BG110436A - Micromanipulator - Google Patents

Abstract

The invention refers to a micromanipulator which finds applications in the automaton of micro- and nano-manipulations in microbiology and in micro- and nano-technologies, in the field of fluids and mechanics, as well as a regulating unit for actuating relays in electrical engineering, medicine, robotics, and others. The micromanipulator consists of a void cylindrical unit (1) and of positioned init three piezoelements (2, 3, 4), one end of which is connected with the front side (5) of the void unit (1) by means of plane and spherical links (6, 7 8) while the other end touches the bearing nests (9, 10, 11) of an integrator (12), which is connected through the spring (13) is attached to the back end (14) of the void unit (1), in the fore side of which there is an axis opening, through which the lever (15) passes one end of which is immovably fastened to the integrator (12), while to the other end, by means of a holder (16), a pipette (17) is fixed.

Description

Technical field

The invention relates to a micromanipulator, which is used for automation of micro and nano manipulations in microbiology and micro- and nanotechnologies, in the field of fluids and mechanics, as well as a control unit for actuating relays in electrical engineering, medicine, robotics, etc.

BACKGROUND OF THE INVENTION

A high-rigidity piezoactive device [1] is known, consisting of a hollow ellipsoid body, in which a large cavity has two piezoelectric elements, one end of which is attached to a hollow body and the other ends are connected by a tension element. representing two wedge-shaped bodies. The wedge-shaped bodies strain the piezoelectric elements, which in turn strain the mechanical construction of the ellipsoid body.

The disadvantage of this device is that it reduces the active part of the displacement generated by the piezo elements.

Another drawback of the device is that it has limited displacements and therefore cannot be used in small workspaces.

The disadvantage is that it gives us translational movement on only one axis of motion.

A piezoelectric device with a motion amplifier [2] is known, consisting of more than two piezoelectric devices mounted by screws to the underside of a movable table. Each piezoelectric device is a hollow elliptical body with two piezoelectric elements arranged in its large diameter, one end of which is attached to a hollow body and the other end rests on a tension element representing two wedge-shaped bodies.

The wedge-shaped bodies strain the piezoelectric elements, which in turn strain the mechanical construction of the ellipsoid body. Through three or four such piezoelectric devices, the mass is driven on three axes, two orienting motions and one translational along the axis of the device.

A disadvantage of the drive device is its limited movement relative to the size of the device, which makes it unsuitable for manipulation of biological and other micro-objects.

Technical essence

It is an object of the invention to provide a micromanipulator for biological micro-objects that enables the automation of the process - injection of cells by accurately positioning and orienting the pipette to cells and other micro-objects.

The task is performed by a micromanipulator consisting of a hollow cylindrical body (1), in which three piezoelements (2,3,4) are placed, one end of which is connected to the front side (5) of the hollow body (1), by plane or spherical connections / 6,7,8 / and their other end rests in bearing sockets / 9,10,11 / of the integrator / 12 / which is connected to the rear end / 14 / of the hollow body by a spring / 13 / / 1 /. The front side (5) of the hollow body (1) has an axial opening through which a lever (15) passes, at which one end is fixed to the integrator (12) and a pipette is attached to its other end by a holder (16). / 17 /.

The three piezoelectric elements are spatially oriented at 120 degrees, and the planes or spherical connections (6,7,8) are pre-stressed by a spring / 18 / to guarantee the desired rigidity of the mechanical system.

The advantage of a micromanipulator is its small, compact and simple design.

Another advantage is that the three piezoelectric elements produce rapid orienting and positioning movements when injecting biological cells up to 800 microns.

The advantage is that the micromanipulator does not need additional forces to exert the structure, thus utilizing the entire movement for rapid positioning and orientation movements.

The advantage is that the micromanipulator allows the automation of the process - injection of cells, which increases productivity and reduces the risk of cell destruction.

Description of the attached figures

The invention is illustrated by the accompanying drawings, where:

Figure 1 is a general view of a micromanipulator in three projections realized with two piezoelectric elements;

Figure 2 is a general view of the micromanipulator in three projections realized with three piezoelectric elements;

Figure 3 is a general view of the robotic system.

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Example of implementation

The task is performed by a micromanipulator consisting of a hollow cylinder body (1), which houses three piezoelements (2,3,4), one end of which is connected to the front side (5) of the hollow body (1), by means of planes or spherical connections / 6,7,8 /, the other end of which rests in bearing sockets / 9,10,11 / of the integrator / 12 / which through a spring / 13 / is connected to the rear end / 14 / of the hollow body / 1 /. The front side (5) of the hollow body (1) has an axial opening through which a lever (15) passes, at which one end is fixed to the integrator (12) and a pipette is attached to its other end by a holder (16). / 17 /.

The three piezoelectric elements are spatially oriented at 120 degrees, and the planes or spherical connections (6,7,8) are pre-stressed by a spring / 18 / to guarantee the desired rigidity of the mechanical system.

Use of the invention

The invention works as follows:

To perform the process of automated injection of cells from control unit 18, control signals are generated to the robot 19, which feeds the pipette 17 of the micromanipulator 20 into the area of the cell holder 21. Control signals 18 produce control signals to one or more of the piezoelements 2 , 3, 4 of the micromanipulator 20. In the case when one is supplied, an orienting micromanage of the pipette 17 is arranged, 120 degrees relative to the same micromanctions of the pipette 17, realized by the other two piezoelements. the case where only them individually fed control signals. By arbitrary combination of the joint work of two or three piezoelectric elements 2, 3,4, an arbitrary orientation of the pipette 17 in the XY plane is achieved. In the case where the control signal is the same and is transmitted simultaneously to the three piezoelectric elements 2, 3, 4, translational micro-displacement is realized along an axis perpendicular to the XU plane for injection of cells with a pipette 17. Thus, after a controlled series of orienting injecting micro-movements 3, the piezoelements , 4 the micromanipulator 189 performs an automated injection of cells from the holder matrix 21 upon visual observation of the process by a encryption video camera 22.

Literature:

Claims (3)

Claims A micromanipulator consisting of a hollow body (1) and piezoelements (2,3,4), characterized in that three piezoelements (2,3,4) are placed in a hollow cylindrical body (1, 4), one end of which is connected to the front / 5 / of the hollow body / 1 / by plane or spherical connections / 6,7,8 / and the other end rests in the bearing sockets / 9,10,11 / of the integrator / 12 /, which, by means of a spring (13), is connected to the rear end (14) of the hollow body (1), has an axial opening through which a lever (15) passes, to which one end is fixed to the integrator (12), and to its other end, by a holder / 16 / , a pipette is mounted / 17 /. The micromanipulator according to claim 1, characterized in that the three piezoelectric elements (2,3,4) are oriented 120 degrees to one another. A micromanipulator according to claim 1, characterized in that the planes or spherical connections (6,7,8) are pre-stressed by a spring (13).