UA148035U - DEVICE FOR DETERMINATION OF WEAR RESISTANCE OF STRUCTURAL DENTAL AND NATURAL MATERIALS - Google Patents

Abstract

The device for determining the wear resistance of structural dental and natural materials contains a base mounted on the frame, a beam mounted on the frame on the axes and equipped with a flat return spring and compression bar, upper and lower sample holders, a load mechanism consisting of a camshaft, drive rotation of the two-cam shaft and installed in the beam of the spring-loaded pusher with a cylindrical cavity, which houses the holder of the upper sample, made in the form of a spring-loaded rod. On the cylindrical surface there is a longitudinal groove, which includes a pin mounted in a radial hole made in the pusher, and measuring and recording equipment. It additionally includes a single-cam shaft, a bevel gear, one of the wheels of which is mounted on the double-camshaft of the device and the other on the single-cam, and sliding guides, which are fixed on the base and on which a spring-loaded lower sample holder is mounted. In this case, the cam of the single-cam shaft is installed with the possibility of interaction with the side surface of the holder of the lower sample, in addition, on the inner cylindrical surface of the beam is made a longitudinal groove that interacts with the pin.

Description

A useful model belongs to the field of medicine, namely to dental testing techniques, and can be used to determine the wear resistance, strength characteristics and fracture kinetics of samples of a wide class of dental materials, including filling materials and materials for orthopedic structures, as well as for the selection of adhesive systems in filling of carious cavities and fixation of partial orthopedic restorations.

A well-known device for determining the wear resistance of materials used in dentistry (Russian Patent No. 2636398, IPC AbI1S 19/04 (2006.01), Publ. 23.11.2017, Byul. 331, containing a vessel into which a model medium is poured, which by its acidic -alkaline parameters and chemical-biological composition close to the patient's oral fluid. At the bottom of the vessel, samples of the materials under study are placed with a flat working surface. Together with them, a reference sample is installed. Opposite the samples, an ultrasonic emitter connected to the model medium is installed with partial immersion in the model environment generator of high ultrasonic frequency (20...40 kHz).Abrasive in the form of powder is also poured into the vessel within 1/3...1/4 of the volume of the model environment.

The research on the known device consists in the excitation of ultrasonic vibrations in the model environment, as a result of which abrasive particles hit the flat working surface of the tested and reference samples. This causes the destruction of these surfaces with a corresponding change in the mass and linear dimensions of the samples.

Wear resistance is assessed by comparing the loss of mass and/or linear dimensions of the tested and reference samples.

The disadvantage of the known device is that it absolutely does not reproduce the contact-force processes that are realized in the human mouth during chewing between the antagonist teeth. Destruction of surfaces is carried out by hydroabrasive wear, which is not observed in the human oral cavity.

A well-known device for determining the wear resistance of structural dental and natural materials, selected as a prototype of a useful model, claimed |A. with. USSR Mo 1118360 A,

IPC Ab1C 19/04, Publ. 15.10.1984, Bull. 38), which includes a base, a frame fixed on it, a beam that is mounted on the frame on the axles and equipped with a flat return spring and a pressure bar, upper and lower sample holders, a loading mechanism consisting of a double-cam shaft, a drive for rotating the double-cam shaft and an installed in the beam of the spring-loaded pusher with a cylindrical cavity, in which the holder of the upper sample is placed, made in the form of a spring-loaded rod, on the cylindrical surface of which a longitudinal groove is made, which includes a pin installed in a radial hole made in the pusher, and measuring and recording equipment.

When the camshaft drive is turned on, the latter starts to rotate. At the same time, one of the two cams interacts with the spring-loaded pusher, the movement of which is transmitted through the spring to the rod - the holder of the upper sample, creating a load in the tested pair. The second cam interacts with the pressure bar and causes the beam to oscillate, giving it back-oscillating movements that ensure sliding between the samples. Thus, a cyclic normal load with sliding of the working surfaces is created between the tested samples using a two-cam mechanism.

One of the disadvantages of the known mechanism is that it does not fully reproduce the kinematics of the interaction of teeth in the human oral cavity: in addition to vertical loading and sagittal movements, during chewing, transverse movements are also carried out, which are not reproduced on the known device. As a result, the stress state that is created on the working surfaces during tests on a known device does not correspond to the stress state that occurs during real chewing. This reduces the accuracy and reliability of the results obtained on the device.

