CN212630892U - Guide rail device and medical robot - Google Patents

Abstract

The utility model provides a guide rail device and medical robot relates to medical instrument technical field. The guide rail device includes: the medical robot comprises a curve guide rail and a sliding block, wherein the sliding block is connected to the curve guide rail in a sliding manner, and the bottom of the sliding block is suitable for being connected with a medical robot; the curve guide rail comprises a first arc section guide rail and a second arc section guide rail, and the arc opening direction of the first arc section guide rail is opposite to the arc opening direction of the second arc section guide rail. The curved guide rail is arranged at the high altitude of a patient to be operated, so that the problems that the existing laparoscopic surgery robot with a floor type structure is inflexible to walk, inconvenient to operate, easy to block the sight, occupies a large amount of ground space and the like are solved.

Description

Guide rail device and medical robot

Technical Field

The utility model relates to the technical field of medical equipment, particularly, relate to a guide rail device and medical robot.

Background

Compared with the traditional operation, the laparoscopic surgery is popular with patients, especially has small scar after operation and meets the aesthetic requirements, young patients are more willing to accept the laparoscopic surgery, and the minimally invasive surgery is the general trend and pursuit target of surgical development.

The laparoscopic surgery robot is an important device for laparoscopic surgery, and the existing medical robot represented by the laparoscopic surgery robot generally adopts a floor type structure, and the structure has the defects of inflexible walking, inconvenient operation, easy sheltering of sight, occupation of a large amount of ground space and the like.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the problems that the prior medical robot represented by the laparoscopic surgery robot generally adopts a floor type structure to a certain extent, and the structure has the defects of inflexible walking, inconvenient operation, easy sheltering from sight, large amount of floor space occupation and the like.

In order to solve the above problem, the utility model provides a guide rail device, include:

a curved guide rail; and

the sliding block is connected with the curve guide rail in a sliding mode, and the bottom of the sliding block is suitable for being connected with a medical robot;

the curve guide rail comprises a first arc section guide rail and a second arc section guide rail, and the arc opening direction of the first arc section guide rail is opposite to the arc opening direction of the second arc section guide rail.

Further, the curve guide rail further comprises a first linear guide rail, a second linear guide rail and a third linear guide rail which are parallel to each other, the first linear guide rail, the first arc section guide rail, the second linear guide rail, the second arc section guide rail and the third linear guide rail are connected in sequence, the opening direction of the first arc section guide rail faces to one end of the second linear guide rail, and the opening direction of the second arc section guide rail faces to the other end of the second linear guide rail.

Furthermore, the curved guide rail comprises a guide rail body and two support rail plates, the support rail plates are connected with the guide rail body, the support rail plates are of a long strip-shaped plate-shaped structure and extend along the length direction of the curved guide rail, and the two support rail plates are respectively arranged on two sides of the guide rail body;

the slider includes glide machanism, glide machanism is two bearing wheels, and two bearing wheels are arranged in respectively two the top of support rail board, through the guide rail body is arranged in two between the bearing wheel, in order to prevent the slider with the curve guide rail breaks away from.

Further, the slider further includes:

fixing the bottom plate; and

the two rotating blocks are respectively connected to the top of the fixed base plate in a rotating mode, the bearing wheels are arranged at the rotating blocks, and the supporting rail plate is arranged between the bearing wheels and the rotating blocks.

Further, the bearing wheel is rotatably connected with the rotating block.

Furthermore, the sliding block further comprises a stable moving mechanism, the stable moving mechanism comprises two retaining wheels, the retaining wheels are arranged at the rotating block, annular wheel grooves are formed in the wheel edges of the retaining wheels, and two side edges of the supporting rail plate are respectively arranged in the wheel grooves of the two retaining wheels to prevent the sliding block from shaking when moving.

Further, the retaining wheel is rotatably connected with the rotating block.

