KR20120076956A - Compression examination press for static load) - Google Patents

Abstract

PURPOSE: A press for measuring a compressive strength is provided to enable to move while upper and lower molds are horizontally maintained because a plurality of upper and lower spindle shafts are simultaneously rotated. CONSTITUTION: A press(100) for measuring a compressive strength comprises an upper mold(10) and a lower mold(20). Each one end part of an upper spindle shaft(60) and a lower spindle shaft(70) are installed to be rotated by penetrating the upper and lower fixing plate so that a press is not interfered with a plurality of guides(50) being joined in between upper and lower fixing plates(30,40). An object is positioned between the upper and lower molds. The compressive strength of the object is measured by pressing the upper mold. A pressing plate(11) being joined to the upper mold is moved up and down by rotating the upper spindle shaft along a guide while being spirally coupled with the upper spindle shaft. The lower mold is moved up and down by rotating the lower spindle shaft according to a size of the object along the guide while being spirally coupled with the lower spindle shaft. When the upper mold presses the object placed on the lower mold between the upper mold and the pressing plate, a load cell measuring a compressive load is installed.

Description

Compression examination press for static load}

The present invention relates to a press for measuring the compressive strength, and in particular, the upper mold is moved horizontally by helical coupling to a plurality of spindle shafts that rotate at the same time so that the pressing force is not biased during pressurization for measuring the compressive strength of the target accurate measurement The present invention relates to a press for measuring compressive strength from which a value can be obtained.

As is generally known, the compression test apparatus is a test apparatus for examining the resistance to compression load and the relationship or strength with deformation caused by the compression test apparatus. It is mainly used to measure the compressive force of the back.

In such a compression test apparatus, first, a sample is prepared in the form of a cylinder or a cube, and the sample is installed in the compression test apparatus.

After applying a compressive load to the sample, the proportional limit, the elastic limit, or the like is measured.

On the other hand, the sample is actually affected by at least two external conditions such as temperature, humidity, and pressure.

As such, the compression test apparatus is placed on the lower mold and the upper mold is moved downward to pressurize the sample. Most compression test apparatuses use one or two hydraulic shafts to transfer the upper mold to one or more hydraulic shafts. When the test is made for two long time, the hydraulic shaft was eccentric and the upper mold was inclined to one side.

In addition, when the upper mold is inclined due to the eccentricity of the hydraulic shaft of the compression test apparatus, the compressive load cannot be evenly applied to the sample, which causes a problem that the sample or the upper mold is damaged or fails to calculate an accurate measurement value.

As a result, when the upper and lower molds move up and down, they can move in a horizontal state to compress the load evenly on the cross-sectional area of the sample to prevent breakage and deformation of the structure and to calculate accurate data values. Test equipment is desperately needed.

Accordingly, the present invention has been made in view of the problems of the prior art as described above, by pressing the upper and lower spindle shafts at the same time installed in a plurality of compression strength measurement presses to allow the upper and lower molds to move in a horizontally maintained state. The purpose is to provide.

Another object of the present invention is to allow the upper and lower molds to be spirally fastened by the rotation of the spindle shaft so that they can be moved so that the pressing force acts evenly on the entire cross-sectional area when the object is compressed to calculate an accurate measured value.

In addition, another object of the present invention is to be installed so that the upper, lower spindle shafts are idle to each other in a straight line form to prevent the bending of the spindle shaft.

In addition, another object of the present invention is to prevent the breakage of the load cell by installing an elastic member having a rubber or similar properties to the top of the load cell to press the object to measure the pressure by pressing the object.

In order to achieve the above object, the present invention provides a plurality of guides coupled between upper and lower fixing plates in a press for measuring an object's compressive strength by placing an object between an upper mold and a lower mold to press the upper mold. One end of the upper spindle shaft and the lower spindle shaft to be rotated through a plurality of upper and lower fixing plates, respectively, so as not to interfere with the upper spindle shaft, and the upper spindle shaft and the lower spindle shaft passed through the upper and lower fixing plates of the upper fixing plate. Each of the upper drive unit and the lower drive unit is configured to be rotated at the same time by receiving rotation, and the upper plate is coupled to the upper mold in the state in which the upper spindle is coupled with the upper spindle shaft in a spirally fastened up and down movement along the guide. The lower mold is rotated by the lower spindle shaft in a spirally coupled state with the lower spindle shaft. It is configured to move up and down along the guide according to the size of the object, and install the load cell for measuring the compression load when the upper mold presses the object placed on the lower mold between the upper mold and the pressure plate, the upper It provides a compressive strength measurement press characterized in that the upper spindle shaft formed of a plurality of the drive unit rotates at the same time to maintain a horizontal state when the upper mold moves up and down, so that the accurate compression load is transmitted to the object.

