RU205469U1 - STAND FOR CUTTING BLANKS - Google Patents

Abstract

The bench for cutting blanks belongs to instrumentation, namely to laboratory installations used in research and educational activities. The workpiece cutting stand can be used to measure cutting forces and study the chip formation process when cutting anisotropic materials, for example, wood, cutting tools with various parameters (sharpening angle, thickness and height of the tooth, etc.). The workpiece cutting stand includes a frame, cutting a working body, a system of sensors, a table for fastening a workpiece, characterized in that the table is mounted on a frame on a movable axis with the possibility of its rotation relative to the frame, on the surface of the frame located under the table, on circles of different radii, two ring rows are made with the same number of evenly distributed around the circumference of blind tapered holes, and the blind tapered holes of one ring row are located on the bisectors of the corners formed by radial lines drawn through the centers of adjacent holes of another row to the center of the circle on which they are located, while on the outer side surface of the table at an equal distance from each other friend n divisions are made, the number of which corresponds to the number of blind conical holes in each of the annular rows, a control mark is applied to the frame, while two threaded through holes are made in the table, the center of one of which corresponds to the intersection of one of the circumferences of the blind conical holes and a radial line, defining the position of one of the marks on the outer side surface of the table, and the other - the other circle of the location of blind conical holes and a line corresponding to the bisector of the angle formed by radial lines drawn from the marks to the center of the circle on which they are located, while the threaded holes of the table are installed screws with an end facing towards the frame, made in the form of a cone with a taper greater than the taper of blind tapered holes, while arcuate through grooves are made in the table mirrored with respect to each other, the center of bending of the axial line of which coincides with the center of the movable axis of the table , moreover, the fixation of the fixed position of the rotary table relative to the frame at the moment of impact on the workpiece by the cutting working body is ensured by the fact that studs with external threads are fixedly installed on the frame opposite the centers of the arcuate through grooves of the table, which pass through the arcuate grooves of the table, on the outer threaded sections of each of their studs extending beyond the table, a washer and a nut are installed, while the cutting working body is made with the possibility of moving it along the guide. 5 ill.

Description

The workpiece cutting stand belongs to instrumentation, namely to laboratory installations used in research and educational activities. The bench for cutting blanks can be used to measure cutting forces and study the process of chip formation when cutting anisotropic materials, for example, wood, cutting tools with different parameters (sharpening angle, thickness and height of the tooth, etc.).

Known installation for studying the process of cutting materials at low cutting speeds [Installation for studying the process of cutting materials at low cutting speeds. - Electronic resource. - Access mode: https://cyberleninka.ru/article/n/ustanovka-dlya-izucheniya-protsessa-rezaniya-materialov-na-malyh-skorostyah-rezaniya/viewer], which is a modular design, including a microscope, strain gauge station, cutting motion drive, lighting device, photo attachment with control panel, oscilloscope. The main base part of the installation is a Zeiss instrumental microscope, on which the cutting motion drive, a slide table with a stand for setting the workpiece, a dynamometer with a device for fixing the cutting tool, and an optical system for observing the chip formation process are mounted. The modules are interconnected by electrical cables.

The disadvantage of the known installation for studying the process of cutting materials at low cutting speeds is that the workpiece is installed on a table, which is mounted on a rack rigidly fixed on a slide. This design does not allow changing the angle of installation of the workpiece, and thus to study the cutting process at different angles to the structural components of the workpiece on standard samples, for example, wood samples, in which the strength characteristics significantly depend on the direction of cutting relative to the fibers, which is necessary when studying characteristics of the curvilinear cutting process.

Known installation for the study of the cutting process when turning titanium alloys [Installation for researching the cutting process when turning titanium alloys. - Electronic resource. - Access mode: https://www.elibrary.ru/download/elibrary_21701058_83115060.pdf], which is based on the 16B16KA lathe and includes the following measuring systems: a system for measuring the temperature deformation of the cutter, a dynamometer, a chuck for fixing a part, inductive sensors , thermal imager, controller, computer.

The disadvantage of the known installation for studying the cutting process when turning titanium alloys is that the workpiece is installed on a table, which is mounted on a lathe slide. This design does not allow changing the angle of installation of the workpiece and thus to study the cutting process at different angles to the structural components of the workpiece on standard samples, for example, wood samples, in which the strength characteristics significantly depend on the direction of cutting relative to the fibers, which is necessary when studying the characteristics curvilinear cutting process.

The closest in essence and taken as a prototype is a well-known experimental setup, created on the basis of a horizontal console-milling machine [Experimental setup for researching the processes of cutting wood and wood materials. - Electronic resource. - Access mode: http://www.science-bsea.bgita.ru/2019/les_2019/basov_eksperiment.htm], including a massive bed, guide slides, handwheels for controlling the table position with a workpiece, made in the form of steering wheels, a control unit with buttons control, installed in a separate case, fixed on the front side of the bed, laptop.