In addition, the known device does not provide for axial fixation of the rod - the holder of the upper sample relative to the beam. This can lead to mutual (azimuth) rotation of the working surfaces of the tested samples during testing, which will also negatively affect the adequacy of the results, especially when testing samples with fillings and partial orthopedic structures.

The purpose of the useful model is to improve the design of the device by introducing an additional kinematic chain, which provides a more accurate reproduction of the kinematics and dynamics of chewing movements when testing the wear resistance of tooth samples.

The task is solved by the fact that the device for determining the wear resistance of structural dental and natural materials, which includes a base, a frame fixed on it 60, a beam that is mounted on the frame on the axes and equipped with a flat return spring and a pressure bar, upper and lower specimen holders, a mechanism load, which consists of a double-cam shaft, a double-cam shaft rotation drive and a spring-loaded pusher with a cylindrical cavity installed in the beam, which houses the holder of the upper sample, made in the form of a reinforced rod, a longitudinal groove is made on the cylindrical surface, which includes a pin installed in the radial the hole made in the pusher and the measuring and recording apparatus, according to the useful model, additionally contains a single-cam shaft, a bevel gear, one of the wheels of which is fixed on a double-cam shaft of the device, and the second - on a single-cam, and slide guides, which are fixed on the base and on which is installed under a sprung lower sample holder, and the cam of the single-cam shaft is installed with the possibility of interaction with the side surface of the lower sample holder, in addition, a longitudinal groove is made on the inner cylindrical surface of the beam, which interacts with the pin.

The introduction of an additional vertical shaft with a cam into the design of the device, which interacts with a horizontal two-cam shaft through a bevel gear, ensures the formation of a kinematic chain that creates transverse transverse movements between the surfaces of the tested samples.

Equipping the device with sliding guides, such as cylindrical ones, provides the possibility of translational movement for the holder of the lower sample.

Making a longitudinal groove on the inner cylindrical surface of the beam, which interacts with the pin, makes it impossible to rotate the samples relative to each other.

In fig. 1 shows the design of the device for determining the wear resistance of structural dental and natural materials, front view; in fig. 2 - section A A in fig. 1.

The device for determining the wear resistance of structural dental and natural materials includes a base 1, a frame 2, a beam 3, a loading mechanism, which includes a shaft 4 with cams 5 and b, and a pusher 7 installed in the beam with a cylindrical cavity 8, which houses a rod 9 - a holder of the upper sample 10. Pusher 7, spring-loaded by spring 11, and rod 9 - by tare spring 12 (fig. 1 and 2).

In addition, a longitudinal groove 13 (Fig. 1) is made in the rod 9, and a longitudinal groove 14 is made on the inner cylindrical surface of the beam Z. In the pusher 7, a pin is installed in the radial hole

Z 15, which limits the stroke of the rod 9 at one end, and prevents the pusher 7 from turning relative to the beam 3 with the other, thus ensuring a constant axial orientation of the sample 10 relative to the antagonist sample 21.

The beam 3 is installed in the frame 2 on the axes 16 (Fig. 1 and 2) and is equipped with a flat return spring 17. The flat return spring 17 is immovably fixed on the beam 3 at one end, and

C5 interacts with the second stop 19 fixed fixedly on the base 1. The pressure bar 18 is fixed fixedly on the beam 3, and the second end interacts with the cam 6.

The holder 20 of the lower sample 21 is installed on sliding guides (for example, cylindrical) 22, which are immovably fixed on the frame 2.

The device also includes a vertically placed shaft 23 (Fig. 1), mounted on a frame 2 with the ability to rotate around its axis, and a bevel gear, which consists of two wheels. The first wheel 24 is fixed on the horizontal shaft 4, and the second wheel 25 - on the shaft 22.

At the other end of the shaft 23, a cam 26 is installed, which interacts with the side surface of the holder 20 of the lower sample 21. The holder 20 itself is spring-loaded by a spring 27 in the direction of force locking of the profile surface of the cam 26 and the side surface of the holder 20.

In addition, the device also includes an electric motor 28, which rotates shaft 4, and measuring and recording equipment, consisting of a counter 29 of the number of cycles of interactions of samples 10 and 21, a strain gauge 30, a strain amplifier 31 and a relay 32.

The device for determining the wear resistance of structural dental and natural materials is used as follows.

