KR0157705B1 - Base table transferring means of real weight force standard - Google Patents

Abstract

The present invention relates to a reference table conveying means of a real-load force standard to increase the transfer efficiency of the reference table and to stably apply a square load to the force measuring device. A guide table having respective guide balls and having a predetermined interval in the longitudinal direction at the center thereof and having a ride ball formed thereon; A guide shaft mounted through each guide hole formed in the reference table and connected to the upper support and the lower support; A lead screw fixedly mounted while penetrating through each lead hole formed in the reference table on the upper support and the lower support like the guide shaft; A transmission unit spirally coupled to the lead screw and having an inner diameter spiral formed therein and a tooth formed outside; The reference table conveying means of the actual load force standard, characterized in that the power unit is engaged with the teeth of the transmission portion and composed of a power unit mounted in the longitudinal direction on the bottom surface of the reference table.

Description

Reference table feed means of the actual load force standard

1 is a mounting state of the reference table conveying means of the actual load force standard of the present invention.

Figure 2 is an exploded perspective view of the reference table feed means of the actual load force standard of the present invention.

3 is a mounting state of the reference table transfer means of the conventional actual load force standard.

4 is a perspective view of a conventional actual load force standard machine reference table conveying means,

(a) is by two lead screws,

(b) is with four lead screws.

* Explanation of symbols for main parts of the drawings

1: Standard load force standard 10: Transfer means

12: reference table 13: mounting plate

14: guide shaft 15: bottom plate

16: lead screw 18: electric drive

20: power unit 22: guide ball

24: lead ball 25: linear bearing

26: worm wheel 28: worm

B: Bearing TB: Thrust Bearing

The present invention relates to a reference table conveying means of a real load force standard, and to a reference table conveying means of a real load force standard to increase the transfer efficiency of the reference table and to stably apply a square load to the force measuring instrument.

In general, the weight varies by region, which is caused by the acceleration of gravity depending on latitude and altitude. As a result, the unit of measurement for weighing in each region is different, which causes considerable confusion when the weight measured in one region is transferred to another region. In order to prevent this, there is a need for a unified standard.

The actual load force standard is a device for measuring the weight, and compensates for the above-mentioned gravity acceleration to measure an accurate mass value.

That is, it is possible to apply the weight of the weight (hereinafter referred to as weight) having the correct mass value to the force measuring device to know the exact gravity acceleration of the mass value and the place where the weight is installed, and the buoyancy value of the air that the weight receives Consider. If this is expressed as an expression, it is as follows.

F = m * g _loc (1-p _air / p _m )

Where g _loc is the local gravitational acceleration of the site where the weight is installed

p _air : density of air

p _m : density value of the weight

Based on the above equation, it is possible to generate the desired weight by obtaining the correct mass and density values of the weight.

3 is a state diagram of the mounting table of the reference table transfer means of the conventional actual load force standard, with reference to this description will be described with respect to the actual load force standard 30 to obtain the standard by measuring the actual load.

The actual load force standard (30) is to generate a force by using a weight as described above, for high precision force measurement generates only a vertical load by gravity and transmits to the force measuring instrument, horizontal load, bending and torsion It should be a structure that does not generate loads. It is not only used as a national standard of force, but also used for the test and calibration of high precision force measuring instruments such as load cells.

The conventional general load-force standard 30 supports the upper support portion 31 formed on the upper portion and the lower support portion 32 formed on the lower portion with four pillars 33, and a self-weight frame 34 therebetween. Is equipped. In addition, the upper support portion 31 is provided with a control unit 35 for adjusting the position by moving the self-weight frame 34, the reference frame 36 is installed on the self-weight frame 34 Bar, the lead screw 38 is passed to the left and right portions of the reference table 36 to move the upper support portion 31 and the lower support portion 32.

In addition, a weight (not shown) is installed in the self-weight frame 34, and the force measuring device 100 to be tested is placed on the reference table 36.

At this time, the distance between the bottom surface of the upper plate 34a constituting the self-weight frame 34 and the upper surface of the force measuring device 100 should be about 1 to 2 mm to determine the weight of the self-weight frame 34 by the force measuring device 100. Can be added to. However, since the height of the force measuring device 100 depends on the capacity and shape of the force measuring device, the reference table 36 should be a structure that can move in the vertical direction of the force standard.

Therefore, a transfer means 40 is required for the reference table 36 to be movable.

4 is a perspective view of the reference table conveying means 40 of the conventional actual load force standard, (a) being by two lead screws, and (b) by four lead screws.

The conveying means 40 rotates by means of a power source (not shown) of the lead screw 38 as an actuating means which is penetrated through the conveying nut holes formed on both sides of the reference table 36, thereby moving the reference table 36 up and down. Move.

