JP5269159B2 - Deterioration diagnosis apparatus for lubricant and viscous material and deterioration diagnosis method thereof - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To use minute amounts of a lubricant and a viscous substance without preprocessing to easily diagnose deteriorated states of the lubricant and the viscous substance. <P>SOLUTION: A deterioration diagnosis device of a lubricant and a viscous substance comprises: a first transparent plate body 33a having a sample reception part slidably placed on one end side of a base 31a having a prescribed length; a second transparent plate body 33b made of glass, which has a sample pressing part for pressing a sample slidably placed on the other side of the base 31a from above so as to be superposed over the sample with a desired load; a driving device 37 which pulls the second transparent plate body away from the first transparent plate body when the sample placed on the sample reception part is radially spread up to a prescribed diameter by receiving the load of the second transparent plate body having the sample pressing part; and measurement means 39 which is provided on the first transparent plate body side and measures peeling force having correlation with the degree in which the sample is deteriorated when the second transparent plate body is pulled by the driving device. <P>COPYRIGHT: (C)2012,JPO&amp;INPIT

Description

  The present invention relates to a deterioration diagnosis apparatus and a deterioration diagnosis method for a lubricant and a viscous material used for a sliding part and a sliding current-carrying part of an operation mechanism part constituting an electrical circuit switch and a mechanism structure.

  Conventionally, lubricants and viscous substances have been used in many operation switches of electric circuit switches and mechanism structures. The properties of these lubricants and viscous substances change with age, due to deterioration over time, oxidative deterioration due to energization and oil separation, corrosive gas and environmental ultraviolet rays in the installation environment, and adhesion of dust and sand. The lubrication performance gradually decreases. Incidentally, when viscosity of viscous materials such as grease increases due to deterioration or oil separation, for example, the resistance to the driving force and the frictional force of the sliding part of the operating mechanism part and the rotating part of the rotating mechanism part increase. This will affect the operating characteristics of the equipment.

  Therefore, it is necessary to grasp signs of deterioration of the lubricant and the viscous material at an early stage before the maintenance of the lubrication function and the operational characteristics of the lubricant and the viscous material are disturbed. For this purpose, a small amount of sample is collected during periodic inspections, etc., the deterioration of lubricants and viscous substances is diagnosed, the degree of deterioration is estimated and the life is predicted, and preventive maintenance such as future replacement timing is planned. It is important to.

  By the way, conventional deterioration diagnosis methods for engine oil, hydraulic oil, lubricating oil, etc. include sulfate group, nitrate group, carbol group, resin content, moisture, total acid value, antioxidant, color, pH, acidity, base There has been proposed a method for determining the degree of deterioration from the measurement result of the increase amount such as the nature, the pollution degree, the electric resistance of the acid, the low molecular weight component of the oil, and the measurement result of the transmitted light amount by the laser light irradiation (Patent Document) 1). Among viscous materials, the penetration method defined in JISK2220 is generally used as a method for measuring the consistency of grease. The penetration method is a measurement method in which a needle is pressed against a surface portion of grease, which is a sample, and a judgment is made by looking at how the needle is lowered.

  However, in this penetration method, it is necessary to collect a sample of at least 5 g, and it is necessary to perform a stirring process about 60 times as a pretreatment for measurement. In addition, since the measurement result obtained by the needle insertion method looks at the stop position when the needle is advanced, it can be considered as a kind of static characteristic different from the general dynamic characteristic movement of the actual machine, It is difficult to accurately grasp the degree of deterioration.

  As a measuring method other than the penetration method, a load was applied from above to a method of measuring the spread area of the sample when the sample was sandwiched between two plates or to two transparent plates sandwiching the sample Thereafter, light is emitted from a light source, and a non-light-receiving area with respect to the spread of the sample is measured by a photoreceptor arranged below (Patent Documents 2 and 3).

  As another degradation measurement method, after filling the cylinder with grease, which is a sample, the pressure at which the grease is pushed out by the piston is measured to measure the apparent viscosity of the grease, or the sample is placed in the cylinder. After the insertion, a screw-shaped rotating blade is put into the sample, and the deterioration is measured from the detection resistance of a resistance detection sensor attached to the rotating blade when the rotating blade is rotated at a predetermined torque ( Patent Document 4, Patent Document 5).

