KR101066065B1 - Measuring apparatus for the coefficient of friction - Google Patents

Abstract

The present invention relates to an apparatus for measuring a friction coefficient, comprising: a mold unit into which a target material to measure a friction coefficient is inserted between a fixed mold and a moving mold, and a pressing unit pressurizing the movable mold to provide a predetermined pressing force to the target material; A drawer which draws out the target material to provide a predetermined pull output, an angle adjusting unit which rotates the mold to adjust the drawing angle of the target material, and a mold heating that heats the mold to provide a predetermined heat to the target material. And a control processor for controlling the pressing part, the drawing part, the angle adjusting part, and the mold heating part to calculate the friction coefficient of the target material from the measured pressing force and the output force.
Friction coefficient measuring apparatus according to the present invention has the effect of measuring the coefficient of friction in accordance with the various temperature ranges and draw angle ranges and various mold conditions to data the coefficient of friction according to various conditions.

Description

Friction Coefficient Measuring Device {MEASURING APPARATUS FOR THE COEFFICIENT OF FRICTION}

The present invention relates to a friction coefficient measuring apparatus, and in particular, the friction coefficient measuring device that can provide optimum data on the friction characteristics of the target material by easily measuring the friction coefficient according to various temperature conditions, the extraction angle and various mold conditions It is about.

Generally, friction refers to a phenomenon in which an object tries to block motion at the contact surface when it starts to move or is in contact with another object. The frictional force is called frictional force. It can be represented by F = μN. (N is the load (normal force) applied to the object perpendicularly, and the proportional constant (μ) at this time is called the friction coefficient.

The coefficient of friction is a value indicating the degree of friction and is not a unique value of a material that can classify the material and depends on a given system. The smoothness of the surface, the material of the object, the presence and absence of lubricants, etc. Will depend.

These friction coefficients and friction characteristics act as an important factor in determining the formability of a certain material, and in particular, when the steel sheet is stamped, breakage caused by a friction failure is one of the problems. In order to solve the problem, it is very important to set the working conditions so as not to cause breakage during stamping molding by accurately measuring the friction characteristics of the steel sheet, especially the coefficient of friction.

Conventional devices for measuring friction and wear characteristics include block-on-ring type testers, pin-on-disk type testers and ball-on -Ball-on-Disk Type tester, reciprocating sliding friction tester, etc.

However, these conventional friction coefficient measuring apparatus has a limit in measuring the friction coefficient according to various temperature conditions, angle conditions, etc. in the actual industrial site, the mold using carbon steel, mold using stainless steel, various heat treatment It is also difficult to measure the coefficient of friction while satisfying such conditions in accordance with various mold material conditions such as used molds.

The present invention is to solve the conventional problems, the present invention is to measure the friction coefficient of the target material according to the various temperature range and draw angle range and the mold material or lubrication characteristics friction to be able to data the coefficient of friction according to various conditions It is to provide a coefficient measuring device.

As a problem solving means of the present invention for achieving the above object,

The mold part into which the target material to measure the friction coefficient is inserted between the stationary mold and the moving mold, the pressing part pressurizing the moving mold to provide a predetermined pressing force to the target material, and the target material is drawn out to produce a predetermined pullout force. A drawing part for providing, an angle adjusting part for rotating the mold part to adjust the drawing angle of the target material, a mold heating part for heating the mold part to provide a predetermined heat to the target material, and the pressing part, the drawing part, and the angle. Disclosed is a friction coefficient measuring apparatus including a control processing unit for controlling an adjusting unit and a mold heating unit and calculating a friction coefficient of a target material from measured pressing force and pull output.

Here, the mold may be coupled to the inside of the front plate of the mold case with an open top, and the movable mold may be slidably moved to a plurality of guide rods horizontally provided inside the mold case.

In addition, the mold case may be bolted to the front plate detachably on both side plates to facilitate the replacement of the fixed mold and the moving mold.

In addition, the angle adjusting portion is provided with a lower base of a predetermined length, an upper base which is slidably movable along the longitudinal direction of the lower base, and is provided on the upper base to rotatably support the mold part through a pair of rotation shafts. It may be configured to include a pair of mold support, and a drive motor for providing a rotational force to the rotating shaft to rotate the mold by a predetermined angle.

