KR20100008872A - Apparatus for testing slump of concrete - Google Patents

Abstract

PURPOSE: A device for testing slump of concrete is provided to check the slump value of concrete sample with the naked eye, and simplify a structure. CONSTITUTION: A device for testing slump of concrete comprises a plate part, a support member(310), a horizontal member(330), a distance measuring part(30), and a display part(70). A slump cone in which concrete sample is accepted is settled on the base plate part. The support member is installed on the base plate part or separated from the base plate part. The height of the support member is higher than the height of the slump cone. The horizontal member is formed on the top part of the support member in a horizontal direction. The distance measuring part is composed of laser distance measuring members. The display part displays the calculated slump value.

Description

Measuring device for concrete slump {APPARATUS FOR TESTING SLUMP OF CONCRETE}

The present invention and the base plate portion is seated slump cone to accommodate the concrete sample; A support member provided on the base plate portion or at a position spaced apart from the base plate portion by a predetermined distance, the support member having a height at least greater than the height of the slump cone, a horizontal member formed in a horizontal direction at an upper end of the support member, and the horizontal A distance measuring unit comprising a laser distance measuring member formed on the member; A calculation unit for calculating a slump of the concrete sample placed on the base plate unit by the value measured from the distance measuring unit; It relates to a concrete slump measuring apparatus comprising a; display unit for displaying the value of the slump calculated by the calculation unit.

Generally, slump and floor of concrete are used to measure the consistency of hardened concrete in construction sites and laboratories, and to estimate the workability of the transport and placing of concrete. Test to measure.

Here, the slump refers to a phenomenon in which the height of the flash concrete gradually decreases due to its own weight when the slump cone is filled with fresh concrete, that is, the wet concrete but not yet hardened.

The floor refers to a phenomenon in which the bottom area of the flash concrete is gradually widened when the height of the flash concrete is gradually lowered by its own weight when demolding after filling the flash concrete to the slump cone.

On the other hand, by measuring the slump and the floor of the flash concrete into the slump cone into the three levels of the flash concrete in 1/3, and evenly mixed the concrete contained in the slump cone with a stick or the like and then the slump cone upwards The method of measuring slump and floor of fresh concrete in the state of lifting and demolding is widely used, but it is not only hassle for the worker to measure the slump and floor of fresh concrete every time with a tape measure. There is a problem that can not measure the floor.

Therefore, recently, a digital slump measuring device capable of evenly mixing the flash concrete to be measured and displaying an accurate slump value; A slump floor of concrete using a computer device that divides the digital camera and each image taken into a preset number of pixels and analyzes the position of the pixels on the boundary line between the slump plate and the flash concrete for each image. Automatic measuring devices and measuring methods have been proposed.

However, the digital slump measuring device can only measure the slump of the flash concrete and display the exact value, and cannot measure the floor of the flash concrete, and the automatic slump floor measuring device and the measuring method of the concrete using the computer device have the structure Since there is a complex and the manufacturing cost is greatly increased, there is a problem that it is difficult for a worker to purchase and use because it is distributed at a high price in the market.

The present invention was created in order to solve the above-mentioned problems, and it is possible to measure the slump and the floor of the concrete sample more accurately, as well as the simple structure of the concrete slump measuring apparatus that can be distributed on the market at a low cost. Its purpose is to provide.

The present invention for achieving the above object is the base plate portion to which the slump cone is accommodated concrete sample is received; A support member provided on the base plate portion or at a position spaced apart from the base plate portion by a predetermined distance, the support member having a height at least greater than the height of the slump cone, a horizontal member formed in a horizontal direction at an upper end of the support member, and the horizontal A distance measuring unit comprising a laser distance measuring member formed on the member; A calculation unit for calculating a slump of the concrete sample placed on the base plate unit by the value measured from the distance measuring unit; It provides a measuring device for the concrete slump comprising a; display unit for displaying the value of the slump calculated by the calculation unit.

Here, a plurality of laser distance measuring members are formed in the distance measuring unit, and the calculating unit calculates an average slump of the concrete sample based on values measured by the plurality of laser distance measuring members and outputs the average slump to the display unit. desirable.

In addition, it is preferable that a lattice shape or a concentric circular measurement display part is formed on an upper surface of the base plate part.

Furthermore, a temperature sensor for measuring the temperature is further provided, and the display unit displays the temperature measured by the temperature sensor.

In addition, the base plate portion is made of a magnetic material, the lower end of the support member of the distance measuring unit is preferably made of a permanent magnet is fixed to the base plate portion is provided.

In addition, it is preferable that the end of the horizontal member is fixed to the upper portion of the support member.

The present invention uses a tape measure as in the prior art because the calculation unit calculates the slump of the concrete sample placed on the base plate portion by the value measured from the distance measuring portion provided on the base plate portion or at a position spaced from the base plate portion by a predetermined distance. Not only does the slump need to be measured, but also the slump of the concrete sample can be measured more accurately, and since its structure is simple, it can be distributed at low cost on the market, and furthermore, the slump value calculated by the calculation unit is displayed. Since the additional display, the operator can easily check the slump value of the concrete sample with the naked eye.