Furthermore, as another method for measuring deterioration, by measuring the absorbance ratio of the base oil in the grease with a wave number of 3500 cm ⁻¹ (peroxide) using infrared rays, regardless of the type of base oil and the presence or absence of additives, deterioration degree was measured infrared absorbance ratio of the wave number 1250 cm ^-1 wavenumber 1250 cm of quantitatively evaluating the base oil of the method and in the grease to ^{-1 (methyl} silicone) and a thickener (grease retaining agent), a small amount of This is a method for measuring the degree of degradation of grease (Patent Document 6, Patent Document 7).
In addition, as a proposal of similar technology, an arbitrary load is applied to the sample by a load increasing / decreasing device using a magnetic wire ring, and the displacement amount of the sample with respect to the load is measured by a displacement measuring device using a differential transformer. There is a method for determining the consistency from the amount of displacement. This measurement method requires a calibration curve that prescribes the relationship between the measured consistency and the amount of displacement in accordance with the standard in advance (Patent Document 8).

JP 08-226896 A JP 58-055838 A JP-A-61-223631 JP 62-119432 A JP 2000-241330 A JP-A 63-263451 Japanese Patent Laid-Open No. 63-053445 JP 60-161545 A

  By the way, the amount of lubricant and viscous material used in the operation mechanism part constituting the electrical circuit switch and mechanism structure subject to deterioration diagnosis as described above is almost insignificant. In many cases, the amount necessary for measuring the consistency cannot be collected. In addition, dynamic characteristics such as initial operation failure due to the hardness of the grease when it is first operated with an actual mechanism operation unit, etc., such as the so-called initial malfunction, are not consistent with measured values of consistency due to the penetration method and spread area. Not reflected. The reason is that the state of the grease in the actual mechanism operation unit cannot be seen.

  In addition, the conventional penetration method and consistency measurement method based on the spread area have large variations in measurement data, such as the area changing depending on the density of the viscous material due to artificial dimensional reading errors and contamination by foreign matter and dust. In addition, pretreatment such as sufficient stirring and removal of impurities is necessary, which is complicated.

  Furthermore, the method using the infrared absorbance ratio requires pretreatment without removing impurities or separating the base oil and the thickener, and although the degree of oxidation of the viscous substance can be grasped, It is difficult to directly grasp the dynamic characteristics of a sex substance.

  On the other hand, it can be presumed that the method of rotating the viscous material with a piston or inserting a rotating blade into the sample to rotate it captures the dynamic characteristics of the viscous material, but requires a certain amount of sample. It is not suitable for measurement of trace samples. In addition, most of the conventional measuring methods have a problem that a calibration curve representing the relationship between the consistency and the spread area measured in advance according to the standard is required.

  The present invention was made in view of the above circumstances, using a small amount of lubricant and viscous material without pretreatment, dynamic characteristics and mechanical characteristics to diagnose the deterioration of these lubricants and viscous materials It is an object of the present invention to provide a lubricant and viscous substance deterioration diagnosis device and a deterioration diagnosis method thereof that can easily grasp the deterioration state of these substances.

  In order to solve the above-described problems, the lubricant and viscous substance (hereinafter referred to as a sample) deterioration diagnosis device according to the present invention can slide to one end on a base having a predetermined length in a rectangular parallelepiped shape. The first transparent plate body provided with the sample receiving portion and the other end side are slidably placed, and the sample placed on the sample receiving portion is superposed with a desired load from above. A glass-made second transparent plate body provided with a sample pressing portion to be pressed against and a sample placed on the sample receiving portion receives a load of the second transparent plate body having the sample pressing portion. A driving device for pulling the second transparent plate in a direction opposite to the first transparent plate when radially spread to a predetermined diameter; and the driving device provided on the first transparent plate side Has a correlation with the degree of deterioration of the sample when the second transparent plate is pulled. Ruhiki off force (shearing force, tensile force) is a configuration that includes a measuring means for measuring.

  Further, the lubricant and viscous substance deterioration diagnosis method according to the present invention is a sample receiving portion upper surface protruding from a first transparent plate that is slidably mounted on one end side on a rectangular parallelepiped base. A first step of applying a sample to a predetermined portion of the sample, and a sample to be applied to the sample receiving portion by protruding to a second glass transparent plate slidably mounted on the other end of the base The second step in which the sample pressing part is set so as to be overlaid with a desired load from above, and when the sample applied to the sample receiving part is enlarged to a predetermined diameter by overlapping the sample pressing part A third step of pulling the second transparent plate in a direction opposite to that of the first transparent plate, and the sample of the sample when the second transparent plate is pulled by the third step. Peeling force (shearing force) that correlates with the degree of deterioration A deterioration diagnosis method and a fourth step of measuring the pulling force).