In addition, the stationary mold and the moving mold is composed of a mold plate, a mold jig fixed to the back of the mold plate, the mold heating unit is inserted into the inside of the mold plate electric heater for providing a predetermined heat, and It may be configured to include a heat insulating plate installed between the mold plate and the mold jig, and a cooling water line installed along the inside of the mold jig.

Friction coefficient measuring device according to the present invention,

Through the configuration of the mold heating part and the angle control part, there is an advantage that data can be easily calculated by calculating friction coefficients according to various temperature conditions and various drawing angles.

In addition, it is configured to facilitate the replacement of the mold portion has the advantage of calculating the friction coefficient data in the mold conditions having various materials and lubrication characteristics.

In addition, through the friction coefficient data measured under these various conditions, it is possible to provide standardized data on the friction characteristics for optimal molding in actual industrial sites, which can greatly contribute to improving the precision of sheet forming.

In addition to the effects specifically specified as mentioned above, it is added that unique effects that can be easily derived and expected from the characteristic configuration of the present invention can be included in the effects of the present invention.

1 is a perspective view showing the overall configuration of the friction coefficient measuring apparatus according to an embodiment of the present invention,
FIG. 2 is a plan view illustrating a mold part in FIG. 1;
3 is an exploded perspective view of a mold part and an angle adjusting part;
4 is a detailed perspective view of the stationary mold and the moving mold,
5 is a perspective view illustrating a friction coefficient measuring device in a state in which the mold unit is slid forward;
6 is an exemplary view illustrating an operating state of the pressing unit and the extraction unit for measuring the friction coefficient,
7 is an operation example illustrating a change in the extraction angle.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the friction coefficient measuring apparatus according to the present invention.

This embodiment is provided to more completely explain the present invention to those skilled in the art, and the shape, size, etc. of the elements in the drawings are exaggerated as necessary to emphasize a more clear description. Can be expressed.

In addition, in describing the embodiments, in the case where it is determined that the technical features of the present invention may be unnecessarily obscured as a matter already known to those skilled in the art, such as known functions or known configurations, the details of the embodiments will be described in detail. The description will be omitted.

As shown in FIG. 1 to FIG. 4, the friction coefficient measuring apparatus 10 according to the exemplary embodiment of the present invention includes a mold part 100, a pressing part 200, and an angle adjusting part 300. And a drawing unit 400, a mold heating unit 500, and a control processing unit.

Hereinafter, looking at the configuration of the friction coefficient measuring device 10 according to an embodiment of the present invention in more detail,

First, the mold part 100 is a part into which the target material 20 to measure the friction coefficient is input, the mold case 110, the plurality of guide rods 120, the fixed mold 130, and the movement. It may be made including a mold (140).

The mold case 110 may have a substantially rectangular parallelepiped shape, and an upper surface of the mold case 110 may be opened to allow the target material 20 to be drawn out.

The plurality of guide rods 120 are installed horizontally parallel to each other between the front plate 111 and the rear plate of the mold case 110, the guide rods 120 are horizontal of the moving mold 140 At least two or more may be provided as a guide for movement, and four may be installed at both upper and lower sides as shown in the drawings.

The fixed mold 130 and the moving mold 140 may be formed of mold plates 131 and 141, and mold jigs 132 and 142 fixed to rear surfaces of the mold plates 131 and 141, respectively.

The fixed mold 130 is coupled to the inner side of the mold case 110, that is, the front plate 111 of the mold case 110 is fixed to its position.

The movable mold 140 is fitted to the plurality of guide rods 120 so that the slide can be horizontally moved along the guide rods 120.

In order to install the movable mold 140, the mold jig 142 of the movable mold 140 has a rod through hole 143 penetrated by the plurality of guide rods 120 to the guide rod 120. It may be formed corresponding to the number.

 In addition, the fixed mold 130 and the moving mold 140 installed inside the mold case 110 need to be easily replaced to allow measurement according to various mold material conditions, and the mold case 110 for this purpose. The front plate 111 is preferably coupled to both sides of the plate 112 by bolt fastening.

