JP4993459B2 - Weighing device and weighing method using the same - Google Patents

Description

  The present invention relates to a measuring device for measuring the amount of air in a sample such as fresh concrete and the like, the volume of a sample such as an aggregate used, and a measuring method using the same.

  Since the amount of air in fresh concrete largely contributes to concrete properties such as strength, it is specified in Japanese Industrial Standard (JIS) A 1128 (Testing Method by Pressure of Air in Fresh Concrete-Air Chamber Pressure Method). . As an air quantity measuring device (air meter) used in this measuring method, for example, those described in Patent Documents 1 to 3 are known. According to JIS A 1128, the air volume of concrete is measured by the following procedure.

(1) After putting the sample to about 1/3 of the container and leveling it, poke each layer evenly 25 times with a stick so as not to poke the bottom of the container. Strike the side of the container 10-15 times with a wooden prick (soot) so that there are no holes and no large bubbles on the concrete surface. Add the sample to about 2/3 of the container and repeat the same operation as before. Finally, the sample is poured so that it slightly overflows from the container, and the same operation is repeated. Then, the excess sample is scraped off with a ruler so that the concrete surface and the upper surface of the container are correctly aligned. The penetration depth of the stick is approximately the thickness of each layer.
(2) After completely cleaning the upper surface of the flange of the container and the lower surface of the flange of the lid, attach the cover to the container and tighten it so that air does not leak. Water is drained from the drainage port, and water is poured from the water injection port with slight vibration until the air between the back surface of the lid and the water surface is expelled. Finally close all valves.
(3) Use an air hand pump to slightly increase the pressure in the air chamber from the initial pressure. After about 5 seconds, gradually open the control valve, tap the pressure gauge so that the pressure gauge pointer is stable, and correctly align the pointer with the initial pressure scale. After about 5 seconds, fully open the valve and tap the side of the container with a wooden stick. Again, open the valve sufficiently and read the scale of the pressure gauge with one decimal point after the pointer has stabilized. The reading is defined as the apparent air volume A ₁ of the concrete.

And the air quantity A of concrete is computed by the following formula.
A = A ₁ −G
Where A: Air content of concrete (%)
A ₁ : Apparent air volume of concrete (%)
G: Aggregate correction factor

The initial pressure is determined as follows.
(1) Fill the container with water so that the front and back of the lid can be ventilated, and gently attach the lid to the container. After attaching the lid, open the drain port and pour water from the water inlet until the air between the front side of the lid and the water surface is expelled.
(2) Close all valves and make the air chamber pressure slightly higher than the initial pressure with an air hand pump. After approximately 5 seconds, the control valve is gradually opened so that the pressure gauge pointer is correctly aligned with the initial pressure scale.
(3) Open the operating valve sufficiently, equilibrate the air pressure in the air chamber and the pressure in the container, read the pressure gauge, and check whether the reading correctly matches the scale of 0% air volume. If this is not the case, repeat the calibration after checking for air and water leaks and other checks. When repeated 2-3 times, the pointer of the pressure gauge points to the same point, but if it does not coincide with the zero point, the scale of the initial pressure moves so that the pointer remains at the zero point. Thereafter, the operation is repeated to check whether the position of the initial pressure scale is appropriate.

Japanese Utility Model Publication No. 56-2195 JP 2000-88843 A Utility Model Registration No. 3106603

  According to JIS A 1128, the amount of air in fresh concrete is determined by reducing the pressure in the air chamber, and the determination of the initial pressure is a very important item. However, when determining the initial pressure, as described above, it is necessary to have considerable skill to correctly match the pressure in the air chamber with the scale of the initial pressure. This is adjusted by making the pressure of the air chamber slightly larger than the initial pressure in advance and releasing the pressure with the regulating valve. However, experience is necessary for the delicate operation of the regulating valve.

  Therefore, in the present invention, it is possible to measure the amount of air in a sample such as fresh concrete with a simple operation, and in addition, a measuring device capable of measuring the volume of a sample such as an aggregate used and the like are used. The purpose is to provide a weighing method.

  The weighing device of the present invention is composed of a cylindrical container into which a predetermined amount of sample and water are respectively charged, and a measuring instrument mounted on the upper part of the cylindrical container, the measuring instrument includes a pointer indicating a measured value, It has a float that floats on the water on the sample and measures the water level, and a transmission mechanism that converts the vertical movement of the float into the movement of the pointer.