  According to the present invention, it is possible to grasp the dynamic characteristics and mechanical characteristics for diagnosing the deterioration of these lubricants and viscous substances using a small amount of lubricant and viscous substances without pretreatment. It is possible to provide a lubricant and a viscous substance deterioration diagnosis device and a deterioration diagnosis method for easily diagnosing substance deterioration.

The block diagram which shows embodiment of the deterioration diagnostic apparatus of the lubricant and viscous substance which concern on this invention. The figure which plotted the elasticity modulus, viscosity, and loss tangent (tan-delta) which were calculated | required for every period, rotating a sample alternately with the frequency of 1 Hz, and a fixed amplitude value. The figure which shows the elasticity modulus and viscosity with respect to a new article, a deteriorated product, and a lifetime product. BRIEF DESCRIPTION OF THE DRAWINGS It is a block diagram which shows embodiment of the deterioration diagnosis apparatus of the lubricant and viscous substance which concern on this invention, Comprising: The same figure (a) is a front view, The same figure (b) is a top view. Sectional drawing which shows the fitting state of a stationary base and a transparent plate body. The figure which shows the scale provided in the upper surface part of the sample pressing part provided in one transparent plate body. The shear characteristic figure which shows the relationship between the shift | offset | difference movement distance of a sample, and shear force (tensile force), when the tensile force is given to the said sample 5 times in the same sample. The figure which shows the relationship between the grade of deterioration with respect to the new article of a lubricant, and a viscous substance, a deteriorated product, and a lifetime product, and shear force.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a configuration diagram showing an embodiment of a deterioration diagnosis apparatus for lubricant and viscous material.

  The deterioration diagnosis apparatus is arranged on the lower side, and is arranged on the upper side so as to face the sample measurement system 2 and the sample measurement system 2 for measuring a physical quantity related to the deterioration of the sample 1, and the sample 1 has a desired thickness. The sample setting system 3 and the signal processing unit 4 are set.

  The sample measurement system 2 includes a sample mounting table 12 having a built-in torque sensor 11, a passive element 13 rotatably supported on the sample mounting table 12, and an upper end portion of the passive element 13, which is fixed to the measurement object. For example, a disk-shaped sample receiving plate 14 on which the lubricant 1 and the sample 1 which is a viscous substance are placed is provided. Note that a strain sensor may be used instead of the torque sensor 11.

  The sample measuring system 2 has a function of setting the sample 1 having a predetermined thickness on the sample receiving plate 14 and then repeatedly rotating the passive element 13 alternately at a predetermined frequency and with a predetermined amplitude value.

  The sample setting system 3 includes, for example, a drive control unit 21 such as an actuator driver, and receives a drive control instruction signal from the drive control unit 21 to electrically control the drive. In addition, a sample pressing plate 24 is provided.

  The drive control unit 21 sets a distance for setting the sample 1 to a desired thickness, outputs a drive control instruction signal corresponding to this set distance, and sends it to the drive device 22. The set distance differs depending on the amount of the sample 1 placed on the sample receiving plate 14, and a plurality of different distances may be set as necessary.

  The drive device 22 such as the actuator main body moves the actuator 23 forward by a predetermined distance based on the drive control instruction signal from the drive control unit 21 and lowers the sample pressing plate 24. The sample pressing plate 24 is a disc-shaped plate body having the same diameter as the sample receiving plate 14, and is fixed to the lower end portion of the actuator 23, and is attached to the sample 1 placed on the sample receiving plate 14. A predetermined thickness is set by pressing.

  In the sample measurement system 2, the sample 1 is set to a predetermined thickness and then repeatedly rotated at a predetermined frequency, for example, 1 Hz, and at a constant amplitude. Alternatively, the actuator 23 may be alternately rotated repeatedly in a predetermined direction at a frequency of 1 Hz on the 21 side.