Through this, after removing the bolt fastening to separate the front plate 111, replace the fixed mold 130, and also remove the moving mold 140 from the guide rod 120, and then replace it by reassembly and fixed easily The friction coefficient may be measured by replacing the mold 130 and the moving mold 140 with a mold material having different characteristics.

One side of the mold unit 100 of the above configuration is provided with a pressing unit 200, the pressing unit 200 is moved between the fixed mold 130 and the moving mold 140 by pressing the moving mold 140. It functions to provide a predetermined pressing force to the injected target material 20.

The pressing unit 200 is fixed to the outside of the back plate of the mold case 110, the actuator 210 to generate a pressing force, and the movable jig 142 of the mold jig 142 of the movable mold 140 is detachably connected The pressure rod 220 may be configured to move the pressure 140. The actuator 210 may be a hydraulic cylinder, a pneumatic cylinder, or the like.

And the mold unit 100 of the above configuration is rotatably supported by the angle adjusting unit 300, the rotation angle is adjusted, the angle adjusting unit 300 is the lower base 310, the upper base 320 ), A mold support 330, and a driving motor 350.

The lower base 310 is fixed to the apparatus body 700 as shown in the above drawings, and has a constant length so as to protrude horizontally from the apparatus body 700.

The upper base 320 is installed on the lower base 310, the length is shorter than the lower base 310, it is installed to enable the slide reciprocating movement in the longitudinal direction of the lower base (310).

For this purpose, a rail groove 311 is formed in the lower base 310 in the longitudinal direction thereof, and a rail protrusion 321 that is inserted into the rail groove 311 and slidable is formed in the upper base 320.

The upper base 320 is configured to reciprocate in the front-rear direction along the longitudinal direction of the lower base 310 so that replacement of the target material 20 and replacement of the mold part 100 can be made easier. .

The mold support 330 is fixedly installed on the upper base 320, it is made of a pair of left and right, and are installed at a predetermined distance from each other.

The mold case 110 of the mold part 100 is interposed between the pair of mold supports 330 spaced apart from each other, and both sides of the mold case 110 are paired with a pair of rotating shafts 340. The support is coupled to each of the support 330, and thus, the mold case 110 is rotatable about the rotation shaft 340 to the pair of mold support 330.

The driving motor 350 performs a function of rotating the mold unit 100 by a predetermined angle about the rotating shaft 340 by applying a rotational force to the rotating shaft 340, of the pair of mold support 330 One side mold support 330 may be fixedly installed outside.

The driving motor 350 applies and controls a predetermined rotational force to a rotating shaft such as a geared motor, a stepping motor, a servo motor, or the like, which is connected to the rotary shaft 340 through gear meshing. Various known motors can be employed that can.

Here, the mold part 100 is rotated about the rotation shaft 340 through the angle adjusting part 300. The mold material 100 is configured to rotate the mold part 100 in this manner. This is to allow the angle of withdrawal to be varied.

Therefore, in order to change the withdrawal angle of the target material 20, the rotating shaft 340 has a fixed mold 130 and a moving mold 140 which are in close contact with each other when the center of rotation of the moving mold 140 is pressed. It is preferable to be installed in the mold case 100 and the mold support 330 to be in a horizontal position with the top surface.

The withdrawal unit 400 is provided in the apparatus body 700 directly above the mold unit 100 to provide a predetermined withdrawal output to the target material 20. That is, the withdrawal unit 400 is the fixed mold. Injected between the 130 and the moving mold 140 and pressurized by the pressing unit 200 to pull out the target material 20 fixed to the mold unit 100 at a predetermined withdrawal speed.

The withdrawal unit 400 includes a withdrawal actuator 410 for generating a predetermined withdrawal output, and a withdrawal rod 420 for withdrawing the object material 20 to a predetermined withdrawal output by driving the withdrawal actuator 410. The lower end of the withdrawal rod 420 is provided with a material fixing part 430 for fixing the target material 20. And the take-out unit 400 is provided with a load cell (Loadcell) for measuring the output power.

The mold heating part 500 heats the mold part 100 to provide a predetermined heat to the target material 20.

The mold heating unit 500 may be formed in real molding, such as when the temperature of the mold is increased due to a mold process that is required in accordance with a material characteristic of the target material 20, such as a hot rolled sheet, or a mold process which is continued in the actual molding process. This is to enable more accurate measurement of the friction coefficient of the target material in response to the environment.