  According to the metering device of the present invention, when a predetermined amount of sample and water are put into a cylindrical container, water enters the gap of the sample and fills the gap. Then, the water level decreases by the volume of the water filling the gap. The decrease in the water level is measured by the float of a measuring instrument attached to the upper part of the cylindrical container, and indicated by the volume as water.

  When measuring the amount of air contained in a sample using this measuring device, sample and water are sampled and put into a cylindrical container, and a measuring instrument is attached to the upper part of the cylindrical container. And the volume obtained by subtracting the measured value read by the pointer from the total volume of the sample and water put into the cylindrical container is taken as the air amount of the sample.

  Also, when measuring the volume of a sample, a predetermined amount of a dried sample is collected and placed in a cylindrical container, and a predetermined volume of water is added, and a measuring instrument is attached to the upper part of the cylindrical container. The measurement value is read, and the volume obtained by subtracting the volume of water charged into the cylindrical container from the measurement value read by the pointer is defined as the volume of the sample.

  Furthermore, when measuring the specific gravity of a sample, a predetermined volume of a dried sample is collected, the mass is measured, the sample collected is charged into a cylindrical container, and a predetermined volume of water is added to the cylinder. A measuring instrument is attached to the upper part of the container, the measured value is read with the pointer, and the mass of the sample put into the cylindrical container is the capacity obtained by subtracting the volume of water charged into the cylindrical container from the measured value read with the pointer. The divided value is the specific gravity of the sample.

  Here, in the measuring device of the present invention, the measuring instrument includes a bottom portion that closes the upper portion of the cylindrical container, and a water level measuring cylindrical portion that is formed through the bottom portion, and the float is a water level measuring cylinder. It is desirable that it is arranged in the shape part. In this way, when the amount of change in the water level is small, the water level is pushed in by the bottom of the measuring instrument, and the amount of change in the water level is increased by pushing up the water into the water level measurement tubular portion formed through the bottom. The amount of change in the water level can be measured with a float with high accuracy.

  Moreover, it is desirable that the weighing device of the present invention further includes a columnar portion for volume adjustment formed so as to be movable up and down through the bottom. By moving the column for volume adjustment up and down, the water on the sample corresponding to the volume of the column for volume adjustment protruding from the bottom is pushed up into the column for water level measurement. The volume of the sample put into the cylindrical container when it is mounted can be adjusted.

  The volume adjusting columnar portions are desirably arranged at equal intervals around the water level measuring cylindrical portion. Accordingly, the water level can be uniformly pushed from the periphery around the water level measurement cylindrical portion, so that the water level adjustment error can be reduced even when the upper surface of the sample is not horizontal.

  Moreover, it is preferable that the weighing device of the present invention further includes a volume adjusting cylindrical portion that is formed so as to be openable and closable through the bottom portion. When the measuring instrument is mounted on the cylindrical container, if the volume adjusting cylindrical portion is opened, the water on the sample flows into the volume adjusting cylindrical portion, and the volume adjusting cylindrical portion Since the volume of water pushed up to the water level measurement tubular portion is reduced by the amount of the inflowing water, the amount of change in the water level measured by the float can be reduced. On the other hand, when the volume adjusting cylindrical portion is closed, the volume adjusting cylindrical portion is filled with air lighter than water, and the water on the sample does not flow into the volume adjusting cylindrical portion. Therefore, it does not affect the amount of change in the water level measured by the float. When a plurality of volume adjusting cylindrical portions are provided, the amount of change in the water level can be adjusted by individually changing the opening and closing of each volume adjusting cylindrical portion.

  The measuring instrument is placed on the upper edge of the cylindrical container, and is provided with cams for tilt adjustment at a plurality of locations in contact with the upper edge of the cylindrical container. It is desirable that the screw is fixed to the measuring instrument with a screw. Since the cam has a periphery where the distance from the rotation axis is not constant, the cam contacts the upper edge of the cylindrical container around the rotation axis and changes the inclination of the measuring instrument with a small change amount. Therefore, the tilt and height of the measuring instrument can be finely adjusted by the rotation angle of the cam.

