides, described moving back between glass top end face of ring 120 and the bottom face of described housing 114 is provided with lower stage clip 121,

Probe 110, its top offers a groove 1101, the bottom of described torsion wire 105 is arranged in described silk groove 1101, and fastening by clip 109, the middle part of described probe 110 is connected with bearing pin 111, the two ends of described bearing pin 111 are placed in respectively described two stopper slots 1144, hunting range with restriction probe 110, the top of described probe 110 offers through hole 1102, during original state, the central shaft of described through hole 1102 is coaxial with the central shaft of described two locating slots 1121, described probe 110 tops are also provided with minute surface 122, described minute surface 122 and described generating laser 123 and angular displacement sensor 124 homonymy settings,

Wherein, by adjusting two holding screws 107 to adjust the horizontal level of flange support 103, and then the horizontal level of the axis of adjustment probe 110; By rotation end cap 101, to adjust the vertical height of probe 110; By rotary crankshaft, follow closely the circumferential position of 113 fine setting upper flanges 106, and then the horizontal circumferential position of fine setting probe 110; Thereby realize the accurate location to probe 110 detection positions.

Concussion mechanism 200 (as shown in Figure 8), it comprises the guide rod 206 that runs through described bar hole 402, be anchored on the change 205 of described guide rod 206 one end, the drive unit that drives described change 205 to rotate, be arranged at the glass stand 208 of described guide rod 206 other ends, be arranged at the cup chamber 209 in described glass stand 208, described glass stand 208 both sides all offer guide hole (not shown), in described guide hole, be provided with linear bearing 207, described glass stand 208 can move up and down along guide rod 206 under the effect of linear bearing 207, the outer wall of described change 205 offers at least two change square holes 2051, described drive unit comprises drive motor 204, the cam 201 being connected with the driving shaft of described drive motor 204, keep tangent Slave Block 202 with described cam 201 outer walls, one end of the fork 203 being connected with described Slave Block 202, the other end of described fork 203 is arranged in described change square hole 2051, by fork 203 being arranged in the change square hole 2051 of diverse location, to regulate shock range, by drive motor 204, rotate and drive described cam 201 to rotate, thereby drive described fork 203 reciprocally swingings, the middle part of described fork 203 is fixed with one end of extension spring 211, the other end of described extension spring 211 is affixed to described fixed block 403, the bottom of described glass stand 208 is provided with collet 213, the place, center of described collet 213 is equipped with moves back glass bar 212, the upper surface of described top of moving back glass bar 212 and described cup 209 bottoms, chamber is bonded to each other, the upper surface of described collet 213 and described in move back between the lower surface of glass bar 212 and be provided with stage clip 214, wherein, described lower flange 112 is placed in described annular distance 401, and be anchored in described back up pad 400, described lower flange 112 outer cover are equipped with rolling bearing 210, described change 205 is anchored on the outside of described rolling bearing 210.

Survey glass 300 (as shown in Figure 10 and Figure 11), it comprises glass body 320, be placed in coaxially cup in described cup body 320 310, coaxially be embedded at the pouring weight 330 of described cup 310 inner bottom, described cup body 320 inside are hollow structure, the outer wall of described cup body 320 is provided with three cup body muscle 321, the inwall opening part of described cup body 320 is offered porose shoulder 322 and cup body guiding slope 323 successively, the inner bottom of described cup body 320 is the circular-arc of outside stretching, extension, described glass 310 is the hollow circular cylinder of T-shape shape, the inwall opening part of described glass 310 is provided with a cup head guiding slope 315, described cup 310 inwall are also provided with three cup muscle 311, the bottom of described glass 310 is circular-arc, and tangent with the inner bottom of described cup body 320, cup 310 is fastening by three cup muscle 311 and probe 110, and take transition fit with probe 110, cup body 320 is fixed in glass chamber 209 by three cup body muscle 321, and take transition fit mode with cup chamber 209, the inwall of the outer wall of described glass 310 and described cup body 320 all adopts frosted to process and be provided with reagent layer.