The mold heating unit 500 may include an electric heater 510, a heat insulating plate 520, and a cooling water line 530, as shown in FIG. 4.

The electric heater 510 is installed in the mold plates 131 and 141 of each of the stationary mold 130 and the movable mold 140 to heat the respective mold plates 131 and 141.

In order to install the electric heater 510, each of the mold plates 131 and 141 may have a heater hole. And it can be installed by inserting the electric heater 510 into the heater hole.

The insulation plate 520 is fixed between the mold plate 131 and 141 and the mold jig 132 and 142 of each of the stationary mold 130 and the movable mold 140, respectively, and heat generated by the electric heater 510 is fixed. Blocking the transfer to the mold jig 132, 142 serves to prevent damage to other components.

The cooling water line 530 is installed in the mold jig 132, 142 of each of the stationary mold 130 and the moving mold 140, the cooling water flows into the inside. This cooling water line 530 is to prevent damage to other components by cooling the mold jig 132, 142.

In addition, a temperature sensor 540 may be installed on the mold plates 131 and 141 to measure the temperature of the mold plate. As the temperature sensor 540, a thermocouple (TC, Thermo Couple) having good durability may be used. have.

The control processing unit (not shown) controls the driving of the actuator 210 of the pressurizing unit 200 and the withdrawal actuator 410 of the withdrawal unit 400 to apply a pressing force or output to the target material 20. And control means for controlling the drawing angle or temperature by controlling the rotation operation of the angle adjuster 300 or the heating operation of the electric heater 510, and may be implemented as an electronic circuit means including a microprocessor.

The control processing unit also calculates a friction coefficient from the pressing force and pull output applied to the target material 20 according to the drawing angle or temperature as well as the above-described control function, and has a function of storing the data by storing them. .

Referring to the operation of the friction coefficient measuring apparatus 10 according to an embodiment of the present invention made of a configuration as described above as follows.

5 is a perspective view illustrating a friction coefficient measuring device 10 in a state in which the mold part 100 is slid forward, and FIG. 6 is an operating state of the pressing part 200 and the lead part 400 for measuring the friction coefficient. 7 is an exemplary view illustrating an operation, and FIG. 7 is an operation example illustrating a change in a drawing angle.

In order to measure the coefficient of friction of the target material 20, first, the target material 20 should be fixed to the mold part 100. As shown in FIG. 5, the upper base 320 of the angle adjuster 300 is shown. Slide forward to position the front end of the lower base 310 and then insert the target material 20 between the stationary mold 130 and the moving mold 140.

When the target material 20 is inserted between the stationary mold 130 and the movable mold 140, the pressing unit 200 is operated to pressurize and move the movable mold 140 toward the stationary mold 130.

When the moving mold 140 is moved under pressure, the target material 20 is in a state of receiving a predetermined pressing force between the stationary mold 130 and the moving mold 140 and a state in which a vertical load is applied.

When the fixing of the target material 20 to the mold part 100 is completed, the lower base 310 is placed back so that the mold part 100 is positioned directly below the lead part 400, and the lead part 400 is removed. After fixing the upper end of the target material 20 to the material fixing portion 430 of the, the withdrawal unit 400 is operated to pull out the target material 20 to a predetermined output.

Then, the pressing force and the output force are measured and input to the control processing unit, and the friction coefficient is stored in the control processing unit as calculation data.

On the other hand, the measurement test described above may be performed at various drawing angles as well as the target material 20 is drawn out in a straight state.

In order to measure friction at various drawing angles, the target material 20 is fixed to the mold part 100 in a pressurized state and the upper end portion of the target material 20 is fixed to the lead part 400 in the mold part 100. Rotate the mold unit 100 by operating the drive motor 350 of the angle adjusting unit 300 to the desired withdrawal angle.

In this way, the mold unit 100 is rotated and the drawing unit 400 is operated in the state where the drawing angle is changed, thereby pulling up the target material 20 to a predetermined drawing output, thereby obtaining friction coefficient measurement data according to various drawing angles. .