  The float is formed of a floating portion having a specific gravity smaller than 1 and a weight portion having a specific gravity heavier than 1, and the weight portion is provided on the lower surface of the floating portion so as to leave the peripheral edge of the lower surface of the floating portion. It is desirable that Thereby, the peripheral part of the lower surface of a floating part becomes a collar part, rides on a water surface, surface tension becomes large, and buoyancy becomes large. Therefore, the float is stabilized without being affected by the viscosity of the water to be measured, and the measurement can be easily performed.

  Moreover, it is desirable that the floating portion is formed by a conical portion that tapers upward and a body portion on which a weight portion is provided. Accordingly, even when the gap between the water level measuring tubular portion and the inner wall surface is small, it is possible to prevent the capillary phenomenon in which water is sucked into the gap, and the water level is hardly affected.

(1) Each is composed of a cylindrical container into which a predetermined amount of sample and water are charged, and a measuring instrument attached to the upper part of the cylindrical container. The measuring instrument includes a pointer indicating a measured value and water on the sample. A float that measures the water level and a transmission mechanism that converts the vertical movement of the float into the movement of the pointer, so that a predetermined amount of sample and water are put into the cylindrical container, respectively. The volume of the void of the sample put into the cylindrical container is indicated by the pointer by a simple operation of attaching the measuring instrument to the cylinder. Thereby, it becomes possible to measure the air quantity, volume, etc. in samples, such as fresh concrete.

(2) The measuring instrument includes a bottom portion that closes the upper portion of the cylindrical container, and a water level measurement cylindrical portion that is formed through the bottom portion, and the float is disposed in the water level measurement cylindrical portion. Therefore, when the amount of change in the water level is small, the amount of change in the water level can be enlarged and accurately measured.

(3) By measuring a cylindrical container by adjusting the vertical position of the volume adjustment columnar part by further including a volume adjustment columnar part penetrating the bottom part so as to be movable up and down. It is possible to adjust the volume in the cylindrical container when the container is mounted, and to perform fine measurement by finely adjusting the volume of the sample put into the cylindrical container.

(4) Since the volume adjusting columnar parts are arranged at equal intervals around the water level measuring cylindrical part, the water surface is evenly distributed from the periphery around the water level measuring cylindrical part. By pushing into the surface, even when the upper surface of the sample is not horizontal, an error in water level adjustment can be reduced and measurement can be performed with high accuracy.

(5) By further including a volume adjustment cylindrical portion formed so as to be openable and closable through the bottom, opening and closing the volume adjustment cylindrical portion allows the water level measurement cylindrical portion to be opened. Since the volume of the pushed-up water can be adjusted, the amount of change in the water level measured by the float can be adjusted.

(6) The measuring instrument is placed on the upper edge of the cylindrical container, and is provided with tilt adjusting cams at a plurality of locations in contact with the upper edge of the cylindrical container, and the cam is a rotating shaft. Is fixed to the measuring instrument by a screw, and the tilt and height of the measuring instrument can be finely adjusted by the rotation angle of the cam.

(7) The float is formed of a floating portion having a specific gravity smaller than 1 and a weight portion having a specific gravity heavier than 1, and the weight portion is provided on the lower surface of the floating portion so as to leave a peripheral edge of the lower surface of the floating portion. As a result, the float is stabilized without being affected by the viscosity of the water to be measured, and measurement can be easily performed.

(8) Since the floating portion is formed of a conical portion that tapers upward and a body portion provided with a weight portion, the gap between the inner wall surface of the tubular portion for measuring the water level is reduced. Even if it is small, it is possible to prevent the occurrence of a capillary phenomenon in which water is sucked into this gap, and it becomes difficult to affect the water level.

(Embodiment 1)
1 is a front view of a weighing device according to a first embodiment of the present invention, FIG. 2 is a plan view of FIG. 1, FIG. 3 is a vertical sectional view of the upper part of FIG. 1, and FIG. 5 is a cross-sectional view taken along the line CC of FIG. 4, FIG. 6 is a schematic configuration diagram of the transmission mechanism viewed from above, FIG. 7 is a view taken along the arrow B in FIG. FIG.

  As shown in FIG. 1, a weighing device 1 according to a first embodiment of the present invention is a hollow cylindrical bottomed cylindrical container 2 and a measuring instrument mounted on the upper part of the cylindrical container 2. 3. A sample to be weighed is put into the cylindrical container 2 after a predetermined amount is weighed. The measuring instrument 3 is mounted on the upper portion of the cylindrical container 2 after a predetermined amount of water is further charged into the cylindrical container 2 into which the sample has been charged. Alternatively, after a predetermined amount of water is introduced into the cylindrical container 2, a sample is introduced and the measuring instrument 3 is mounted on the upper part of the cylindrical container 2.