  The reason for setting the frequency to 1 Hz is that when the sample receiving plate 14 is alternately and repeatedly rotated at a predetermined cycle, the bending deformation stress (rotational torque) corresponding to the consistency of the sample 1 is continuously synchronized every cycle. For example, when the frequency increases, the bending deformation stress due to the consistency of the sample 1 cannot follow the repetition cycle at all, and the bending deformation stress cannot be obtained.

Next, the operation of the above-described deterioration diagnosis apparatus and an embodiment of the deterioration diagnosis method will be described.
(1) The distance for advancing the actuator 23 of the drive device 22 by a predetermined distance is set in the drive control unit 21. Further, at the initial stage, the sample receiving plate 14 and the sample pressing plate 24 are set at fixed positions sufficiently separated from each other.

  In the above state, after a small amount of the sample 1 is placed on the central portion of the upper surface of the sample receiving plate 14, a drive control instruction signal corresponding to the set distance is sent from the drive control unit 21 to the drive device 22.

  When the drive device 22 receives the drive control instruction signal, the drive device 22 moves the actuator 23 forward by the set distance. Along with this, the sample pressing plate 24 descends and presses the sample 1 on the sample receiving plate 14. As a result, when the area of the sample 1 increases and expands to an amount corresponding to the entire area of the sample receiving plate 14, a desired thickness corresponding to the set distance is obtained. Then, when the sample 1 is set to a predetermined thickness, the sample 1 protruding outside from the surface portion of the sample receiving plate 14 is wiped off to meet the measurement conditions from the area and thickness of the sample 1 and the specific gravity of the sample 1. Manage the amount.

(2) After the sample 1 on the sample receiving plate 14 has a desired thickness, the passive element 13 on the sample mounting table 12 is set to a frequency of, for example, 1 Hz based on a rotation control instruction from the drive control unit 21 or the signal processing unit 4. In addition, the rotation is alternately repeated at a predetermined amplitude (required rotation angle). At this time, the sample pressing plate 24 is subjected to a force to follow the rotational force of the passive element 13. The torque sensor 11 measures a rotational torque signal (correlated with the rotational angular velocity) corresponding to the bending deformation stress due to the consistency of the sample 1 and sends it to the signal conversion processing unit 4.

  Note that the actuator 23 on the side of the driving device 22 may be alternately and repeatedly rotated at a predetermined frequency and at a predetermined amplitude value. That is, the drive device 22 receives a rotation vibration instruction signal having a frequency of, for example, 1 Hz set by the drive control unit 21 and rotates the actuator 23 alternately and repeatedly at a frequency of 1 Hz and a predetermined amplitude value in a predetermined direction. . At this time, the passive element 13 holding the sample receiving plate 14 measures a rotational torque signal corresponding to the bending deformation stress applied to the sample 1 and sends it to the signal conversion processing unit 4.

(3) The signal conversion processing unit 4 amplifies the rotational torque signal measured by the torque sensor 11 to a required level with an amplifier, and then converts it into a plurality of types of physical characteristic quantities. In other words, the signal conversion processing unit 4 has a proportional relationship between the bending deformation stress in the sample 1 and the rotational torque signal (strain signal). For example, based on Hooke's law, the signal conversion processing unit 4 uses a predetermined conversion constant to move the sample 1. To elastic modulus. Then, by rotating the passive element 13 repeatedly at a constant amplitude of 1 Hz frequency, the dynamic elastic modulus of the sample 1 is obtained for each period, and the passive element 13 is moved until the dynamic elastic modulus becomes a stable value. The sample is rotated repeatedly alternately, and the true elastic modulus of the sample 1 is acquired when entering the stable region. The dynamic elastic modulus stability range time varies depending on the type of sample 1 to be processed. For example, in the case of grease, the dynamic elastic modulus is stabilized by repeatedly rotating at a constant amplitude of 1 Hz frequency for about 200 seconds. To do.

  FIG. 2 shows that the torque signal measured by the torque sensor 11 is rotated by the signal sensor 4 while the passive element 13 is repeatedly rotated at a frequency of 1 Hz and at a constant amplitude. It is the figure which acquired and plotted rate Pb and loss tangent (tan-delta). In addition, the dynamic viscosity Pb of the sample 1 corresponds to energy (heat consumption energy) consumed every time the rotation is repeated at a frequency of 1 Hz and at a constant amplitude. The dynamic viscosity Pb can be assumed that the viscous stress in the viscous material corresponds to a linear function of the deformation rate (strain), and can be expressed by a proportional coefficient to the velocity gradient at that time. The loss tangent (tan δ) can be expressed by vibration absorbency indicating the ratio of the viscosity modulus Pb to the elastic modulus Pa.