Further, the curved guide rail further comprises a rack, the rack extends along the length direction of the support rail plate, the sliding block further comprises a gear and a driving motor, the driving motor is used for driving the gear to rotate, and the gear is meshed with the rack.

Further, a stopper is arranged on the top of the sliding block, and the stopper is suitable for stopping the sliding block from moving along the curved guide rail.

In addition, the utility model also provides a medical robot, include the guide rail device.

Since the function of the medical robot in the present invention is the same as the function of the rail device, the medical robot will not be explained.

Compared with the prior art, the utility model provides a pair of guide rail device has but not be limited to following technological effect:

by arranging the curve guide rail at the high altitude of the patient to be operated, the curve guide rail in the state can not block the sight of the patient and the doctor and can not occupy the space on the ground, the slide block slides along the curve guide rail, the design of the curve ensures that the slide block can slide in a two-dimensional plane with the robot body, only the slide block needs to be moved to a proper position on the two-dimensional plane, the operation is convenient, under the condition of the suspension arrangement, after the medical robot is connected with the slide block, the medical robot can not be hindered by obstacles (such as a sickbed and an operating table), so that the medical robot can walk flexibly, solves the problem that the existing medical robot represented by the laparoscopic surgery robot generally adopts a floor type structure, the structure has the defects of inflexible walking, inconvenient operation, easy sheltering of sight, occupation of a large amount of ground space and the like.

Drawings

Fig. 1 is a schematic structural view of a guide rail device according to an embodiment of the present invention;

FIG. 2 is a schematic block diagram of a slide according to an embodiment of the present invention;

FIG. 3 is an enlarged view at B of FIG. 1;

FIG. 4 is an enlarged view taken at A in FIG. 1;

fig. 5 is a schematic structural view of a meshing state of a gear and a rack according to an embodiment of the present invention.

Description of the labeling:

1-a curve guide rail, 101-a first linear guide rail, 102-a first arc section guide rail, 103-a second linear guide rail, 104-a second arc section guide rail, 105-a third linear guide rail, 11-a support rail plate, 111-a side edge, 12-a curve rack and 13-a guide rail body;

2-sliding block, 21-fixed bottom plate, 22-rotating block, 23-retaining wheel, 231-wheel groove, 24-bearing wheel, 25-brake, 26-gear and 27-driving motor;

3-robot body, 31-lifting rod, 32-support arm rotating support, 33-rotating support arm, 34-telescopic rod and 35-operation manipulator.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention more comprehensible, embodiments accompanied with figures are described in detail below.

In the description of the present invention, it should be understood that the terms "upper", "lower", "front", "rear", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed in a specific orientation, and be operated, and thus should not be construed as limiting the present invention.

Also, in the drawings, the Z-axis represents a vertical, i.e., up-down position, and a positive direction of the Z-axis (i.e., an arrow direction of the Z-axis) represents up, and a negative direction of the Z-axis (i.e., a direction opposite to the positive direction of the Z-axis) represents down;

in the drawings, the X-axis represents the longitudinal direction of the horizontal plane, perpendicular to the Z-axis, and the positive direction of the X-axis (i.e., the arrow direction of the X-axis) represents the front side, and the negative direction of the X-axis (i.e., the direction opposite to the positive direction of the X-axis) represents the rear side;

in the drawings, Y represents a horizontal direction, while being perpendicular to the Z-axis and the X-axis, and a positive direction of the Y-axis (i.e., an arrow direction of the Y-axis) represents a left side, and a negative direction of the Y-axis (i.e., a direction opposite to the positive direction of the Y-axis) represents a right side;

the plane formed by the X axis and the Z axis is a vertical plane.

It should also be noted that the foregoing Z-axis, Y-axis, and X-axis representations are merely intended to facilitate the description of the invention and to simplify the description, and are not intended to indicate or imply that the device or element so referred to must have a particular orientation, be constructed and operated in a particular orientation, and are not to be construed as limiting the invention.