7 illustrates a state in which a measurement test is performed in a state in which the rotating shaft 340 is rotated 30 °.

In addition, it is possible to measure the friction coefficient according to various temperature conditions, that is, by heating the mold plate 131, 141 by applying power to operate the electric heater 510 of the mold heating unit 500, As the mold plates 131 and 141 are heated, when the temperature is raised to a desired temperature range, the measurement test of the target material 20 may be performed in the same manner as described above.

Through the operation of the mold heating unit 500 it is possible to obtain data on the friction coefficient of the target material 20 according to various temperature ranges.

On the other hand, it is possible to measure the coefficient of friction in the mold conditions having a variety of material properties by replacing the fixed mold 130 and the moving mold 140 of the mold portion 100 with another mold having a different material, lubrication conditions.

When the mold unit 100 is replaced in this way, the upper base 320 of the angle adjusting unit 300 is first moved forward so that the mold unit 100 is positioned outside the device body 700 and other components. After the interference, the bolts are released to separate the front plate 111 of the mold case 110 from both side plates 112.

After the fixed mold 130 is separated from the front plate 111, the mold is replaced with a fixed mold having different material characteristics, and then recombined, and after the moving mold 140 is removed from the guide rod 120, another material characteristic is also removed. Replace it with a moving mold with a fitting back to the guide rod (120).

After the mold is replaced, the front plate 111, which has been separated, is bolted to both side plates 112 again to complete the replacement, thereby measuring the coefficient of friction under mold conditions having various material properties.

As described above, the friction coefficient measuring apparatus 10 according to the present invention can measure the coefficient of friction in the mold conditions having various draw angles and temperature conditions and various material characteristics can be optimally utilized in actual industrial sites It can be seen that various friction coefficient data can be efficiently provided.

As mentioned above, preferred embodiments of the present invention have been described, but the technical scope of the present invention is not limited to the above-described embodiments and drawings, and is modified or changed by those skilled in the art. Equivalent configuration will be made without departing from the scope of the technical idea of the present invention.

Referring to the symbols for the main parts of the accompanying drawings as follows.
10: friction coefficient measuring device 20: target material
100: mold part 110: mold case
120: guide rod 130: fixed mold
140: moving mold 200: pressing unit
210: actuator 220: pressure rod
300: angle adjuster 310: lower base
320: upper base 330: mold support
340: axis of rotation 350: drive motor
400: withdrawal part 500: mold heating part
510: electric heater 520: heat insulation plate
530: cooling water line

Claims (5)

A mold part into which a target material to measure a friction coefficient between the fixed mold and the moving mold is inserted;
A pressing unit pressurizing the moving mold to provide a predetermined pressing force to a target material;
A drawing unit which draws out the target material and provides a predetermined drawing output;
An angle adjusting unit rotating the mold to adjust a drawing angle of the target material;
A mold heating part for heating the mold part to provide predetermined heat to a target material; And
And a control processor for controlling the pressing part, the drawing part, the angle adjusting part, and the mold heating part and calculating a friction coefficient of the target material from the measured pressing force and the output force. The method of claim 1,
The mold part,
Friction coefficient measuring device, characterized in that the fixed mold is coupled to the inside of the front plate of the mold case with an open top and the movable mold is slidably installed on a plurality of guide rods provided horizontally inside the mold case. The method of claim 2,
The mold case is a friction coefficient measuring device, characterized in that the front plate is detachably bolted to both side plates to facilitate the replacement of the fixed mold and the moving mold. The method of claim 1,
The angle adjustment unit,
Lower base of constant length;
An upper base installed to slide in the longitudinal direction of the lower base; And
A pair of mold supports provided on the upper base to rotatably support the mold unit through a pair of rotation shafts; And
Friction coefficient measuring apparatus comprising a; drive motor for rotating the mold by a predetermined angle by providing a rotational force to the rotating shaft. The method of claim 1,
The fixed mold and the moving mold is composed of a mold plate, a mold jig fixed to the back of the mold plate,
The mold heating unit,
An electric heater inserted into the mold plate to provide a predetermined heat;
An insulation plate installed between the mold plate and the mold jig; And
Friction coefficient measuring device comprising a; coolant line installed along the inside of the mold jig;

Images