  As shown in FIGS. 2 and 3, the measuring instrument 3 is provided at the hollow cylindrical portion 30, the disk-shaped bottom portion 31 that closes the lower end portion of the cylindrical portion 30, and the upper end portion of the cylindrical portion 30. The disc-shaped display part 32 and the lid part 33 for contacting the upper edge part 20 of the cylindrical container 2 and positioning the cylindrical container 2 are provided. The display unit 32 is provided with a pointer 34a and a scale 34b that indicate measurement values.

  The bottom portion 31 has a packing 31a at the circumferential portion thereof, and slides in the axial direction (vertical direction in FIG. 3) of the cylindrical container 2 along the inner peripheral surface 21 of the cylindrical container 2, so that the cylindrical container 2 Block the top of the. The bottom portion 31, the display portion 32, and the lid portion 33 are fixed to the cylindrical portion 30, and the position of the bottom portion 31 is determined in a state where the lid portion 33 is in contact with the upper edge portion 20 of the cylindrical container 2. Is done.

  Further, a hollow cylindrical water level measuring cylindrical portion 35, a cylindrical volume adjusting columnar portion 36, and a hollow cylindrical volume adjusting cylindrical portion 37 are formed in the bottom portion 31 through the bottom portion 31, respectively. Has been. Further, a recess 31b for removing air on the water in the cylindrical container 2 is formed on the back surface of the bottom portion 31 (the lower surface in FIG. 3). The concave portion 31b is formed in a conical shape with the head cut off, and is inclined so that the periphery of the water level measuring tubular portion 35 at the center of the bottom portion 31 is at the highest position. A plurality of communication holes 35a are provided at equal intervals around the upper end portion of the connection portion between the water level measuring tubular portion 35 and the recess 31b. Air on the water in the cylindrical container 2 is collected around the communication hole 35a by the concave portion 31b, enters the water level measuring cylindrical portion 35 through the communication hole 35a, and is externally exposed from above the water level measuring cylindrical portion 35. It is supposed to come out.

  As shown in FIG. 4, the water level measuring cylindrical portion 35 is fixed to the center portion of the bottom portion 31, and a cylindrical float 38 for measuring the water level by floating on the water on the sample is included therein. Has been placed. The float 38 is connected to a thread-like body 39a such as a wire or a rope. The filament 39a includes pulleys 39b and 39c, a pointer moving pulley 39d, an anti-tension pulley 39e, a take-up pulley 39f, a counterweight 39g, and the like, and a transmission mechanism 39 (which converts the vertical movement of the float 38 into the movement of the pointer 34a. (See FIG. 6). The pointer 34a is fixed on the rotating shaft of the pointer moving pulley 39d, and swings left and right (up and down in FIG. 2) from the state shown in FIG. 2 according to the vertical movement of the float 38.

  As shown in FIG. 4, four volume adjustment columnar portions 36 are provided around the water level measurement cylindrical portion 35 and are arranged at equal intervals. Each volume adjusting columnar portion 36 is formed so as to be vertically movable through the bottom portion 31. Although not shown, a packing is provided on the inner surface of each through hole of the bottom portion 31 through which each volume adjustment columnar portion 36 passes to prevent water below the bottom portion 31 from leaking and entering the bottom portion 31. Yes.

  As shown in FIG. 4, the volume adjusting cylindrical portion 37 is provided around the water level measuring cylindrical portion 35 as in the case of the volume adjusting columnar portion 36, and is arranged at equal intervals. Has been. Each volume adjusting tubular portion 37 is fixed through the bottom portion 31. Further, a lid (not shown) is provided on the upper portion of each volume adjusting cylindrical portion 37, and the internal space of each volume adjusting cylindrical portion 37 is opened and closed by opening and closing this lid. Is possible.