Referring to fig. 1 to 5, the present embodiment provides a rail apparatus including:

a curved guide rail 1;

the sliding block 2 is matched with the curved guide rail 1, namely is connected with the curved guide rail 1 in a sliding mode, and the sliding block 2 is suitable for moving along the curved guide rail 1;

the bottom of the slide 2 is adapted to be connected to a medical robot, which may be a laparoscopic surgical robot or other medical robot, for example.

Here, the curved guide rail 1 may be disposed at a high altitude, which refers to above an operating table or a hospital bed, and more specifically, with respect to a patient to be operated, the curved guide rail 1 is disposed above an operating area of the patient, may be disposed on a roof of the room, or may be disposed on a top of the operating table.

The curve guide rail 1 in the state can not block the sight of a patient and a doctor, and can not occupy the space on the ground, the slide block 2 slides along the curve guide rail 1, the curve design enables the slide block 2 to carry the medical robot to slide in at least one two-dimensional plane, only the slide block 2 needs to be moved to a proper position on the two-dimensional plane, and the operation is convenient, under the suspension arrangement condition, the medical robot connected with the bottom of the slide block 2 can not be blocked by a barrier such as a sickbed, so that the walking is flexible, and the problems that the existing laparoscopic surgery robot with a floor type structure has the defects of inflexible walking, inconvenient operation, easy sight shielding, large amount of ground space occupation and the like are solved, wherein the two-dimensional plane refers to an XY plane in fig. 1; of course, the curved guide rail 1 can be not only in a two-dimensional plane, but also in a three-dimensional space, that is, it can also be a three-dimensional curved guide rail, so that the sliding block 2 can move in the three-dimensional space, and is not limited to the two-dimensional plane, and the flexibility is higher.

Meanwhile, the above-mentioned "disposed" and "disposed" include various connection manners such as fixed connection and detachable connection, and the same also applies to the "disposed" and "disposed" mentioned later in this embodiment.

Referring to fig. 1 to 4, preferably, the curved guide rail 1 includes a first arc segment guide rail 102 and a second arc segment guide rail 104, and the arc opening direction of the first arc segment guide rail 102 is opposite to the arc opening direction of the second arc segment guide rail 104, that is, the first arc segment guide rail 102 and the second arc segment guide rail 104 are protruded toward different directions.

Through first arc guide rail 102 and second arc guide rail 104, guarantee that curve guide rail 1 has two minimum departments of bending, guarantee that slider 2 can carry out twice at least diversion in a two-dimensional plane. Compared with the traditional linear guide rail moving mode, the moving mode is more flexible and changeable.

Referring to fig. 1 to 4, preferably, the curved guide rail 1 further includes a first linear guide 101, a second linear guide 103, and a third linear guide 105, the first linear guide 101, the first arc-shaped guide 102, the second linear guide 103, the second arc-shaped guide 104, and the third linear guide 105 are connected in sequence, the first arc-shaped guide 102 protrudes outward toward one end of the second linear guide 103, and the second arc-shaped guide 104 protrudes outward toward the other end of the second linear guide 103.

Connect gradually through first linear guide 101, first arc section guide 102, second linear guide 103, second arc section guide 104 and third linear guide 105 for curve guide 1 can be an S shape guide, and the shape is pleasing to the eye, and more laminating reality when removing in a two-dimensional plane.

Referring to fig. 1 to 3, preferably, the curved guide rail 1 includes a guide rail body 13 and a support rail plate 11, the support rail plate 11 is connected to the guide rail body 13, for example, the support rail plate 11 may be connected to the bottom of the curved guide rail 1 body, the support rail plate 11 is in a strip-shaped plate-shaped structure and extends along the length direction of the curved guide rail 1, and the slider 2 includes a sliding mechanism, the sliding mechanism is hung on the support rail plate 11, and the slider 2 is prevented from being separated from the curved guide rail 1 by the sliding mechanism being engaged with the support rail plate 11.