As described above, the present invention has an effect of allowing the upper and lower molds to move in a horizontal state by simultaneously rotating a plurality of upper and lower spindle shafts.

In addition, the upper and lower molds are spirally fastened by the rotation of the spindle shaft so that they can be moved, so that the pressing force acts evenly on the entire cross-sectional area when the object is compressed to calculate an accurate measured value.

In addition, the upper and lower spindle shafts are coupled to be idle to each other is installed in a straight form is effective to prevent the bending of the spindle shaft.

In addition, the upper mold has an effect of preventing the breakage of the load cell by installing an elastic member on the pressure plate to which the upper surface of the load cell to press the object to measure the pressure.

1 is a front side cross-sectional view showing a press for measuring compressive strength according to the present invention;
Figure 2 is a side cross-sectional view showing a press for measuring the compressive strength according to the present invention,
3 is a plan view showing a press for measuring the compressive strength according to the present invention,
Figure 4 is a bottom view showing a press for measuring compressive strength according to the present invention,
5 is an operation diagram in which the upper mold coupled to the pressing plate is returned to its original position after pressing.

BRIEF DESCRIPTION OF THE DRAWINGS The above and other features and advantages of the present invention will be more apparent from the following detailed description taken in conjunction with the accompanying drawings, in which: FIG.

As shown in Figures 1 to 5, the compressive strength measurement press of the present invention by placing the object between the upper mold 10 and the lower mold 20 to press the upper mold 10 to the compressive strength of the object Regarding the press for measuring, the upper and lower fixing plate 30, 40 is connected to the guide 50, the upper spindle 60 and the lower spindle shaft 70 a plurality of upper and lower fixing plate 30, respectively The upper and lower spindle shafts 60 are rotated by receiving the rotational force of the upper and lower driving units 80 and 90, respectively. The upper mold 10 along the 70 is moved up and down in a horizontal state to press the object placed on the lower mold 20 to constitute a press 100 for measuring the compressive force by the load cell 12.

First, install a plurality of guides 50 are coupled between the upper, lower fixing plate 30, 40.

At this time, the guide 50 is composed of four in the present invention is coupled to the corner side of the upper, lower fixing plate 30, 40.

In addition, one end of the upper spindle shaft 60 and the lower spindle shaft 70 is configured to rotate through the upper and lower fixing plates 30 and 40, respectively, so as not to interfere with the guide 50.

At this time, the guide 50 is composed of four in the present invention is coupled to the corner portion of the upper, lower fixing plate 30, 40.

Here, the upper and lower spindle shafts 60 and 70 may be configured by, for example, that a square spiral is formed on the outer circumferential surface, and the drawing number is not indicated so that the upper and lower fixing plate 30, 40 is idling. The ball bushings are not inserted into the upper and lower fixing plates 30 and 40 and the upper and lower spindle shafts 60 and 70 are coupled to pass through the ball bushings.

At this time, the upper and lower spindle shafts (60) and (70) are each configured in four in the present invention, the coupling is installed on the inner edge portion of the upper and lower fixing plates (30) and (40) on which the guides (50) are installed.

In addition, the upper spindle shaft 60 and the lower spindle shaft 70 are disposed in a straight line on a vertical line.

The rotary end 61 formed at the lower end of the upper spindle shaft 60 is inserted into the rotary groove 71 formed at the upper end of the lower spindle shaft 70 so that the upper spindle shaft 60 and the lower spindle shaft 60 are lower. The spindle shafts 70 are configured to be supported by each other so as not to be eccentric to rotate.

That is, the upper and lower spindle shafts (60, 70) is to perform the function of supporting the upper mold 10 and the lower mold 20, respectively, to the weight of the upper and lower molds (10, 20) By doing so, the upper and lower spindle shafts 60, 70 is configured to prevent the bending deformation.

In addition, the upper spindle 60 and the lower spindle shaft 70 passed through the upper and lower fixing plate 40 of the upper fixing plate 30, respectively, the rotation drive of the upper driving unit 80 and the lower driving unit 90 It is configured to rotate simultaneously with receiving.

In this case, upper and lower pulleys 62 and 72 are coupled to the upper end of the upper spindle shaft 60 and the lower end of the lower spindle shaft 70, respectively.

Then, the upper and lower pulleys 62 and 72 and the upper and lower belts 64 to receive the driving force of the upper motor 63 and the lower motor 73 of the upper and lower driving units 80 and 90. 74 respectively.