  The measuring instrument 3 also includes an inclination adjustment mechanism 40 for adjusting the inclination with respect to the cylindrical container 2. The tilt adjustment mechanisms 40 are provided at three positions at equal intervals on the peripheral edge of the lid 33 of the measuring instrument 3. The inclination adjustment mechanism 40 includes an inclination adjustment cam 41 provided at a portion that comes into contact with the upper edge portion 20 when the measuring instrument 3 is placed on the upper edge portion 20 of the cylindrical container 2, and the inclination adjustment mechanism 40. The rotary shaft 42 of the cam 41 is comprised from the wing nut 43 as a screw fixing | fixed part which fixes to the cover part 33 with a screw.

  The tilt adjustment cam 41 is a circular plate, and is rotatably attached to a notch 33 a provided at the peripheral edge of the lid 33 by a rotary shaft 42. The rotation shaft 42 is provided eccentric from the center of the inclination adjustment cam 41, so that the inclination adjustment cam 41 functions as a cam whose distance from the rotation shaft 42 to the lowest end changes depending on the rotation angle. That is, it is possible to set the distance from the upper edge portion 20 of the cylindrical container 2 to the rotation shaft 42 by adjusting the rotation angle of the inclination adjusting cam 41. Therefore, the inclination and height of the measuring instrument 3 with respect to the cylindrical container 2 can be adjusted by adjusting the rotation angles of the three inclination adjusting cams 41, respectively. A screw thread is formed on the rotating shaft 42, and the rotation angle of the tilt adjusting cam 41 is fixed by screwing the wing nut 43 with the screw thread of the rotating shaft 42.

  Next, various weighing methods using the weighing device 1 configured as described above will be described.

(A) Air content measurement of fresh concrete (1) 2.5 L (liter) of water in the cylindrical container 2 and a sample (fresh concrete) 7 L (including air) collected by the same method as JIS A 1128. And the air in the sample is released by shaking the cylindrical container 2 or stirring the sample in the cylindrical container 2. Due to the release of the air, the water level in the cylindrical container 2 indicates the water level reduced by the amount of air released from the total volume of 9.5 L of the sample 7L and the water 2.5L in the cylindrical container 2. That is, the amount of reduction is the amount of air contained in the sample.

(2) In the cylindrical container 2, solid contents such as aggregate and cement of the sample are settled, and moisture is separated and retained in the upper layer portion. Here, when the measuring instrument 3 is mounted on the upper part of the cylindrical container 2 and pushed in, water on the water passes from the concave part 31b of the bottom part 31 through the communication hole 35a to the outside from the upper part of the cylindrical part 35 for water level measurement, Is pushed up into the water level measuring tubular portion 35. At this time, the float 38 in the tubular portion 35 for measuring the water level rises as the level of the pushed-up water rises, and the pointer 34a is operated via the transmission mechanism 39. Therefore, the measurement is performed from the scale 34b indicated by the pointer 34a. Read the value.

(3) The volume obtained by subtracting the measured value read by the pointer 34a from the total 9.5L of the sample 7L and the volume 2.5L of water charged into the cylindrical container 2 is recorded as the amount of air in the sample. Here, the scale 34b of the pointer 34a can be configured in advance to directly represent the air amount of the sample.

  In the above (2), when the volume adjusting cylindrical portion 37 is opened, the volume adjusting cylindrical portion 37 is pushed up into the volume adjusting cylindrical portion 37. The ratio of the water pushed up into the water level measuring tubular portion 35 varies depending on the number of the number 37. When measuring the amount of air in fresh concrete, since the upper limit of the amount of air in general fresh concrete is 7%, the volume adjusting cylindrical portion 37 is set so that the measured value read by the pointer 34a is about 0 to 500 mL. The opening / closing number of the is adjusted in advance. Further, when the amount of water on the sample is small and insufficient to push up the float 38, the volume adjusting columnar portion 36 protrudes downward from the bottom portion 31 so that water corresponding to the protrusion amount is supplied to the water level measuring cylinder. It is possible to measure it by pushing it up into the shaped part 35.

  In addition, when confirming the accuracy of a conventional air meter, the amount of air measured by collecting 7 L of fresh concrete with an air meter and the fresh concrete 7 L after measurement are put into the cylindrical container 2 and the same as described above. What is necessary is just to compare with the air quantity measured by the method.