Through setting up the region that support rail board 11 provided to slider 2 removal and support, the glide machanism guarantees slider 2 along the removal of curvilinear guide 1 through hanging the mode on support rail board 11, prevents that slider 2 and curvilinear guide 1 from breaking away from.

Referring to fig. 1 to 4, preferably, the top of the guide rail body 13 may also be provided with a support rail plate 11, through which the curved guide rail 1 can be fixed on the roof by the support rail plate 11 provided on the top, and the support rail plate 11 on the top provides an effective area for fixing the curved guide rail 1.

Referring to fig. 1 to 4, preferably, the slider 2 further includes:

a fixed base plate 21; and

the two rotating blocks 22 are rotatably connected to the top of the fixed base plate 21, the sliding mechanism is arranged at the rotating blocks 22 and is provided with two bearing wheels 24, the two support rail plates 11 are respectively arranged on two sides of the guide rail body 13, the guide rail body 13 is arranged between the two bearing wheels 24 so as to prevent the sliding block 2 from being separated from the curved guide rail 1, and the support rail plate 11 is arranged between the bearing wheels 24 and the rotating blocks 22.

Through two bearing wheels 24 respectively arranged on the support rail plates 11 at two sides of the body of the curve guide rail 1, the body 13 of the curve guide rail faces the two bearing wheels 24 for guiding and limiting, and the curve guide rail is ensured not to be separated from the curve guide rail 1, and it can be understood that the bearing wheels 24 not only play a role in guiding the sliding block 2, but also play a role in bearing corresponding structures.

Referring to fig. 1 to 4, preferably, the sliding block 2 further includes a stable moving mechanism, and the sliding block 2 is prevented from shaking when moving along the curved guide rail 1 by the cooperation of the stable moving mechanism and the support rail plate 11.

Preferably, the stable moving mechanism is two retaining wheels 23, the retaining wheels 23 are arranged at the rotating block 22, the wheel edge of the retaining wheel 23 is provided with an annular wheel groove 231, and the two side edges 111 of the supporting rail plate 11 are respectively embedded in the wheel groove 231 of one retaining wheel 23, so as to ensure the stability of the slider 2 during moving.

Here, the load of the bearing wheel 24 is reduced by the holding wheel 23, and the bearing wheel 24 can be used only for bearing under the guiding action provided by the holding wheel 23, so that the structure is more stable, and the sliding block 2 can move without shaking and more stably. Namely, the wheel grooves 231 of the retaining wheels 23 at the front side and the rear side of each group are matched with the side edges 111 of the supporting rail plate 11 in an embedded manner, so that the retaining wheels 23 can only move stably along the curve direction of the supporting rail plate 11, the sliding of the sliding block 2 on the curve guide rail 1 is realized, and meanwhile, the retaining wheels 23 provide certain support and bearing for the medical robot below.

The two sets of the holding wheels 23 in the left-right direction, namely two holding wheels 23 in the front and the back of the supporting rail plate 11, make the running of the holding wheels 23 more stable.

The rotating block 22 is rotatably connected with the fixed bottom plate 21, so that when the walking reaches the radian area of the curve guide rail 1, the rotating block 22 rotates to change the direction at the same time, and the walking can be smoothly carried out.

Here, the turning block 22 may be a U-shaped plate in which the bearing wheels 24 are provided on both side inner walls of the U-shaped plate and the holding wheels 23 are provided in two open grooves on the outside of the U-shaped plate.

Referring to fig. 2, preferably, the top of the slider 2 is provided with a stopper 25, and the stopper 25 is adapted to stop the slider 2 from moving along the curved guide rail 1.