When the upper and lower motors 63 and 73 of the upper and lower driving units 80 and 90 rotate, respectively, the driving force is the upper and lower belts 64 and 74, and the upper and lower pulleys 62 ( The upper spindle 60 or the lower spindle shaft 70, which is transmitted to 72 and formed in plurality, rotates at the same time.

In addition, the upper and lower motors (63) (73) is preferably composed of a stationary motor that can be rotated in the rotational direction in order to move the upper and lower molds (10, 20) up and down, upper and lower belts In order to maintain the tension of the 64 and 74, between the upper and lower motors 63 and 73 and the upper and lower pulleys 62 and 72 and between the upper and lower pulleys 62 and 72, respectively. A plurality of idle pulleys 62a and 72a in contact with the outer surfaces of the upper and lower belts 64 and 74 can be configured.

Thus, the plurality of upper and lower spindle shafts 60 and 70 are configured to be horizontally movable when the upper mold 10 or the lower mold 20 moves upward and downward due to simultaneous rotation.

At this time, the upper and lower pulleys (62, 72) is composed of a timing pulley having a gear formed on the outer peripheral surface.

The upper and lower belts 64 and 74 are formed of timing belts in which gears are formed on an inner surface thereof.

That is, when the upper and lower motors 63 and 73 rotate, the upper spindle shaft 60 is prevented from slipping between the upper and lower pulleys 62 and 72 and the upper and lower belts 64 and 74. ) Or the lower spindle shaft 70 is configured to maintain a constant rotation speed during rotation.

On the other hand, the pressing plate 11 coupled to the upper mold 10 on the lower surface to move up and down along the guide 50 by the rotation of the upper spindle shaft 60 in a state in which the upper spindle shaft 60 is spirally fastened. Configure.

In addition, the lower mold 20 is configured to move up and down along the guide 50 in accordance with the size of the target object by the rotation of the lower spindle shaft 70 in a spirally coupled state with the lower spindle shaft 70.

When the upper mold 10 presses the object placed on the lower mold 20 between the upper mold 10 and the pressure plate 11, the load cell 12 is installed to measure the compression load.

In this case, the load cell 12 is connected to communicate with the display device in order to transmit a sense pressure to the display device (not shown) as a signal.

Then, the cutting groove 13 is formed in each corner portion of the upper mold 10, and then the load cell 12 is inserted to fix the lower portion of the pressure plate 11.

In addition, after forming the insertion groove (11a) on the lower surface of the pressure plate 11 which the upper surface of the load cell 12 touches the elastic member 14 is inserted.

At this time, the elastic member 14 may be made of a rubber material as a synthetic resin material.

As a result, the load cell 12 is configured to prevent damage due to direct contact with the pressure plate 11.

On the other hand, the upper mold 10 and the pressure plate 11 is finely spaced by the guide bolt 15 and is connected so that the upper surface of the upper mold 10 is in contact with the load cell 12.

In addition, the guide bolt 15 penetrates and is fixed to the upper mold 10 by penetrating the pressure plate 11, and when the upper mold 10 moves upward, the guide bolt 15 moves upward together.

That is, the upper mold 10 is configured to be connected to the spring bolt 16 to be finely pushed upward when the object is pressed to return to the original position.

Here, the spring bolt 16 is tightened or released to adjust the separation distance between the upper mold 10 and the pressure plate 11.

In addition, when the upper mold 10 is pushed to the upper portion when pressing the object and the pressure is released, the upper mold 10 is spaced apart from the pressure plate 11 by the weight of the upper mold 10 and is elastic by the spring 16a of the spring bolt 16. It is configured to maintain a constant interval.

At this time, the spring bolt 16 supports the bolt 16b by a spring 16a coupled between the bolt 16b coupled to the upper mold 10 and the pressure plate 11 through the pressure plate 11. do.

The pressure plate 11 and the lower mold 20 have upper and lower spindles 65 and 75 coupled to each other to be helically coupled to the upper spindle shaft 60 and the lower spindle shaft 70, respectively.

That is, the present invention by rotating the upper drive unit 80 of the plurality of upper spindle shaft 60 is rotated at the same time to maintain the horizontal state when moving the upper mold 10, the exact compression load is delivered to the object It is configured as possible.

Hereinafter, the operation and operation of the present invention will be described.

First, in order to measure the compressive strength of the object using the press 100, the position of the lower mold 20 is adjusted to be included in the vertical movement range of the upper mold 10 in consideration of the height of the object.

At this time, in order to adjust the position of the lower mold 20, when the lower motor 73 of the lower drive unit 90 is operated, the lower belt 74 rotates and the lower pulleys 72 are all rotated.