  FIG. 3 is a line graph showing the degree of deterioration in the horizontal axis direction and the elastic modulus and viscosity obtained by the signal conversion processing unit 4 in the vertical axis direction. As is apparent from this figure, the lubricant and viscous material are new, deteriorated and life-long products, and the elastic modulus and viscosity of the lubricant and viscous material are graphed. As the degree of deterioration of the viscous material progresses, the elastic modulus and viscosity increase. This is because by measuring physical properties such as the elastic modulus and viscosity of the lubricant and the viscous material, tan δ, between these elastic modulus and viscosity, tan δ and consistency (= degradation degree). It can be seen that it has a high correlation.

  Therefore, according to the embodiment as described above, after the sample 1 is placed on the sample receiving plate 14, the sample 23 is pressed by moving the actuator 23 and the sample pressing plate 24 while moving forward by a predetermined distance. After that, the sample receiving plate 14 side or the sample pressing plate 24 side is alternately and repeatedly rotated at a predetermined frequency and with a predetermined amplitude value, and according to the bending deformation stress of the sample 1 at that time Since the torque signal is taken out and a physical quantity serving as an index of deterioration of the sample 1 is obtained, dynamic characteristics including the initial operation failure of the lubricant and the viscous substance can be taken out, and the deterioration state can be easily grasped. it can.

  In addition, in order to extract the dynamic characteristics of lubricants and viscous substances, large-scale pretreatment is not required, and no calibration curve is required, and the deterioration state can be grasped relatively quickly without complicated work. it can.

  FIG. 4 is a view showing an embodiment of the lubricant and viscous substance deterioration diagnosis device according to the present invention, in which FIG. 4 (a) is a front view and FIG. 4 (b) is a top view.

  This deterioration diagnosis apparatus is arranged so that two metal bases 31a and 31b each having a rectangular parallelepiped shape face each other. Concave grooves 32a and 32b are formed along the longitudinal direction of the upper surfaces of the bases 31a and 31b, and transparent plates 33a and 33b such as glass are formed in the grooves 32a and 32b to the height of the transparent plates 33a and 33b. For example, the fitting is performed so as to enter about one-sixth of the height, and the lateral displacement of the transparent plate bodies 33a and 33b is prevented (see FIG. 5).

  The transparent plate 33a placed on the base 31a is cut out in an L shape in the right direction in the figure from a position that bisects the longitudinal direction to form a flat sample receiving portion 34a, while the transparent plate 33a is placed on the base 31b. The transparent plate 33b to be placed is cut out in an inverted L shape in the left direction in the figure from a position that bisects in the longitudinal direction to form a flat sample pressing portion 34b. That is, the sample receiving portion 34a of the transparent plate 33a and the sample pressing portion 34b of the transparent plate 33b positioned above the sample receiving portion 34a are completely overlapped.

  At this time, in order to enable the transparent plate bodies 33a and 33b to move in the horizontal direction in the drawing, the transparent plate members 33a and 33b are transparent on the other side and the tip portions of the sample receiving portions 34a and the sample pressing portions 34b. A predetermined gap 35 is provided between the opposing surfaces of the plate bodies 33b and 33a.

  In addition, although the glass plate body was used for the transparent plate body 33a, for example, a light acrylic plate body may be used. On the other hand, since the transparent plate 33b requires an appropriate weight, it is desirable to use a glass plate.

  And the scale 36 as shown in FIG. 6 is given to the predetermined area | region of the upper surface part of the sample pressing part 34b of the transparent plate 33b. The scale 36 is marked with an interval of 0.5 mm in each of the X-axis direction and the Y-axis direction, and circles with an interval of 5 mm are drawn outward from the center. The reason for marking circles with 5 mm intervals and marking with 0.5 mm intervals in the X-axis direction and Y-axis direction is to make it possible to visually read the set position and spread diameter of the lubricant and viscous material. Because of that.