Here, by providing the stopper 25, the slider 2 cannot move on the curved rail 1 continuously after the stopper 25 is actuated, and the medical robot is prevented from moving accidentally, which may cause an undesirable effect. The brake 25 is a conventional brake, and may be, for example, a friction brake that is braked by a frictional force between a braking member of the friction brake and the curved guide rail 1 when the friction brake is activated, and is kept in a stopped state, so as to achieve braking of the slider 2 on the curved guide rail 1.

Referring to fig. 2 to 4, preferably, the curved guide 1 is provided with a rack 12, the rack 12 extends along the curved guide 1, the slider 2 is provided with a gear 26 and a driving motor 27, the driving motor 27 is used for driving the gear 26 to rotate, and the gear 26 is engaged with the rack 12.

For example, the rack gear 12 may be provided at the bottom of the support rail plate 11, and the gear 26 and the driving motor 27 are provided at the top and lower portions of one of the turning blocks 22, respectively.

Here, a protruding surface may be extended on a side of one rotary block 22 away from the other rotary block 22, increasing the area of the rotary block 22, providing a sufficient area position for disposing the driving motor 27 and the gear 26, and not interfering with the rotation of the rotary block 22.

The gear 26 is rotated by the drive motor 27, and the slide 2 is moved "passively" along the curved guide rail 1 by engagement with the fixed toothed rack 12.

Referring to fig. 2, preferably, the holding wheel 23 is rotatably coupled to the rotating block 22, and the bearing wheel 24 is rotatably coupled to the rotating block 22.

By rotatably connecting the bearing wheel 24 and the retaining wheel 26 with the rotating block 22 respectively, sliding friction is converted into rolling friction when the bearing wheel 24 and the retaining wheel 23 walk on the support rail plate 11, and resistance borne by the bearing wheel and the retaining wheel is reduced.

Referring to fig. 1, the present embodiment further provides a medical robot, which includes the aforementioned rail device, and the medical robot is connected to the bottom of the sliding block 2 in the rail device, where the medical robot is a laparoscopic surgical robot, and the laparoscopic surgical robot includes a robot body 3, and the robot body 3 is connected to the bottom of the sliding block 2. This robot 3 includes lifter 31, rotatory support arm 33, telescopic link 34 and the operation manipulator 35 that from top to bottom sets gradually, and wherein the top of lifter 31 is connected with the bottom of slider 2, and lifter 31 and the equal vertical setting of telescopic link 34, rotatory support arm 33 level sets up.

By the lifting function of the lifting rod 31, when an operation is not needed, the rotary arm 33, the telescopic rod 34 and the operation manipulator 35 are suspended at high heights, and when an operation is needed, the rotary arm 33, the telescopic rod 34 and the operation manipulator 35 are moved down to a position slightly higher than the upper part of a patient.

Referring to fig. 1, it is preferable that a plurality of rotary arms 33 are provided, an arm rotary bracket 32 is provided at the bottom of the lifting rod 31, and one ends of the plurality of rotary arms 33 are rotatably coupled in receiving grooves of the arm rotary bracket 32 in a plane perpendicular to the lifting rod 31.

Through setting up a plurality of rotatory support arms 33, and then can set up a plurality of operation hands 35, under the effect of a plurality of operation hands 35 different positions, can be more nimble, more simple and convenient completion operation.

Referring to fig. 1, preferably, the telescoping rod 34 is adapted to move along the length of the rotating arm 33.

The operation manipulator 35 is more flexible through the small-range lifting of the telescopic rod 34, the rotation of the rotary arm 33 and the movement of the telescopic rod 34 on the rotary arm 33.

It should be noted that the specific structure of the robot body 3 may be the prior art, and will not be described herein.

Here, through this kind of suspension type structure, it is little to have the occupation of land space now to the console mode structure, all walk the line and all locate at the high altitude, ground can not have loaded down with trivial details cable, through Z epaxial lifter 31, can rise equipment to the top when not needing the operation, it is very little to walk about of personnel and the visual field influence like this, slider 2 slides on curve guide rail 1 and the mutual motion of each joint realizes the space removal of operation operative hand 35, thereby can accurate person's wound position of conveniently fixing a position on the sick bed, it is more stable and simple to compare cantilever type robot structure, the operation is steady, the location is accurate, better dexterity has, can accomplish more meticulous and complicated operation safely.

