CN205037879U - Operation robot system accuracy testing device - Google Patents
Operation robot system accuracy testing device Download PDFInfo
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- CN205037879U CN205037879U CN201520673162.1U CN201520673162U CN205037879U CN 205037879 U CN205037879 U CN 205037879U CN 201520673162 U CN201520673162 U CN 201520673162U CN 205037879 U CN205037879 U CN 205037879U
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Abstract
The utility model relates to an operation robot system accuracy testing device, install including a support the top of support sets up a plurality of target spot pillars, sets up a target spot on the top of each target spot pillar. The utility model provides an one including the detection device of pillar, target spot pillar and target spot, and the line that uses the target spot place through drive operation robot is planning route motion, observes the test bar pointed end of connecting at operation robot execution end and whether can accurately touch the target spot center to this precision of coming definite system, this method is novel ingenious and easily realize, does not relate to complicated algorithm.
Description
Technical field
The utility model relates to a kind of surgical robot system accuracy detecting device, belongs to operating robot technical field.
Background technology
Positioning precision is the most important performance of operating robot.The precision of correct evaluation system is the key job guaranteed operation safety, complete smoothly.The index evaluating robot precision has absolute precision, repetitive positioning accuracy etc.Common robot precision's pick-up unit is accuracy detection for industrial robot and designs, as the Chinese patent that application number is 97105266.2, be called " system for repeated detecting position precision of robot " is used for the repeatable accuracy of measuring robots, application number is 200410014906.5, the Chinese patent of " pose detecting " by name is used for position and the attitude of measuring robots.Said apparatus is all comparatively complicated, often needs to carry out complicated calculating, and measures not directly perceived, does not also relate to spatial positioning accuracy.
Operating robot is applied in the accurate location for operating theater instruments or implant in operation.By with medical imaging device with the use of, realize surgical planning and operation pathway location, by robot localization operation pathway, assist physician accurately completes the operation of operation.System accuracy is subject to the various factors such as anamorphose, image space and robot volume coordinate mapping accuracy, mechanical arm positioning precision, operation tool mismachining tolerance.Existing measuring system can not be measured comprehensively and effectively to the system accuracy of operating robot.
In actual operation process, the most important application of operating robot is the path determining to perform the operation, and this paths can describe with a space line.Not only be point location error requirements to the accuracy requirement of surgical robot system, but take into account fixed point and directed error requirements simultaneously, requirement directed is in some cases even more important.Therefore, the method for absolute precision and this simple statement fix error of repetitive positioning accuracy, can not the precision of thoroughly evaluating orthopedic navigation robot.In practice, the accurate measurement of spatial point distance is usually also very difficult.
Summary of the invention
For the problems referred to above, the purpose of this utility model be to provide a kind of can accurately, the surgical robot system accuracy detecting device of thoroughly evaluating operating robot precision.
For achieving the above object, the utility model is by the following technical solutions: a kind of surgical robot system accuracy detecting device, it is characterized in that: it comprises a bearing, multiple target spot pillar is set at the top of described bearing, one target spot is set on the top of each target spot pillar.
Described target spot is steel ball, copper ball or shot; The material of described bearing and target spot pillar is organic glass, nylon or plastics.
The top of described bearing is provided with multiple target spot mounting hole, and described target spot pillar is removably connected in described target spot mounting hole.Described bearing and target spot pillar are made by the material that X-ray receptivity is poor.
Also comprise a three-degree-of-freedom motion mechanism; Described three-degree-of-freedom motion mechanism comprises a base, the first chute that a vertical direction is arranged is fixedly connected with at the top of described base, described first chute connects one first expansion link slidably, the second chute that a horizontal direction is arranged is fixedly connected with at the top of described first expansion link, described second chute connects one second expansion link slidably, the 3rd chute that a horizontal direction is arranged is fixedly connected with in one end of described second expansion link, described 3rd chute connects one the 3rd expansion link slidably, and described 3rd expansion link is vertical with described second expansion link; One end of described 3rd expansion link is fixedly connected with described bearing.
The end face of described bearing is a dip plane.
Described first expansion link, the second expansion link and the 3rd expansion link are provided with rule.
Described first chute is provided with one for locking the locking nail of described first expansion link; Described second chute is provided with one for locking the locking nail of described second expansion link; Described 3rd chute is provided with one for locking the locking nail of described 3rd expansion link.