(a) shows the case where two lead screws 38 are mounted on the reference table 36 for movement.

The reference table 36 by the two lead screws 38 has the advantage that the structure and operation is simple, but there is a problem in the vertical movement.

In other words, when the reference table 36 moves up and down, the planar direction including the lead screw is relatively stable, but in the vertical direction of the plane, the reference table 36 is not stable due to the thread play of the lead screw 38. ) Is broken horizontally.

When the horizontal of the reference table is broken, there is a problem in that the inclination load is applied to the force measuring instrument, thereby degrading the force generation accuracy of the force standard.

(b) has no problem in the case of the reference table shown in (a), but since four lead screws 38 are provided in the reference table 36, the structure becomes very large and the manufacturing cost is high. .

In addition, in the case of the reference table of (a) and the reference table of (b), since the lead screw is connected to the power source by a chain and indirectly rotated to rotate the lead screw, the lead screw does not have a fixed end but a pivot pot end. Therefore, there is a problem that is unstable when receiving the weight of the reference table.

The present invention has been invented to solve the above problems, an object of the present invention is to reduce the number of installation of the lead screw to move the reference table to reduce the horizontal stability and minimization and complexity of the movement, and is transmitted from the conveying means An object of the present invention is to provide a reference table conveying means of a real load force standard, which enables horizontal movement to be stably up and down by movement, and also has structural stability and realizes precise force measurement.

In order to achieve the above object, the present invention, the reference table is formed with a guide hole in the upper and lower ends, each having a force measuring device is placed up and down and has a predetermined interval in the longitudinal direction at the center; A guide shaft mounted through each guide hole formed in the reference table and connected to the upper support and the lower support; A lead screw fixedly mounted while penetrating through each lead hole formed in the reference table on the upper support and the lower support like the guide shaft; A transmission unit spirally coupled to the lead screw and having an inner diameter spiral formed therein and a tooth formed outside; The reference table conveying means of the actual load force standard, characterized in that the power unit is engaged with the tooth of the transmission and is mounted on the bottom surface of the reference table in the longitudinal direction.

Therefore, when the force measuring device is placed on the reference table and the power unit is operated to transmit power in the horizontal direction, the lead screw fixedly mounted vertically up and down and the spirally mounted transmission unit rotate to ride upward or downward on the lead screw. The reference table mounting the lead screw on the lower side is moved with it.

Hereinafter, the most preferred embodiment of the present invention will be described in more detail with reference to the accompanying drawings.

1 is a mounting state diagram of the reference table transfer means of the actual load force standard of the present invention, reference numeral 1 denotes a real load force standard, and the same parts as those in FIG. 3 are omitted and the same reference numerals are given.

In the actual load force standard 1 of the present invention, the reference table transfer means 10 of the actual load force standard of the present invention is located between the upper support 31 and the lower support 32.

The reference table conveying means 10 eliminates the horizontal stability and minimization and complexity of the reference table when moving the reference table, so that the horizontal movement can be stably up and down by the movement transmitted from the conveying means, and also has structural stability To realize precise force measurement.

Figure 2 is an exploded perspective view of the reference table conveying means 10 of the actual load force standard of the present invention, the reference table 12, the guide shaft 14, the lead screw 16 and the transmission unit 18 and the power unit ( 20).

The reference table 12 is a force standard (100) is lifted up and down, and the guide hole 22 is formed at each of the upper, lower, left and right ends, and has a predetermined interval from both the left and right centers to both sides and leads on the upper and lower center lines The balls 24 are each formed.

The guide shaft 14 is fixedly connected to the upper support 31 and the lower support 32 through the guide hole 22 of the reference table 12. The reference table 12 is moved up and down along the guide shaft 14. For this purpose, the reference table 12 has the same center line as the guide hole 22 and the reference table 12 is linearly moved along the guide shaft 14. A linear bearing 25 is mounted to assist the operation.

The lead shaft 16 is fixedly connected to the upper support 31 and the lower support 32 through the lead hole 24 formed in the reference table 12.

Here, two things are considered.

In order to move the reference table 12 up or down, the reference table 12 may be pushed up or down, and the lead shaft 16 has a spiral formed on an outer side thereof and fixed ends at both sides as described above. Since the inner diameter screw having an inner diameter equal to the diameter of the lead shaft 16 is rotated, it is possible to move up or down along the spiral of the lead shaft 16.

Singgi transmission unit 18 is for this purpose, has an inner diameter spiral having an inner diameter equal to the diameter of the lead shaft 16, and the upper and lower ends for mounting a bearing for smoothly rotating the transmission unit 18 An end is formed.

Since the upper end receives more load than the lower end, a thrust bearing (TB) is additionally mounted to the bearing B which is commonly mounted on the upper and lower ends, and the upper end is formed larger than the lower end.