Although the present disclosure has been described above, the scope of the present disclosure is not limited thereto. Without departing from the spirit and scope of the present disclosure, those skilled in the art can make various changes and modifications, which will fall into the scope of the present disclosure.

Claims (10)

1. A rail apparatus, comprising:

a curved guide rail (1); and

the sliding block (2) is connected to the curved guide rail (1) in a sliding mode, and the bottom of the sliding block (2) is suitable for being connected with a medical robot;

the curve guide rail (1) comprises a first arc-segment guide rail (102) and a second arc-segment guide rail (104), and the arc opening direction of the first arc-segment guide rail (102) is opposite to the arc opening direction of the second arc-segment guide rail (104).

2. The guide rail device according to claim 1, wherein the curved guide rail (1) further comprises a first linear guide rail (101), a second linear guide rail (103), and a third linear guide rail (105) which are parallel to each other, the first linear guide rail (101), the first arc-segment guide rail (102), the second linear guide rail (103), the second arc-segment guide rail (104), and the third linear guide rail (105) are connected in sequence, the opening direction of the first arc-segment guide rail (102) faces one end of the second linear guide rail (103), and the opening direction of the second arc-segment guide rail (104) faces the other end of the second linear guide rail (103).

3. The guide rail device according to claim 1, wherein the curved guide rail (1) comprises a guide rail body (13) and a support rail plate (11), the support rail plate (11) is connected with the guide rail body (13), the support rail plate (11) is in an elongated plate-shaped structure and extends along the length direction of the curved guide rail (1), and the two support rail plates (11) are respectively arranged on two sides of the guide rail body (13);

the sliding block (2) comprises a sliding mechanism, the sliding mechanism comprises two bearing wheels (24), the two bearing wheels (24) are respectively arranged at the tops of the two supporting rail plates (11), and the guide rail body (13) is arranged between the two bearing wheels (24) to prevent the sliding block (2) from being separated from the curved guide rail (1).

4. Guide rail device according to claim 3, characterized in that the slide (2) further comprises:

a fixed base plate (21); and

the two rotating blocks (22) are respectively and rotatably connected to the top of the fixed bottom plate (21), the bearing wheel (24) is arranged at the rotating blocks (22), and the supporting rail plate (11) is arranged between the bearing wheel (24) and the rotating blocks (22).

5. Guide rail device according to claim 4, characterized in that the bearing wheel (24) is rotatably connected to the turning block (22).

6. The guide rail device according to claim 4, wherein the sliding block (2) further comprises a stable moving mechanism, the stable moving mechanism is two retaining wheels (23), the retaining wheels (23) are arranged at the rotating block (22), a wheel groove (231) in an annular shape is formed at the wheel edge of each retaining wheel (23), and the two side edges (111) of the supporting rail plate (11) are respectively arranged in the wheel grooves (231) of the two retaining wheels (23) to prevent the sliding block (2) from shaking during moving.

7. Guide rail device according to claim 6, characterized in that the retaining wheel (23) is rotationally connected with the turning block (22).

8. The rail apparatus according to claim 3, wherein the curved rail (1) further comprises a rack (12), the rack (12) extends along the length direction of the support rail plate (11), the slider (2) further comprises a gear (26) and a driving motor (27), the driving motor (27) is used for driving the gear (26) to rotate, and the gear (26) is meshed with the rack (12).

9. Guide rail device according to any of claims 1-8, characterized in that the slide (2) is provided with a brake (25) on top, which brake (25) is adapted to stop the movement of the slide (2) along the curved guide rail (1).

10. A medical robot comprising the rail device according to any one of claims 1 to 9.

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