The concrete use procedure of this monitoring device is as follows:

First, the blood sample of collection is placed in and surveys cup 300, the survey cup that blood sample is housed is placed in to glass chamber 209 (as shown in Figure 9), and will glass stand 208 that survey cup 300 is housed be moved upward to the distance of suitable detection, start drive motor 204, cam 201 rotates under the effect of driving shaft, and drives fork 203 reciprocally swingings, make glass stand 208 according to predetermined rule concussion, with thrombotic physiological environment in analogue body;

Secondly, when initial bit 1141, driving lever 118 is in initial bit, and overhead cam 115 holds up probe 110, and probe 110 and the bottom of lower flange 112 are offseted, so in spatial axes to moving; When test bit 1142, by the horizontal test bit that is allocated to of driving lever 118, under the stirring of driving lever 118, lower cam 116 rotates, and overhead cam 115 moves down probe 110 is moved down freely under Action of Gravity Field, and is suspended on the lower end of torsion wire 105, probe 110 insertions are surveyed in cup 300 so that the blood sample of surveying in cup 300 is carried out to the detection of blood viscoelastic power, probe 110 is when surveying blood viscoelastic power, and each cycle is rotated 4 degree 45 minutes, and rotation period is 10 seconds;

Finally, by controlling primary controller (not shown), make generating laser 123 send laser, (order of reflection requires to arrange according to measuring accuracy in minute surface 122 reflections of laser on probe 110, order of reflection is more, precision is higher, structure is also more complicated), reflected light is received by angular displacement sensor 124, detect according to this rotation angle of probe 110, data processor is extrapolated the variation figure of viscoelastic power according to rotation angle, thereby responsive monitoring of blood is solidified the variation of the viscoelastic power in fibrinolytic process, be completed, perpendicular being allocated to of driving lever 118 moved back to cup position 1143, so that the survey cup 300 that blood sample is housed is separated with probe 110, by hand propelled, moving back glass bar 212 more up moves, so that the survey cup 300 being placed in glass chamber 209 is popped up, after hand discharges, move back glass bar 212 resets under stage clip 214 effects.

The blood viscoelastic power monitoring device that the utility model provides, the pouring weight 330 arranging by cup 310 inner bottom, makes to survey cup 300 and forms tumbler devices, is convenient to cup and probe 110 and inserts smoothly glass in 310; By 200 pairs of blood samples of surveying in cup 300 of concussion mechanism, carry out rule concussion, with thrombotic physiological environment in analogue body, thereby guarantee assay accurately and reliably; By detection agency 100, probe 110 is carried out to position adjustments, make the measurement and positioning of probe 110 more accurate, by optical lever method, detect and substitute traditional electromagnetic measurement method, measuring accuracy and sensitivity are significantly improved; By rolling bearing 210, concussion mechanism 200 and detection agency 110 are bound organically in to one, make package unit practicality rational in infrastructure, greatly reduce the friction and wear that concussion brings; This monitoring device is simple and practical, simple operation, measuring accuracy accurately and reliably, can meet the requirement that clinical Hemostasis examination is analyzed now, there is good application value.

In the present embodiment, " top " " upper end " of mentioning is according to the definition of common meaning, and such as, the direction definition of reference to gravitational, the direction of gravity is downwards, and contrary direction is top, similarly up be top or top.

Although embodiment of the present utility model is open as above, but it is not limited in listed utilization in instructions and embodiment, it can be applied to the various fields of the present utility model that are applicable to completely, for those skilled in the art, can easily realize other modification, therefore do not deviating under the universal that claim and equivalency range limit, the utility model is not limited to specific details and illustrates here and the legend of describing.