The disadvantage of the known experimental installation, created on the basis of a horizontal console-milling machine, is that the workpiece is installed on a table, which is mounted on a lathe slide. This design does not allow changing the angle of installation of the workpiece, and thus to study the cutting process at different angles to the structural components of the workpiece on standard samples, for example, wood samples, in which the strength characteristics significantly depend on the direction of cutting relative to the fibers, which is necessary when studying characteristics of the curvilinear cutting process.

The technical result of the proposed stand for cutting workpieces is to improve the convenience of work by facilitating the process of orientation of the workpiece relative to the trajectory of the cutting body.

The technical result is achieved by the fact that in a bench for cutting workpieces, including a frame, a cutting working body, a sensor system, a table for fastening a workpiece, the table is installed on the frame on a movable axis with the possibility of its rotation relative to the frame, on the surface of the frame located under the table, on circles of different radii, two annular rows are made with the same number of blind conical holes evenly distributed around the circumference, and the blind conical holes of one annular row are located on the bisectors of the angles formed by radial lines drawn through the centers of adjacent holes of another row to the center of the circle on which they are located, at the same time, divisions are applied to the outer side surface of the table at an equal distance from each other, the number of which corresponds to the number of blind conical holes in each of the annular rows, a control mark is applied to the frame, while there are two through threaded holes in the table, the center of the location of one of which corresponds to the intersection of one of the circles of the location of blind conical holes and a radial line that determines the position of one of the marks on the outer side surface of the table, and the other - the other circle of the location of blind conical holes and the line corresponding to the bisector of the angle formed by radial lines drawn from the marks to the center of the circle on which they are located, while screws are installed in the threaded holes of the table with the end facing towards the frame, made in the form of a cone with a taper greater than the taper of blind tapered holes, while in the table, mirror-like in relation to each other, arc-shaped through grooves, the center of bending of the axial line of which coincides with the center of the movable axis of the table, and the fixation of the fixed position of the rotary table relative to the frame at the moment of impact on the workpiece by the cutting working body is ensured by the fact that on the frame opposite the centers of the arcuate through grooves of the table it is fixed There are studs with external threads that pass through the arcuate grooves of the table, a washer and a nut are installed on the external threaded sections of each of their studs that extend beyond the table, while the cutting tool is made with the ability to move it along the guide.

FIG. 1 shows a general view of the stand for cutting blanks in isometric view. FIG. 2 shows the main view of the stand for cutting blanks. FIG. 3 shows a top view of a workpiece cutting stand. FIG. 4 shows a sectional view A of the assembly of screws installed in the threaded holes of the table with blind tapered holes made in the frame. FIG. 5 shows a BB section of a bench for cutting blanks, in which the cutting plane is oriented parallel to the frame and passes between the frame and the turntable.

A stand for cutting blanks, including a frame 1, a cutting tool 2, a system of sensors 25, 26, a table 3, which serves to install a blank 4. Table 3 is installed on a frame 1 on a movable axis 5, which makes it possible to rotate the table 3 relative to the frame 1.

On the surface of the frame 1, located under the table 3, on circles 8, 9 of different radii, two annular rows are made with the same number of blind conical holes 10 uniformly distributed around the circumference. lines 11, 12 drawn through the centers of adjacent holes of another row to the center of the circle on which they are located.

On the outer side surface of the table 3 at an equal distance from each other, divisions 6 are applied, the number of which corresponds to the number of blind tapered holes in each of the annular rows.

On the frame 1, a control mark 7 is applied, which serves as a reference point for the number of divisions 6 of the rotation of the table 3.

In the table 3 there are two through threaded holes 13, 14, the center of one of which (for example, 13) is located above one of the circles of the location of the annular rows (for example, 8) of blind conical holes 10, and the center of the other hole (for example, 14) above the other circle (for example, 9). Screws 15, 16 are installed in the threaded holes 13, 14 of the table with the end facing the frame 1, made in the form of a cone with a taper greater than the taper of the blind tapered holes 10.

In the table, mirror-like in relation to each other, arcuate through grooves 17, 18 are made, the center of bending of the axial line 19 of which coincides with the center of the movable axis 5 of the table 3. On the frame 1 opposite the centers of the arcuate through grooves 17, 18 of the table 3, studs 20, 21 s are fixedly mounted external threads that pass through the arcuate grooves 17, 18 of the table 3. On the threaded sections of each of their pins 20, 21, extending beyond the table 3, a washer 22 and a nut 23 are installed.

Stand for cutting blanks works as follows.

The workpiece 4 is installed on the table 3. The nuts 23 and the set screws 15, 16 are turned off. The table 3 is rotated so as to set the workpiece 4 at the desired angle to the cutting tool 2.

The position of the table 3 is controlled by the position of the divisions 6 relative to the reference mark 7. One of the screws 15, 16 is screwed in, the one that is located above one of the blind tapered holes 10. In the event that the divisions 6 are applied so that they coincide with the radial lines made on row 9, then when the division 6 coincides with the control mark 7, screw the screw 16, if the control mark 7 is between the 6 divisions, then screw the screw 15. In this case, the conical end of the screw will enter the tapered hole of the frame, and thereby ensure the correct position of the table 3 relative to the frame 1. Next, the nuts 23 are tightened, and thereby ensure the non-movable position of the table 3 relative to the frame 1.