Further, since a plurality of laser distance measuring members are formed in the distance measuring unit, and the calculating unit calculates an average slump of the concrete sample based on the values measured from the plurality of laser distance measuring members and outputs the average slump to the display unit. There is an effect that can measure the slump of the concrete sample accurately.

In addition, the floor measurement display portion formed on the upper surface of the base plate portion can not only easily measure the floor value of the concrete sample, but also the floor measurement display portion formed in a grid or concentric shape on the upper surface of the base plate. Therefore, there is an effect that it is possible to measure the floor of the concrete sample more accurately.

Furthermore, since the temperature measured by the temperature sensor for measuring the ambient temperature is displayed on the display unit, it is possible to measure the slump and the floor of the concrete sample according to the ambient temperature.

In addition, since the base plate is made of a magnetic material, and the fixing member provided at the lower end of the support member of the distance measuring part is made of a permanent magnet, the operator can easily support the distance measuring part at the base plate part as necessary. There is an effect that can be separated.

In addition, since the end of the horizontal member of the distance measuring unit is rotatably fixed on the upper portion of the support member, the operator can more easily position the horizontal member in the upper direction of the concrete sample placed on the base plate portion. It is effective.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Of course, the scope of the present invention is not limited to the following examples, and various modifications can be made by those skilled in the art without departing from the technical gist of the present invention.

1 is a perspective view schematically showing an apparatus for measuring concrete slump, which is an embodiment of the present invention, and FIG. 2 is an exploded perspective view schematically illustrating a state in which the horizontal member 330 is separated from the support member 310.

Concrete slump measuring apparatus of one embodiment of the present invention as shown in Figures 1 and 2 largely comprises a base plate 10, the distance measuring unit 30, the calculation unit and the display unit 70.

First, the base plate portion 10 is a slump cone to accommodate the concrete sample to measure the slump and the floor is seated, the position spaced a predetermined distance from the base plate portion 10 or from the base plate portion 10 The distance measuring unit 30 is provided.

The shape and structure of the base plate portion 10 is not limited to Figs. 1 and 2, it is sufficient if the shape and structure that the slump cone can be seated.

Next, the distance measuring unit 30 is provided on the base plate portion 10 or at a position spaced apart from the base plate portion 10 by a predetermined distance, as shown in FIGS. 1 and 2. A support member 310 provided on the base plate portion 10 or at a position spaced from the base plate portion 10 at a predetermined distance, and having a height greater than at least the height of the slump cone; A horizontal member 330 formed in a horizontal direction at an upper end of the support member 310; And a laser distance measuring member formed on the horizontal member 330.

Here, the end of the horizontal member 330 is preferably fixed to the shaft rotatably on top of the support member 310.

More specifically, the horizontal member 330 is large as shown in Figure 2, for example, a horizontal plate 333 formed in the horizontal direction on top of the support member 310; The vertical axis is formed perpendicular to the lower end of the horizontal plate 333, the male gear 337 is formed in engagement with the female gear 311 formed on the upper inner circumference of the support member 310 on the lower outer circumference ( 335);

Here, when the worker raises the horizontal plate 333 of the horizontal member 330, the male gear 337 of the vertical shaft 335 is separated from the female gear 311 of the support member 310, this state As the worker rotates the horizontal plate 333 of the horizontal member 330 in the left and right direction, the horizontal plate 333 of the horizontal member 330 is in the upper direction of the concrete sample placed on the base plate portion 10 It can be located at (see Fig. 5).

Then, the worker lowers the horizontal plate 333 of the horizontal member 330 while the horizontal plate 333 of the horizontal member 330 is located in the upper direction of the concrete sample placed on the base plate portion 10. The male gear 337 of the vertical shaft 335 is engaged with the female gear 311 of the support member 310, and thus the horizontal plate 333 positioned in the upper direction of the concrete sample is firmly positioned. It can be fixed.

The end of the horizontal member 330 of the distance measuring unit 30 is rotatably fixed on the upper portion of the support member 310, the operator in the upper direction of the concrete sample placed on the base plate portion 10 There is an advantage that it is possible to position the horizontal member 330 more easily.

On the other hand, the laser distance measuring member measures the distance between the upper portion of the concrete sample placed on the base plate portion 10 and the lower surface of the horizontal plate 333 of the horizontal member 330 to output the value measured by the calculation unit This will be described in detail below for convenience of description.

The shape and structure of the distance measuring part 30 is not limited to FIGS. 1 and 2, and may be provided on the base plate part 10 or at a position spaced a predetermined distance from the base plate part 10. And a structure is sufficient.

Next, the calculation unit calculates the slump of the concrete sample, and calculates the slump of the concrete sample placed on the base plate part 10 by the value measured from the distance measuring unit 30.

Next, the display unit 70 is for displaying the value of the slump calculated by the operation unit 50 with numbers, etc., and as shown in FIGS. 1 and 2, the horizontal plate of the horizontal member 330. It may be provided on one side or the other side of the 333, but preferably the operator so that the display unit 70 can easily check the value of the slump displayed by, for example, a number, with the naked eye. It is preferable that the horizontal plate 333 of the horizontal member 330 is provided on the upper surface.