Claims (10)

1. a blood viscoelastic power monitoring device, is characterized in that, comprising:

Back up pad, offers annular distance on it, described annular distance surrounding offers bar hole;

Detection agency, its outside is provided with end cap, flange support, upper flange, lower flange and housing from top to bottom successively coaxially, the inside of described detection agency is provided with a holder, torsion wire and probe from top to bottom successively coaxially, the top of described lower flange is provided with generating laser placed side by side and angular displacement sensor, described probe top is provided with minute surface, and described minute surface and described generating laser and angular displacement sensor are placed in homonymy;

Concussion mechanism, it comprise run through described bar hole guide rod, be anchored on described guide rod one end change, drive drive unit, the glass stand that is arranged at the described guide rod other end that described change rotates, be arranged at the cup chamber in described glass stand;

Survey cup, it is coaxially embedded in described cup chamber, and described survey cup comprises a glass body, be placed in cup head in described cup body coaxially, be coaxially embedded at the pouring weight of a described cup inner bottom;

Wherein, described lower flange is placed in described annular distance, and is anchored in described back up pad, and described lower flange outer cover is equipped with rolling bearing, and described change is anchored on the outside of described rolling bearing.

2. blood viscoelastic power monitoring device as claimed in claim 1, it is characterized in that, outer wall one side of described housing offers mutual vertically disposed test trough and moves back a glass groove, described enclosure interior is provided with overhead cam and the lower cam being coaxially affixed up and down, described lower cam inside is provided with the ring being coaxially affixed up and down and moves back cup ring, on described ring, be provided with driving lever, described driving lever is placed in described test trough and moves back in glass groove, described moving back between glass top end face of ring and the bottom face of described housing is provided with lower stage clip, the opposite side of described housing outer wall offers translot, in described translot, be provided with guider screw, described guider screw and described driving lever are symmetricly set in described ring both sides.

3. blood viscoelastic power monitoring device as claimed in claim 1, is characterized in that, between the upper end of described silk holder and the bottom face on described flange support top, is provided with compression spring, and the top end face of the upper end of described end cap and described silk holder offsets.

4. blood viscoelastic power monitoring device as claimed in claim 1, is characterized in that, the top end face junction of the bottom face of described upper flange and described lower flange is provided with bent axle nail, and described bent axle nail rotates and drives described upper flange to rotate.

5. blood viscoelastic power monitoring device as claimed in claim 1, is characterized in that, is provided with vertically disposed two holding screws and two plungers each other on described flange support, and described two holding screws and described two plungers are all in same level.

6. blood viscoelastic power monitoring device as claimed in claim 1, is characterized in that, the top of described housing offers two stopper slots that are mutually symmetrical and arrange, and the middle part of described probe is connected with bearing pin, and the two ends of described bearing pin are placed in respectively described two stopper slots.

7. blood viscoelastic power monitoring device as claimed in claim 1, it is characterized in that, the top of described lower flange offers two locating slots that are mutually symmetrical and arrange, the top of described probe offers through hole, during original state, the central shaft of described two locating slots and the central shaft of described through hole coaxially arrange.

8. blood viscoelastic power monitoring device as claimed in claim 1, it is characterized in that, in described back up pad, be provided with fixed block, the outer wall of described change offers at least two change square holes, the cam that described drive unit comprises drive motor, be connected with the driving shaft of described drive motor, keep tangent Slave Block with described cam outer wall, one end of the fork that is connected with described Slave Block, the other end of described fork is arranged in described change square hole, the middle part of described fork is fixed with one end of extension spring, and the other end of described extension spring is affixed to described fixed block.

9. blood viscoelastic power monitoring device as claimed in claim 1, it is characterized in that, the bottom of described glass stand is provided with collet, the place, center of described collet is equipped with moves back a glass bar, the upper surface of described top of moving back glass bar and bottom, described cup chamber is bonded to each other, the upper surface of described collet and described in move back between the lower surface of glass bar and be provided with stage clip.

10. blood viscoelastic power monitoring device as claimed in claim 1, it is characterized in that, the inwall opening part of described cup body is offered porose shoulder and cup body guiding slope successively, the inner bottom of described cup body is the circular-arc of outside stretching, extension, described cup head is the hollow circular cylinder of T-shape shape, the inwall opening part of described cup head is provided with cup head guiding slope, and the bottom of described cup head is circular-arc, and the bottom of the inner bottom of described cup body and described cup head is tangent.