Before the tests, test samples 10 and 21 (Figs. 1 and 2), made for example in the form of artificial teeth, crowns of dental prostheses or natural teeth filled or restored by fixing partial orthopedic structures, are weighed, precisely measured linear dimensions or create artificial bases depending on the selected method of determining the value of their wear. After that, samples 10 and 21 are rigidly fixed on holders 8 and 20, respectively. This is done using known technologies: mechanical fastening, dental cement, adhesive mass, etc. At the same time, both samples 10 and 21 mutually orient to the position of interest to the research doctor.

A tare spring 12 is installed in the cylindrical cavity 8, the elastic characteristics of which are chosen, taking into account the necessary force of pressing the samples 10 and 21 during the study. Because a rod 9 is inserted into the cylindrical cavity 8, while compressing the tare spring 12, after which a pin 15 is installed in the radial hole made on the pusher 7 in such a way that one end of it enters the groove 13 made on the cylindrical surface of the pusher 9.

After that, the spring 11 is absorbed on the unit, which consists of the pusher 7, the rod 9, the calibrated spring 12 and the pin 15, and is installed in the hole of the beam C in such a way that the free end of the pin 15 enters the groove 14.

If it is necessary to carry out research with a different force of interaction between samples 10 and 21, a variant of using the device is possible, when a washer (not shown in the figure) of a given thickness is installed on the bottom of the cylindrical cavity 8, creating an additional tension of the calibrated spring 12.

According to the specified kinematic and dynamic test modes, that is, according to the movements of the tested pair of tooth samples (10 and 21), cams 5 and 6 are designed, manufactured and mounted on shaft 22, and cam 26 on shaft 23.

The testing process itself begins by turning on the electric motor 28, which rotates the shaft 4 together with the cams 5 and 6. The cam 6, pressing on the bar 18, gives the Z beam reciprocating oscillating movements. This becomes possible due to the fact that the beam C is installed on the frame 2 on the axes 16. The force locking in the friction pair "profile surface of the cam 6 - flat working surface of the pressure bar 18" is carried out by a flat return spring 17, which is immovably fixed on the side surface of the beam 3, and the opposite end rests against the stop 19, which is immovably installed on the base 1.

The cam 5 interacts with the end surface of the pusher 7, compresses the tared spring 11, which creates a load on the rod 9 - the holder of the upper sample 10. The force closing in this cam pair is carried out by the spring 11.

The rotation of the shaft 4 through a bevel gear, which consists of gears 24 and 25, is transmitted to the shaft 23. The cam 26 fixed on the shaft 23 interacts with the side surface of the holder 20 of the lower sample 21, drives the holder 20, which is mounted on cylindrical guides 22, into motion: it begins to make transverse reciprocating movements, imitating the transverse movements of the jaw.

During the operation of the device, the cam 5 in combination with the pusher 7 ensures the vertical movement of the sample 10 and creates the tare spring 12 specified by the test program

From the load, the cam 6 in combination with the pressure bar 18 and the return spring 17 provides sagittal movements, and the cam 26 together with the holder 29 and the return spring 27 - transverse transverse movements. Together, all these three movements provide a complete imitation of the chewing movements of the human jaw.

There are two options for conducting research on the claimed device.

In the first option, a certain number of interactions between samples 10 and 21, set in advance by the test program, is carried out, which is fixed with the help of counter 29. At the same time, the samples wear out, their mass, linear dimensions and shape change. After that, the device stops, samples 10 and 21 are dismantled from holders 9 and 20, respectively, weighed, linear dimensions and/or artificial bases are measured, and the wear resistance of the sample materials is evaluated based on the change of these parameters.

In the second version of the tests, the interaction of samples 10 and 21 is carried out until fatigue damage occurs on their working surfaces in the form of cracks: cracks, chips, etc. This event causes the appearance of mechanical vibrations in rod 9 and beam 3. These vibrational disturbances are registered using a strain gauge 30 and amplified by a strain amplifier 31. When the set level of vibrations is reached, relay 32 is activated, which turns off the electric motor 27. The number of load cycles is read from the counter 29, which the tested pair of samples withstood.

In both cases, further studies of the worn surfaces of samples 10 and 21 are possible with the help of profilography and/or electron microscopic studies, which are carried out to establish the mechanism of wear of the studied materials.

Claims (1)

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