  A drive control unit 38 such as an actuator driver is connected to a right end portion of the transparent plate 33a in the figure via a drive device 37 such as an actuator main body that is electrically driven and controlled. The drive control unit 38 transmits a tensile force instruction signal for pulling the transparent plate 33 a to the right side in the drawing with a required tensile force to the drive device 37. The drive device 37 receives the tensile force instruction signal and pulls the transparent plate 33a in the right direction in the figure. In addition, the structure which connects the tension | pulling spring which has a predetermined spring force to the transparent plate 33a at a required timing, and pulls the transparent plate 33a may be sufficient.

  Further, a signal processing unit 40 is connected to the left end portion of the transparent plate 33b in the figure via a load cell 39. The load cell 39 measures the peeling force of the sample 1. The signal processing unit 40 receives a signal corresponding to the peeling force measured by the load cell 39, converts it into a shearing force and a pulling force, and outputs it.

Next, the operation of the deterioration diagnosis apparatus as described above and an embodiment of the deterioration diagnosis method according to the present invention will be described.
(1) First, after applying a lubricant or a viscous substance collected from an electric circuit switch or an operation mechanism part of a mechanism structure to a predetermined position of the sample receiving part 34a of the transparent plate 33a, the sample receiving part 34a is applied. The transparent plate 33b is placed on the base 31b so that the sample pressing portion 34b of the transparent plate 33b is overlaid.

(2) In this state, since the sample 1 on the sample receiving portion 34a spreads under the load of the transparent plate 33b, the spread of the sample 1 through the scale 36 after a certain time has elapsed after placing the transparent plate 33b. By reading the diameter and using at least the transparent plate 33b as a glass plate, bubbles and foreign substances are caught in the sample 1 from the spread sample 1, and the degree of adhesion is further observed and recorded.

(3) When it is determined that there are few air bubbles and foreign matters in the sample 1 and the measurement is sufficient from the degree of adhesion, the drive control unit 38 is operated, a tension control instruction signal is sent out to the drive device 37, and the drive is performed. The transparent plate 33b is pulled in the right direction in the drawing by the device 37.

(4) When the transparent plate 33b is pulled rightward in the drawing by the drive device 37, the transparent plate 33b gradually moves rightward, and accordingly, the amount of deviation (shearing force) corresponding to the consistency of the sample 1 is obtained. Appear. Thereafter, as the pulling force by the driving device 37 increases, the phenomenon in which the sample 1 tends to shift in the opposite directions along the surface portion of the sample receiving portion 34a, that is, the action of being peeled off from each other, works. The transparent plate 33a moves little by little in the right direction in the figure.

  At this time, the load cell 39 takes out a signal having a level proportional to the peeling force (shearing force, pulling force) according to the consistency of the sample 1 through the transparent plate 33 b and sends it to the signal processing unit 40. The signal processing unit 40 amplifies the level signal measured by the load cell 39 by the load cell amplifier, and then calculates and outputs the required peeling force (shearing force, pulling force).

  FIG. 7 is a diagram showing the shear characteristics of Sample 1. FIG. This figure is an experimental example in which the shear characteristics are obtained for the same sample 1 over the number of times N = 5. Originally, the five shear characteristics are expressed in a state of being overlapped with each other. For convenience of explanation, they are shown side by side in the horizontal axis direction for easy viewing. In this figure, the horizontal axis indicates the displacement movement distance of the sample 1 when the sample 1 is pulled through the transparent plate 33b, and the vertical axis indicates the shear force F. In addition, the illustration (A) of each shear characteristic starts to be pulled, the apex (B) of each characteristic is the maximum shear force (tensile force), the illustration (C) is the convergence point where the sample 1 is fully extended, and the illustration (D) is The shift distance (mm) of the sample 1 is shown.

  As is clear from this figure, as can be seen from the results of the five experiments, in the case of the same sample 1, there is no significant change in each maximum shear force. Thus, the maximum shear force obtained by the five experimental results is averaged to obtain the maximum shear force F of the sample 1.

FIG. 8 is a diagram showing the relationship between the degree of deterioration of the lubricant and the viscous material and the maximum shearing force (tensile force) F based on the experimental results of FIG. As shown in the figure, when the maximum shearing force F is obtained by the experiment shown in FIG. 6 for a new product at the beginning of use and a deteriorated product that has been used for a long time and two life products 1 and 2 that require replacement, In this case, since the lubricant and the viscous substance are in a free-run state, the maximum shearing force F is smaller than that of the deteriorated product and the two life products 1 and 2, but as the deteriorated product and the life products 1 and 2 are obtained. Maximum shear force F increases. This is because the lubricant and viscous material gradually harden in the case of the deteriorated product and the life product 1 and 2, so from Fig. 8, mechanical properties such as the shear stress and tensile stress of the lubricant and viscous material are obtained. By measuring the characteristics, it can be seen that there is a high correlation between these shear stress, tensile stress and consistency (= deterioration degree).