(B) Specific gravity and volume measurement of samples such as coarse aggregate, lightweight aggregate, fine aggregate, etc. (1) About 7L of a sample in a dry surface state (dry state in the case of lightweight aggregate) was collected and its mass was measured. After that, it is put into the cylindrical container 2 and further filled with water within a certain water level range (within a range measurable by the measuring device 3). At this time, water is added in units of 0.5 L, for example.
(2) The measuring instrument 3 is attached to the upper part of the cylindrical container 2 and pushed in, and the measured value is read by the pointer 34a.
(3) The volume obtained by subtracting the volume of water charged into the cylindrical container 2 from the measured value read by the pointer is recorded as the volume of the sample. Also, a value obtained by dividing the mass measured first by this volume is recorded as the specific gravity of the sample.

  As described above, in the weighing device 1 according to the present embodiment, a predetermined amount of sample and water are put into the cylindrical container 2 and the measuring instrument 3 is mounted on the upper part of the cylindrical container 2. The volume of the void of the sample put into the cylindrical container 2 is indicated by the pointer 34a. Thereby, it becomes possible to measure the air quantity, volume, etc. in samples, such as fresh concrete.

  The measuring instrument 3 includes a bottom portion 31 that closes the upper portion of the cylindrical container 2 and a water level measurement tubular portion 35 formed through the bottom portion 31, and the float 38 is a water level measurement tubular portion. When the water level change amount is small, the water level change amount can be enlarged and accurately measured. The expansion rate of the change amount of the water level is a ratio of the squares of the inner diameter of the cylindrical container 2 and the inner diameters of the water level measuring cylindrical portion 35 and the opened volume adjusting cylindrical portion 37.

  In the present embodiment, the measuring instrument 3 further includes a volume adjustment columnar portion 36 that is formed so as to be movable up and down through the bottom portion 31. Therefore, the vertical position of the volume adjustment columnar portion 36 is determined. By adjusting, it is possible to adjust the volume in the cylindrical container 2 when the measuring instrument 3 is mounted on the cylindrical container 2. Therefore, it is possible to perform highly accurate measurement by finely adjusting the volume in the cylindrical container 2. Further, even when the upper surface of the sample is not horizontal, the volume adjusting columnar portion 36 is arranged around the water level measuring cylindrical portion 35 at equal intervals. The water is pushed evenly from the periphery around the water level measuring tubular portion 35, so that the error of the water level adjustment can be reduced and the water can be measured with high accuracy.

  In the present embodiment, the measuring instrument 3 is placed on the upper edge portion 20 of the cylindrical container 2 and is used for tilt adjustment at a plurality of locations in contact with the upper edge portion 20 of the cylindrical container 2. Since the cam 41 is provided and the tilt adjusting cam 41 fixes the rotating shaft 42 to the measuring instrument 3 with a screw, the measuring instrument can be fixed by adjusting the rotation angle of the tilt adjusting cam 41 and fixing it. It is possible to finely adjust the inclination and height of the three cylindrical containers 2.

(Embodiment 2)
Next, a weighing device according to the second embodiment of the present invention will be described. The weighing device according to the second embodiment of the present invention is configured to use a measuring instrument 5 shown in FIGS. 9 and 10 instead of the measuring instrument 3 according to the first embodiment. 9 is a plan view of the measuring instrument 5 according to the second embodiment of the present invention, FIG. 10 is a sectional view taken along line EE of FIG. 9, and FIG. 11 is a diagram showing details of the float of FIG. ) Is a plan view, (b) is a front view, and (c) is a bottom view.

  As shown in FIGS. 9 and 10, the measuring instrument 5 in the second embodiment of the present invention includes a hollow cylindrical portion 50, a disk-shaped bottom portion 51 that closes the lower end portion of the cylindrical portion 50, and a cylinder A lid portion 52 provided at the upper end of the shaped portion 50 and a hollow cylindrical water level measuring tubular portion 53 penetrating the bottom portion 51. The measuring instrument 5 includes a columnar volume adjusting columnar part 36 and a hollow cylindrical volume adjusting cylindrical part 37 (not shown) similar to the measuring instrument 3 in the first embodiment. Moreover, the packing part 31a and the recessed part 31b are provided in the bottom part 51 similarly to 1st Embodiment.

  The water level measuring tubular portion 53 is fixed to the center portion of the bottom portion 51, and a float 6 for measuring the water level by floating on the water on the sample is disposed therein. As shown in FIG. 11, the float 6 includes a floating portion 60 formed of a material having a specific gravity smaller than 1, for example, synthetic resin, and a weight portion 61 formed of a material having a specific gravity heavier than 1, for example, stainless steel. It is configured. The floating portion 60 includes a conical conical portion 62 that tapers upward and a cylindrical body portion 63 on which a weight portion 61 is provided.