The worm gear was used for this rotation because the transmission part 18 performs linear movement on the lead screw 16 by rotation. The worm gear is preferable to using other racks because of the high precision of its rotation.

Therefore, a worm wheel 26 is formed between the upper end and the lower end of the transmission part 18.

The power unit 20 engaged with the worm wheel 26 of the transmission unit 18 and rotating is mounted across the bottom surface of the reference table 12 in a direction perpendicular to the mounting direction of the transmission unit 18. The power shaft 28 and the worm 27 engaged with the worm wheel 26 formed outside the transmission unit 18 are mounted on the power shaft 28, and the power shaft 28 The motor M is attached to the predetermined end of In addition, shaft bearings 29 are mounted on both ends of the worm 27 so as to smoothly rotate the power shaft 28 on the power shaft 28 by the motor M. FIG. A bracket is formed at a portion of the shaft bearing 29 that is in contact with the bottom of the reference table so that the shaft bearing 29 is fixed to the reference table. As a result, the shaft bearing 29 and the power shaft 28 mounted thereon and the motor M mounted on the power shaft 28 are fixedly mounted on the bottom surface of the reference table 12.

In addition, the mounting plate 13 is mounted between the shaft bearing 29 and the motor M in order to fix and mount the motor M on the reference table 12, and the mounting plate 13 and the reference table. The side surface of (12) can be fixed with a screw or the like.

The bottom of the reference table 12 is the same as the reference table 12 in order to protect the structure after mounting the above configuration in the space formed for mounting the electric drive 18 and the power unit 20, and the like. The bottom plate 15 of the shape was mounted on the bottom surface of the reference table 12.

Accordingly, when the motor is operated to rotate the power shaft, the motor rotates to transmit the rotational force to the worm wheel of the transmission unit engaged with the worm of the power shaft, thereby changing the direction of the motor, and upwardly moves the reference table by riding the lead screw.

Therefore, the present invention is to reduce the number of installation of the lead screw to move the reference table to reduce the horizontal stability and minimization and complexity of the movement, and to make the horizontal movement to the horizontal stability by the movement transmitted from the transfer means, It also has structural safety and has the effect of realizing precise force measurement.

Claims (9)

The reference table 12 having the guide hole 22 formed in each of the upper and lower ends and having a predetermined distance in the longitudinal direction with the lead ball 24 formed thereon is the force measuring device 100 being moved up and down. and; A guide shaft 14 mounted through each guide hole 14 formed in the reference table 12 and connected to the upper support 31 and the lower support 32; Lead screws 16 fixedly mounted through the lead holes 24 formed in the reference table in the upper support 31 and the lower support 32, such as the guide shaft 14, and having a spiral formed thereon; A transmission part (18) spirally coupled to the lead screw (16) and having an inner diameter spiral formed therein, and having end portions for mounting bearings at upper and lower portions thereof; The reference table conveying means of the actual load force standard, characterized in that consisting of a power unit 20 for transmitting the rotational force to the transmission unit 18 and is mounted in the longitudinal direction on the bottom surface of the reference table. The reference table conveying means according to claim 1, characterized in that the reference table (12) has a linear bearing (25) mounted with the same center line as the guide hole (22). The reference table conveying means of the actual load force standard according to claim 1, wherein the reference table (12) has a space for mounting the electric section (18) and the power section (20) on the bottom surface. According to claim 1 or claim 3, wherein the reference table 12 is characterized in that for mounting the electric motor 18 and the bottom plate 15 for protecting the power unit 20 mounted in the space formed on the bottom surface Reference table feed means of the actual load force standard. The reference table conveying means of the actual load force standard of claim 1, wherein the transmission unit (18) mounts a thrust bearing (TB) at the upper end portion. The reference table conveying means according to claim 1 or 5, wherein the transmission unit (18) forms a worm wheel (26) on the outer side. 2. The power unit (20) according to claim 1, further comprising: a worm (27) engaged with the worm wheel (26) of the transmission unit (18); A power shaft 28 mounted with the worm 27 and mounted in a direction perpendicular to the mounting direction of the lead screw 16; Shaft bearings 29 mounted on both sides including a worm 27 mounted to the power shaft 28; Reference table conveying means of the actual load force standard, characterized in that the motor shaft (28) mounted on one side of the power shaft (28) is configured to drive the power shaft (28). 8. The reference table feed of the actual load force standard according to claim 7, characterized in that the shaft bearing (29) has a bracket formed thereon to fix the shaft bearing (29) to the bottom of the reference table (12). Way. The reference table conveying means of the actual load force standard according to claim 7, wherein the motor (M) is fixedly mounted to the reference table (12) by a mounting plate (13).