  Therefore, according to the embodiment as described above, after the sample 1 is placed on the sample receiving portion 34a of the transparent plate 33a, the sample pressing portion 34b of the transparent plate 33b is placed so as to overlap and a load is applied. Then, the transparent plate 33b is pulled by the driving device 37, and at that time, the peeling force (shearing force, pulling force) of the sample 1 applied to the transparent plate 33a is measured via the sample 1, and thus becomes an indicator of deterioration. By obtaining the mechanical characteristics, it is possible to easily grasp the deterioration state of the lubricant and the viscous substance as in the embodiment described above.

  In addition, in order to extract the mechanical properties of lubricants and viscous substances, no extensive pretreatment is required, and no calibration curve is required, so that the deterioration state can be grasped relatively quickly without complicated operations. it can.

  In addition, the present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the scope of the invention. For example, in FIG. 4, the two metal bases 31 a and 31 b having a rectangular parallelepiped shape are arranged so as to face each other, but one metal base having a rectangular parallelepiped shape having an equivalent length may be used.

  DESCRIPTION OF SYMBOLS 1 ... Sample, 2 ... Sample measurement system, 3 ... Sample setting system, 4 ... Signal processing part, 11 ... Torque sensor, 12 ... Sample mounting stand, 13 ... Passive element, 14 ... Sample receiving plate, 21 ... Drive control part, DESCRIPTION OF SYMBOLS 22 ... Drive device, 23 ... Actuator, 24 ... Sample pressing plate, 31a, 31b ... Metal mounting base, 32a, 32b ... Groove, 33a, 33b ... Transparent plate body, 34a ... Sample receiving part, 34b ... Sample A pressing unit, 36 ... scale, 37 ... driving device, 38 ... drive control unit, 39 ... load cell, 40 ... signal processing unit.

Claims (3)

In a lubricant and viscous substance deterioration diagnosis device for diagnosing deterioration of a lubricant and a viscous substance (hereinafter referred to as a sample),
A first transparent plate body provided with a sample receiving portion and slidably placed on the other end side on one end on a base having a predetermined length of a rectangular parallelepiped shape, and the sample A second transparent plate made of glass provided with a sample pressing portion that presses the sample placed on the receiving portion so as to overlap with a desired load from above;
When the sample placed on the sample receiving portion receives the load of the second transparent plate having the sample pressing portion and expands radially to a predetermined diameter, the second transparent plate is moved to the first transparent plate. A driving device that pulls in a direction opposite to the transparent plate body of
A peeling force (shearing force, pulling force), which is provided on the first transparent plate body side and has a correlation with the degree of deterioration of the sample when the second transparent plate body is pulled by the driving device, is measured. An apparatus for diagnosing deterioration of a lubricant and a viscous substance, characterized by comprising a measuring means. In the lubricant and viscous substance deterioration diagnosis device according to claim 1,
An apparatus for diagnosing deterioration of a lubricant and a viscous substance, characterized in that a scale is provided on the top surface of the sample pressing portion so that the spread diameter of the sample is visible. In the lubricant and viscous substance deterioration diagnosis method for diagnosing sample deterioration,
A first step of applying a sample to a predetermined portion of the upper surface of a sample receiving portion protruding from a first transparent plate that is slidably mounted on one end side of a base having a rectangular parallelepiped shape;
The sample is pressed against the second glass transparent plate that is slidably mounted on the other end on the base so that the sample applied to the sample receiving portion is overlaid with a desired load from above. A second step of setting the part,
When the sample applied to the sample receiving portion expands to a predetermined diameter by overlapping the sample pressing portion, the second transparent plate is pulled in a direction opposite to the first transparent plate. 3 steps,
And a fourth step of measuring a peeling force (shearing force, pulling force) having a correlation with a degree of deterioration of the sample when the second transparent plate is pulled by the third step. Characterized lubricant and viscous material deterioration diagnosis method.

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