  On the other hand, the weight portion 61 is composed of a conical cone-shaped portion 64 that tapers downward and a cylindrical body portion 65 bonded to the floating portion 60, contrary to the floating portion 60. . Further, the body portion 65 of the weight portion 61 has an outer diameter larger than that of the lower surface of the floating portion 60 so that the peripheral portion of the lower surface of the floating portion 60 remains as the flange portion 66 when attached to the lower surface of the floating portion 60. It is formed small. The float 6 only needs to have a shape that can move up and down following the change in the water level inside the water level measuring tubular portion 53, and the conical portions 62 and 64 have a polygonal pyramid shape or the body portion 63. , 65 can be formed into a polygonal column shape.

  In addition, on the upper part of the water level measuring tubular portion 53, a double pulley 70 in which two pulleys 70a and 70b having a large diameter and a small diameter are formed coaxially is supported by bearings between the support plates 71a and 71b. The float 6 is connected to a filament 72 wound around a large-diameter pulley 70a. Note that a thread-like body 74 connected to the counterweight 73 is wound around the small-diameter pulley 70b and is in balance with the float 6.

  Further, on both sides of the shaft of the double pulley 70, drums 75a and 75b on which a scale indicating the measurement value as described above is written are fixed. The lid 52 is formed with windows 76a and 76b so that the scales of the drums 75a and 75b can be seen from above. A pointer 77 is provided on the window 76a.

  The method for performing various measurements using the measuring instrument 5 in the present embodiment is the same as in the first embodiment. Further, in the measuring instrument 5 having this configuration, since the flange portion 66 is formed with a flat bottom surface on the floating portion 60, the flange portion 66 rides on the water surface and the surface tension increases and the buoyancy increases. The float 6 is stabilized without being affected by the viscosity of the water to be measured. That is, since the water to be measured is water in a sample such as fresh concrete, viscosity often occurs, and it is difficult to stabilize with the cylindrical float 38 as shown in FIG. 3, but the float 6 in this embodiment is not stable. Then, without being affected by this viscosity, it is possible to immediately stabilize and quickly measure. FIG. 12 shows the relationship between the mass difference between the float and the counterweight and the depth of the float. As shown in the center part of FIG. 12, the float 6 absorbs a mass difference between the float 6 and the counterweight 73 to some extent, and can keep the depth of the float 6 unchanged. The float 6 can be stabilized without receiving.

  Moreover, in this float 6, as shown to (a), (b) of FIG. 13, compared with the column-shaped float 38 in 1st Embodiment, the clearance gap with the inner wall face of the cylindrical part 53 for water level measurement. Therefore, it is possible to prevent the occurrence of capillary action in which water is sucked into the gap and hardly affect the water level. On the other hand, in the case of the columnar float 38, if the gap between the water level measurement tubular portion 53 and the inner wall surface is small, the float 38 becomes the inner wall surface of the water level measurement tubular portion 53 as shown in FIG. The water may be sucked into the gap and the water level may be sucked into the gap due to capillary action.

  Further, in the measuring instrument 5 in the present embodiment, the vertical movement of the float 6 is directly converted into the rotational operation of the drums 75a and 75b by the double pulley 70 supported by the bearing, as compared with the measuring instrument 3 in the first embodiment. Therefore, the resistance by these transmission mechanisms is very small. Therefore, the vertical movement of the float 6 can be smoothly transmitted to the rotating operation of the drums 75a and 75b, and more accurate measurement can be performed.

  The measuring device of the present invention and the measuring method using the same measure the amount of air in a sample of fresh concrete and the like, and the volume of the sample of aggregate used, etc., and perform the fresh concrete production process and on-site quality control. Useful when doing.