The utility model is owing to taking above technical scheme, it has the following advantages: 1, the utility model proposes the pick-up unit that comprises pillar, target spot pillar and target spot, based on this device, by driving operating robot with the line at target spot place for path planning moves, observe the prod tip being connected to operating robot actuating station and whether can touch target spot center exactly, carry out the precision of certainty annuity with this, the method is novel ingenious and be easy to realize, and does not relate to complicated algorithm.2, the utility model is owing to having set up a three-degree-of-freedom motion mechanism in the bottom of bearing, is therefore convenient to change the locus of target spot, and then can realize the system accuracy of the diverse location in a certain area of space to operating robot and measure.3, the utility model structure simple, be easy to realize, the measurement of all kinds of surgical robot system precision can be widely used in.
Accompanying drawing explanation
Fig. 1 is one-piece construction schematic diagram of the present utility model;
Fig. 2 is the utility model Cleaning Principle schematic diagram.
Embodiment
Below in conjunction with drawings and Examples, the utility model is described in detail.
Embodiment one:
As shown in Figure 1, the present embodiment comprises a bearing 1, and the top of bearing 1 is provided with multiple target spot pillar 2, arranges a target spot 3 on the top of each target spot pillar 2.
Further, target spot 3 adopts the stronger material of X-ray receptivity to make, such as, can be steel ball, copper ball or shot; And bearing 1 and target spot pillar 2 are made up of the material that X-ray receptivity is poor, as organic glass, nylon or plastics.
Further, between target spot pillar 2 and bearing 1, adopt removably connected mode, and, be preset with multiple target spot mounting hole at the top of bearing 1, in selected target spot mounting hole, target spot pillar 2 can be installed according to actual conditions in use.Bearing and target spot pillar are made by the material that X-ray receptivity is poor.
For effect of the present utility model is described all sidedly, be described from Cleaning Principle and use utility model two aspect below:
(1) accuracy detection principle: as shown in Figure 2, if the space line L in surgery planning path is represented, orthopedic robot terminal end path space line L ' represents, is exactly so the evaluation of the collinearity to straight line L ' and L to the evaluation of robot precision.Get A, B on the linel at 2, its space length is S, measures straight line L ' and the distance d1 putting A, B, d2 respectively.As shown in the figure, when d1, d2 are 0, L ' overlaps with L, and result does not have error; D1 or d2 increases, and the conllinear degradation of L ' and L is described.Therefore, be rational by the error that d1, d2 are used as robot.
A difficult point in practical operation is that point is difficult to directly accurately measure with the distance of line, and the utility model adopts the error upper limit to replace distance d1, d2.A, B are made the steel ball of diameter of phi D.In using, x-ray fluoroscopy is carried out with target spot sham operated target location, and carry out image acquisition and surgery planning, with target spot center for the in and out point of operation is planned into needle path footpath, with prod along path planning contact steel ball A, if steel ball A can be hit in prod tip, specification error d1≤D/2, otherwise d1>D/2; Remove steel ball A, with prod contact steel ball B, if steel ball B can be hit in prod tip, show error d2≤D/2, otherwise d2>D/2.If d1≤D/2, and d2≤D/2, system accuracy can be designated as ± D/2.
(2) using method:
1) pick-up unit described in the utility model is fixed on certain position of operative space, selects two target spots 3 to carry out image acquisition by the image acquisition end of operating robot.
2) be carry out path planning into the in and out point in needle path footpath with two target spots 3 selected respectively in operating robot control program.
3) prod is arranged on the actuating station of operating robot, and controls the path motion of operating robot according to planning, the contact situation of observation test rod tip and first target spot 3 (being Φ 3mm steel ball in the present embodiment).
4) the target spot pillar 2 at first target spot 3 place is pulled down, the contact situation of observation test rod tip and second target spot 3 (Φ 3mm steel ball).
5) precision of this position is obtained by the contact situation of prod and two tested target spots 3.
Embodiment two:
On the basis of embodiment one, the present embodiment sets up a three-degree-of-freedom motion mechanism in the bottom of bearing 1, its effect is the locus being convenient to change target spot 3, so that the system accuracy of diverse location to operating robot in a certain area of space is measured.As shown in Figure 1, three-degree-of-freedom motion mechanism of the present utility model comprises a base 4, the first chute 5 that a vertical direction is arranged is fixedly connected with at the top of base 4, first chute 5 connects one first expansion link 6 slidably, the second chute 7 that a horizontal direction is arranged is fixedly connected with at the top of the first expansion link 6, second chute 7 connects one second expansion link 8 slidably, the 3rd chute 9 that a horizontal direction is arranged is fixedly connected with in one end of the second expansion link 8, 3rd chute 9 connects one the 3rd expansion link 10 slidably, wherein, 3rd expansion link 10 is vertical with the second expansion link 8.One end of 3rd expansion link 10 is fixedly connected with bearing 1.