As such, the lower spindle shaft 70 is rotated at the same time as the lower pulley 72 rotates, thereby being coupled to the lower mold 20 by the spiral fastening of the lower spindle 75 coupled with the lower spindle shaft 70. The lower mold 20 coupled to the lower spindle shaft 70 does not rotate and moves up and down in accordance with the rotational direction of the lower spindle shaft 70 to adjust its position.

Then, the upper mold 10 is moved to press the object placed on the lower mold 20.

At this time, the upper mold 10 is coupled to the lower portion of the pressure plate 11, the pressure plate 11 is moved up and down by the fastening of the spiral according to the rotation of the upper spindle shaft (60) As follows.

In order to adjust the position of the pressure plate 11 so that the upper mold 10 pressurizes the object, when the upper motor 63 of the upper driving unit 80 is operated, the upper belt 64 rotates and the upper pulley 62 simultaneously. ) Are all rotated.

As such, the upper spindle shaft 60 is rotated at the same time as the upper pulley 62 rotates, thereby being coupled to the upper mold 10 by the spiral fastening of the upper spindles 65 coupled to the upper spindle shaft 60. The upper mold 10 coupled to the upper spindle shaft 60 does not rotate and moves up and down in accordance with the rotational direction of the upper spindle shaft 60.

That is, the pressure plate 11 and the lower mold 20 is fastened to the four upper and lower spindle spindles 60 and 70 to prevent the eccentricity to one side, the upper and lower pulleys 62 and 72 are upper The lower belts 64 and 74 are connected to the timing pulley by the timing belt so that the belt does not slip in the pulley, so that the same rotation speed as the motor is independent of the distance between the upper and lower motors 63 and 73. It is rotated so that the moving distance of the four corners of the pressure plate 11 and the lower mold 20 is the same.

At this time, when the upper drive unit 80 is operated to move the pressure plate 11 downward, the upper mold 10 moves downward to press the object while contacting the upper surface of the object.

As such, the upper mold 10 is connected to the pressure plate 11 by the guide bolt 15 to slide the upper mold 10 while pressing the object, and presses the load cell 12 while moving upward.

That is, the recording of the compressive load from the moment when the compressive load is transmitted from the upper mold 10 to the load cell 12 during the pressurization of the object of the upper mold 10 from the moment when the object is destroyed without overcoming the compression limit by continuous pressing The value is sensed by the load cell 12 to display the load value and the proportional limit or the elastic limit with a separate display device.

At this time, the load cell 12 is in contact with the elastic member 14 inserted into the insertion groove (11a) of the pressure plate 11 to measure the compression load value that the upper mold 10 is pushed toward the pressure plate (11). Breakage is to be prevented.

When the compression load measurement of the object is completed, when the upper motor 63 of the upper driving unit 80 is rotated in reverse, the upper spindle shaft 60 is rotated in reverse to move the pressure plate 11 upward.

At this time, the upper mold 10 pressurizing the load cell 12 is lowered by its own weight, the spring 16a of the spring bolt 16 supports the bolt 16b with an elastic force, so that the upper mold 10 Drop to original position and return to original position.

In addition, when pressing the object of the upper mold 10 or when the pressure is completed to move to the lower side by the guide bolt 15 is not eccentric to one side is movable in the vertical direction.

That is, the upper and lower molds 10 and 20 are coupled to the upper and lower spindle shafts 60 and 70 to receive axial rotation and move in a linear reciprocating motion so that the compressive load is not eccentrically to one side. It can be delivered evenly to get accurate measurement values.

In addition, the separation interval and horizontal installation of the upper mold 10 and the pressure plate 11 can be adjusted using the guide bolt 15 or the spring bolt 16 to replace or maintain the guide 50, upper and lower spindles It is simply adjustable without replacement or maintenance of the shafts 60 and 70.

In the above, the present invention has been illustrated and described with reference to specific preferred embodiments, but the present invention is not limited to the above-described embodiments and is not limited to the spirit of the present invention. Various changes and modifications can be made by those who have

10: upper mold 20: lower mold
11: pressure plate 11a: insertion groove
12: load cell
13: cutting groove 14: elastic member
15: guide bolt 16: spring bolt
16a: Spring 16b: Bolt
30: upper fixing plate 40: lower fixing plate
50: guide 60: upper spindle shaft
61: rotating end 62: upper pulley
62a: Idle pulley 63: Upper motor
64: upper belt 65: upper spindle
70: lower spindle shaft 71: rotation groove
72: lower pulley 72a: children pulley
73: lower motor 74: lower belt
75: lower spindle 80: upper drive unit
90: lower drive unit 100: press