It is a front view of the weighing device in the 1st embodiment of the present invention. It is a top view of FIG. It is a longitudinal cross-sectional view of the upper part of FIG. It is the sectional view on the AA line of FIG. It is CC sectional view taken on the line of FIG. It is the schematic block diagram which looked at the transmission mechanism from the top. It is a B arrow line view of FIG. It is DD sectional drawing of FIG. It is a top view of the measuring device in the 2nd Embodiment of this invention. It is EE sectional drawing of FIG. It is a figure which shows the detail of the float of FIG. 10, Comprising: (a) is a top view, (b) is a front view, (c) is a bottom view. It is a figure which shows the relationship between the mass difference of a float and a counterweight, and the depth of a float. It is explanatory drawing which compares the float in 2nd Embodiment, and the float in 1st Embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Weighing apparatus 2 Cylindrical container 20 Upper edge part 21 Inner peripheral surface 3,5 Measuring instrument 30,50 Cylindrical part 31,51 Bottom part 31a Packing 31b Recessed part 32 Display part 33,52 Lid part 34a Pointer 34b Scale 35,53 Water level Measuring cylindrical portion 35a Communication hole 36 Volume adjusting columnar portion 37 Volume adjusting cylindrical portion 38, 6 Float 39 Transmission mechanism 39a, 72, 74 Filament body 39b, 39c Pulley 39d Pointer movable pulley 39e Anti-tension pulley 39f Winding pulley 39g, 73 Counterweight 40 Tilt adjusting mechanism 41 Tilt adjusting cam 42 Rotating shaft 43 Wing nut 60 Floating part 61 Weight part 62, 64 Conical part 63, 65 Body part 66 Gutter part 70 Double pulley 70a, 70b Pulley 71a, 71b Support plate 75a, 75b Drum 76a, 76b Window 77 Pointer

Claims (9)

A cylindrical container into which a predetermined amount of sample and water are charged, and
It consists of a measuring instrument attached to the upper part of the cylindrical container,
The measuring instrument includes a pointer indicating a measured value,
A float that floats in the water on the sample and measures the water level;
A transmission mechanism that converts the vertical movement of the float into the movement of the pointer;
A bottom for closing the top of the cylindrical container;
And a water level measuring tubular portion formed through the bottom ,
The float is arranged in the tubular portion for measuring the water level,
A weighing device further comprising a volume adjusting columnar portion formed to penetrate the bottom and move up and down . The volume adjustment columnar portion, the water level measurement tubular portion metering device according to claim 1, wherein in the surrounding around those arranged at equal intervals. Weighing device according to claim 1 or 2 further comprising an openable-formed volume adjusting tubular portion through said bottom portion. The measuring instrument is placed on the upper edge of the cylindrical container, and includes cams for tilt adjustment at a plurality of locations in contact with the upper edge of the cylindrical container,
The weighing device according to any one of claims 1 to 3 , wherein the cam has a rotating shaft fixed to the measuring instrument with a screw. The float is formed of a floating portion having a specific gravity smaller than 1, and a weight portion having a specific gravity heavier than 1, and the weight portion is formed on a lower surface of the floating portion so as to leave a peripheral edge of the lower surface of the floating portion. The weighing device according to any one of claims 1 to 4 , wherein the weighing device is provided. 6. The weighing apparatus according to claim 5 , wherein the floating portion is formed by a conical portion that tapers upward and a body portion on which the weight portion is provided. A weighing method using a measuring device according to any of claims 1 to 6,
Collecting a predetermined volume of each of the sample and water into the cylindrical container and putting them in;
Attaching the measuring instrument to the upper part of the cylindrical container, and reading the measured value with the pointer;
A measuring method including a step of setting a volume obtained by subtracting a volume of water charged into the cylindrical container from a measured value read by the pointer as an air amount of the sample. A weighing method using a measuring device according to any of claims 1 to 6,
Collecting a predetermined volume of a sample in a dry state and putting it into the cylindrical container, and further adding a predetermined volume of water;
Attaching the measuring instrument to the upper part of the cylindrical container, and reading the measured value with the pointer;
A measuring method including a step of setting a volume of the sample by subtracting a volume of water charged into the cylindrical container from a measured value read by the pointer. A weighing method using a measuring device according to any of claims 1 to 6,
Collecting a predetermined volume of a dried sample and measuring the mass;
Throwing the sample of the predetermined volume into the cylindrical container, and further pouring a predetermined volume of water;
Attaching the measuring instrument to the upper part of the cylindrical container, and reading the measured value with the pointer;
A measuring method including a step of setting a value obtained by dividing the mass by a capacity obtained by subtracting a measured value read by the pointer from a total of the capacity of the sample and water charged into the cylindrical container and the specific gravity of the sample.

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