Then the position of the cutting tool 2 is positioned relative to the workpiece 4, and the working cutting tool 2 is brought into the working position, moving it at a predetermined distance from the workpiece 4.

Next, the drive 24 of the cutting tool 2 is switched on. The cutting tool 2, moving along the guide 27, acts on the workpiece 4. At the moment of the impact of the cutting tool 2 on the workpiece, readings from strain gauges are recorded, one of which 25 is installed on the guide 27, and the other - in the attachment point of the drive 24 to the side frame of the frame 1.

Due to the fact that the table is installed on the frame on a movable axis, it is possible to rotate it relative to the frame, and thereby set the workpiece at a certain angle to the trajectory of the cutting tool.

Due to the fact that two circular rows are made in the frame on circles of different radii with the same number (Z) of blind conical holes uniformly distributed around the circumference and the fact that the number of divisions made on the outer side surface of the table and their location are determined by the position of the radial lines drawn through the centers of blind tapered holes of one row to the center of the circle on which they are located, the location of blind tapered holes inside each row and divisions made on the outer side surface of the table with the same angular pitch (P), defined as

where α is the angle formed by radial lines drawn from the marks to the center of the circle on which they are located;

r is the radius of the circle along which the angular step is measured. For the circumference of the blind tapered holes of a smaller radius - R1, a larger radius - R2, the circumference of the divisions - R3 (Figs. 3, 5).

Due to the fact that the blind tapered holes of one ring row are located on the bisectors of the angles formed by radial lines drawn through the centers of the adjacent blind tapered holes, it is possible to position the table with a pitch (P1 / 2) that is half the pitch of the divisions

This circumstance makes it possible to fix the angular positions of the workpiece installed on the table, not only in the position when the division coincides with the reference mark, but also in their intermediate position.

Due to the fact that two through threaded holes 15, 16 are made in the table, the center of one of which corresponds to the intersection of one of the circles of the location of blind conical holes and a radial line defining the position of one of the marks on the outer side surface of the table, the presence of screws with the end face facing the frame, made in the form of a cone with a taper greater than the taper of blind tapered holes, it is possible to accurately position the position of the table, and with it the workpiece installed on it, relative to the frame by centering the tapered end of the screw and the tapered hole ...

Due to the fact that arcuate through grooves are made in the table mirrored with respect to each other, the center of bending of the axial line of which coincides with the center of the movable axis of the table, and the fact that studs with external threads are fixedly installed on the frame opposite the centers of the arcuate through grooves of the table, which pass through arcuate grooves of the table, and a washer and a nut are installed on the threaded sections of each of their pins extending beyond the table, it is possible to reliably fix the position of the table relative to the frame and thereby hold the workpiece installed on the table in a stationary position at the time of exposure to it by the cutting working body.

The whole set of the given design features allows to increase the convenience in work by facilitating the process of accurate orientation of the workpiece relative to the trajectory of the cutting body. In addition, such a design of the stand for cutting workpieces assumes the movement of the cutting tool, and not the workpiece, as is typical of analogues, which helps to increase the visibility when demonstrating the work and approaching the cutting conditions to real ones, when the cutting tool moves, and the workpiece itself is static on basis.

Claims (1)

Stand for cutting workpieces, including a frame, a cutting tool, a system of sensors, a table for fastening a workpiece, characterized in that the table is mounted on a frame on a movable axis with the possibility of its rotation relative to the frame, on the surface of the frame located under the table, on circles of different radii two annular rows are made with the same number of blind conical holes evenly distributed around the circumference, and the blind conical holes of one annular row are located on the bisectors of the angles formed by radial lines drawn through the centers of adjacent holes of the other row to the center of the circle on which they are located, while on the outer side surface of the table at an equal distance from each other marks divisions, the number of which corresponds to the number of blind conical holes in each of the annular rows, a control mark is applied to the frame, while the table has two through threaded holes, the center of one of which corresponds to the intersection of one of the circles of the location of the blind conical holes and the radial line defining the position of one of the marks on the outer side surface of the table, and the other - the other circle of the location of the blind conical holes and the line corresponding to the bisector of the angle formed by radial lines drawn from the marks to the center of the circle , on which they are located, while screws are installed in the threaded holes of the table with the end facing towards the frame, made in the form of a cone with a taper greater than the taper of blind tapered holes, while in the table, mirror-like in relation to each other, arc-shaped through grooves are made , the center of bending of the axial line of which coincides with the center of the movable axis of the table, and the fixation of the stationary position of the rotary table relative to the frame at the moment of impact on the workpiece by the cutting working body is ensured by the fact that studs with an external re a washer and a nut are installed on the outer threaded sections of each of their pins extending beyond the table, with a washer and a nut, and the cutting tool is made with the ability to move along the guide.

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