Claims (8)

In the press for placing the object between the upper mold 10 and the lower mold 20 to press the upper mold 10 to measure the compressive strength of the object,
The upper and lower fixing plates 30 each have a plurality of ends of the upper spindle shaft 60 and the lower spindle shaft 70 so as not to interfere with the plurality of guides 50 coupled between the upper and lower fixing plates 30 and 40. 40 is installed to rotate through the configuration,
The upper spindle 60 and the lower spindle 60, which pass through the upper and lower fixing plate 40 of the upper fixing plate 30, respectively, transmit the rotational driving of the upper driving unit 80 and the lower driving unit 90, respectively. Take it and rotate it simultaneously,
The pressing plate 11 coupled to the upper mold 10 on the lower surface is configured to move up and down along the guide 50 by the rotation of the upper spindle shaft 60 in a state in which the upper plate 10 is helically fastened to the upper spindle shaft 60. ,
The lower mold 20 is configured to move up and down along the guide 50 in accordance with the size of the object by the rotation of the lower spindle shaft 70 in a spirally coupled state with the lower spindle shaft 70,
Between the upper mold 10 and the pressure plate 11 by installing the load cell 12 to measure the compression load when the upper mold 10 presses the object placed on the lower mold 20,
The upper spindle 80 is formed by a plurality of upper spindle shaft 60 rotates at the same time by rotating the upper drive unit 80 to maintain the horizontal state during the upper and lower movement of the upper mold 10, characterized in that configured to transmit the exact compression load to the object Compression strength measurement press. The lower spindle of claim 1, wherein the upper spindle shaft 60 and the lower spindle shaft 70 are disposed in a straight line on a vertical line, and the rotary end 61 formed at the lower end of the upper spindle shaft 60 is lower. Compression strength measurement, characterized in that the upper spindle shaft 60 and the lower spindle shaft 70 is supported by each other rotated to be inserted into the rotary groove 71 formed at the upper end of the shaft 70 so as not to be eccentric Press. According to claim 1, Upper and lower pulleys 62 and 72 are coupled to the upper end of the upper spindle shaft 60 and the lower end of the lower spindle shaft 70, respectively, the upper and lower driving portion 80 ( The upper and lower pulleys 62 and 72 and the upper and lower belts 64 and 74 are respectively connected to receive the driving force of the upper motor 63 and the lower motor 73 of the upper and lower parts. When the upper and lower motors 63 and 73 of the driving unit 80 and 90 rotate, respectively, the driving force is transmitted to the upper and lower belts 64 and 74 and the upper and lower pulleys 62 and 72, respectively. Compression strength, characterized in that the upper spindle 10 or the lower spindle shaft 70 is formed to rotate at the same time so that the upper mold 10 or the lower mold 20 can be moved horizontally when moving up, down Measuring presses. The upper and lower pulleys 62 and 72 are configured as timing pulleys in which gears are formed on the outer circumferential surface, and the upper and lower belts 64 and 74 are configured as timing belts with gears formed on an inner surface thereof. In order to prevent the sliding between the upper and lower pulleys 62 and 72 and the upper and lower belts 64 and 74, the upper spindle 60 and the lower spindle 60 may rotate. Press for measuring compressive strength, characterized in that configured to maintain a constant number. The upper and lower spindles 65 and 75 are coupled to the pressing plate 11 and the lower mold 20 to be helically coupled to the upper spindle shaft 60 and the lower spindle shaft 70, respectively. Compressive strength measuring press, characterized in that the configuration. According to claim 1, After forming the cutting grooves 13 in each corner portion of the upper mold 10 After inserting the load cell 12 and fixed to the lower portion of the pressure plate 11,
The elastic member 14 is inserted into the lower surface of the pressure plate 11 which the upper surface of the load cell 12 is in contact with the load cell 12 is configured to prevent damage due to direct contact with the pressure plate 11 Press for measuring compressive strength. According to claim 1, wherein the upper mold 10 and the pressure plate 11 is finely spaced by the guide bolt 15 and the upper surface of the upper mold 10 is connected to contact the load cell 12, the upper mold Press force for measuring the compressive strength, characterized in that configured to be connected to the spring bolt (16) so as to return to the original position after the finely pushed to the upper portion when pressing the object (10). The method according to claim 7, wherein the spring bolt 16 is tightened or loosened to adjust the separation distance between the upper mold 10 and the pressure plate 11, the upper mold 10 is pushed upward when pressing the object to release the pressure Compression strength measurement press, characterized in that configured to maintain a constant interval by the elastic force of the spring (16) of the spring bolt 16 and spaced apart by the weight of the upper mold (10).

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