Further, the end face of bearing 1 is a dip plane, the x-ray when carrying out horizontal direction perspective can be prevented in the process gathering target spot image to need the material of the width through whole bearing 1, and the x-ray decay needing the material through whole target spot pillar 2 height to cause due to x-ray when carrying out vertical direction perspective is serious.
Further, the first expansion link 3, second expansion link 5 and the 3rd expansion link 7 are provided with rule 11.
Further, first chute 5 is provided with one for locking the locking nail 12 of the first expansion link 6, second chute 7 being provided with one for locking the locking nail 12 of the second expansion link 8, the 3rd chute 9 being provided with one for locking the locking nail 12 of the 3rd expansion link 10.
The utility model is only described with above-described embodiment, and the structure of each parts, setting position and connection thereof all can change to some extent.On the basis of technical solutions of the utility model, all improvement of carrying out individual part according to the utility model principle or equivalents, all should not get rid of outside protection domain of the present utility model.
Claims (7)
1. a surgical robot system accuracy detecting device, is characterized in that: it comprises a bearing, arranges multiple target spot pillar, arrange a target spot on the top of each target spot pillar at the top of described bearing.
2. a kind of surgical robot system accuracy detecting device as claimed in claim 1, is characterized in that: described target spot is steel ball, copper ball or shot; The material of described bearing and target spot pillar is organic glass, nylon or plastics.
3. a kind of surgical robot system accuracy detecting device as claimed in claim 1, is characterized in that: the top of described bearing is provided with multiple target spot mounting hole, and described target spot pillar is removably connected in described target spot mounting hole.
4. a kind of surgical robot system accuracy detecting device as described in claim 1 or 2 or 3, is characterized in that: also comprise a three-degree-of-freedom motion mechanism; Described three-degree-of-freedom motion mechanism comprises a base, the first chute that a vertical direction is arranged is fixedly connected with at the top of described base, described first chute connects one first expansion link slidably, the second chute that a horizontal direction is arranged is fixedly connected with at the top of described first expansion link, described second chute connects one second expansion link slidably, the 3rd chute that a horizontal direction is arranged is fixedly connected with in one end of described second expansion link, described 3rd chute connects one the 3rd expansion link slidably, and described 3rd expansion link is vertical with described second expansion link; One end of described 3rd expansion link is fixedly connected with described bearing.
5. a kind of surgical robot system accuracy detecting device as claimed in claim 4, is characterized in that: the end face of described bearing is a dip plane.
6. a kind of surgical robot system accuracy detecting device as described in claim 4 or 5, is characterized in that: described first expansion link, the second expansion link and the 3rd expansion link are provided with rule.
7. a kind of surgical robot system accuracy detecting device as described in claim 4 or 5, is characterized in that: on described first chute, be provided with one for locking the locking nail of described first expansion link; Described second chute is provided with one for locking the locking nail of described second expansion link; Described 3rd chute is provided with one for locking the locking nail of described 3rd expansion link.
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CN201520673162.1U CN205037879U (en) | 2015-09-01 | 2015-09-01 | Operation robot system accuracy testing device |
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CN201520673162.1U CN205037879U (en) | 2015-09-01 | 2015-09-01 | Operation robot system accuracy testing device |
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN105066916A (en) * | 2015-09-01 | 2015-11-18 | 北京天智航医疗科技股份有限公司 | Surgical robot system precision detection apparatus and method |
CN114081632A (en) * | 2021-11-22 | 2022-02-25 | 南京普爱医疗设备股份有限公司 | Comprehensive positioning error detection device for orthopedic surgery robot |
-
2015
- 2015-09-01 CN CN201520673162.1U patent/CN205037879U/en active Active
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN105066916A (en) * | 2015-09-01 | 2015-11-18 | 北京天智航医疗科技股份有限公司 | Surgical robot system precision detection apparatus and method |
CN105066916B (en) * | 2015-09-01 | 2017-06-16 | 北京天智航医疗科技股份有限公司 | A kind of surgical robot system accuracy detecting device and method |
CN114081632A (en) * | 2021-11-22 | 2022-02-25 | 南京普爱医疗设备股份有限公司 | Comprehensive positioning error detection device for orthopedic surgery robot |
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