The display unit 70 may be made of a known led panel, but is not necessarily limited thereto.

The shape and structure of the display unit 70 is not limited to FIGS. 1 and 2, and the display unit 70 may be formed in a shape and a structure that can display the value of the slump calculated by the operation unit 50 by numbers.

3 to 6 are front views schematically illustrating a process of measuring a slump of concrete, and FIG. 7 is a block diagram schematically illustrating a control state of the controller 100.

Next, the process of measuring the concrete slump will be described in more detail with reference to the drawings.

First, the operator seats the slump cone 7 in which the concrete sample 5 is accommodated in the base plate portion 10 as shown in FIG.

And, when the operator lifts and demolds the slump cone 7 in the upper direction of the base plate portion 10 as shown in Figure 4 (as shown in Figure 5) the concrete sample placed on the base plate portion 10 ( 5) is gradually lowered by its own weight.

In this state, the laser distance measuring member (350 of FIG. 5) formed below the horizontal plate 333 of the horizontal member 330 positioned in the upper direction of the concrete sample 5 has the base plate portion as described above. The distance between the upper portion of the concrete sample (5) placed on the (10) and the lower surface of the horizontal plate 333 of the horizontal member 330 is measured to output the value measured by the calculation unit.

Here, the laser distance measuring member 350 is a sensor for detecting a distance, etc. using a laser, for example, the laser distance measuring member 350 is formed on the lower portion of the horizontal plate 333 of the horizontal member 330 to form an upper portion of the concrete sample 5. A laser oscillator for emitting a laser to the furnace; It may be made, including; a laser transmitter for receiving a laser reflected by hitting the upper portion of the concrete sample (5).

The laser distance measuring member 350 including the laser oscillator and the laser transmitter is a well-known technology and can be clearly understood by those skilled in the art to which the present invention pertains. do.

On the other hand, the calculation unit 50 is, for example, as shown in Figure 7, the laser distance of the distance measuring unit 30 in the state provided in the control unit 100 for controlling the driving of the display unit 70 Receiving the signal output from the measuring member 350 is to automatically calculate the slump of the concrete sample (5).

Here, the calculation unit 50 may automatically calculate the slump of the concrete sample 5 by interlocking with a known calculation program stored in the memory 130 embedded in the control unit 100, for example. The slump of the concrete sample 5 can be calculated by more various methods.

The slump of the concrete sample 5 automatically calculated by the calculating unit 50 is stored in the memory 130 and output to the display unit 70, wherein the control unit 100 supplies power from the power supply unit 110. The display unit 70 controls the display unit 70 so that the display unit 70 can display the slump value of the concrete sample 5 by numbers.

Next, a plurality of laser distance measuring member 350 of the distance measuring unit 30 is formed in the lower portion of the horizontal plate 333 of the horizontal member 330 as shown in FIG.

When a plurality of laser distance measuring members 350 of the distance measuring unit 30 are formed below the horizontal plate 333 of the horizontal member 330, the calculation unit 50 may include the plurality of laser distance measuring members 350. The average slump of the concrete sample 5 is automatically calculated based on the measured value from the output to the display unit 70.

As described above, a plurality of laser distance measuring members 350 are formed in the distance measuring unit 30, and the calculation unit 50 measures the concrete sample 5 based on the values measured from the plurality of laser distance measuring members 350. Since the average of the slump is automatically calculated and output to the display unit 70, there is an advantage that the slump of the concrete sample 5 can be measured more accurately.

The plurality of laser distance measuring members 350 formed in a plurality of lower portions of the horizontal plate 333 of the horizontal member 330 may be formed in a plurality of rows under the horizontal plate 333.

On the other hand, the support member 310 of the distance measuring unit 30 is provided on the base plate portion 10 or at a position spaced apart from the base plate portion 10 as described above, in particular the support member 6, when one of the plurality of laser distance measuring members 350 (351 of FIG. 6) is provided at a position spaced from the base plate portion 10 by a predetermined distance, as shown in FIG. 6, the horizontal plate ( The distance between the lower surface of the 333 and the upper surface of the base plate 10 may be measured to output the value measured by the calculator 50.

More specifically, when the support member 310 of the distance measuring part 30 is provided at a position spaced from the base plate part 10 by a predetermined distance, the height of the support member 310 of the distance measuring part 30 is It is lower than when provided on the base plate portion 10.

As such, when the height of the supporting member 310 of the distance measuring unit 30 is different, there is a possibility that an error occurs in the slump value calculated by the calculating unit 50.

However, any one of the plurality of laser distance measuring members 350 351 measures the distance between the lower surface of the horizontal plate 333 and the upper surface of the base plate portion 10 to the calculation unit 50. When the measured value is outputted, the calculator 50 may determine that any one of the values output by the remaining plurality of laser distance measuring members 353 of FIG. 6 and the plurality of laser distance measuring members 350 are 351. Since the average slump of the concrete sample 5 is automatically calculated based on the output value, there is no fear that an error occurs in the slump value calculated by the calculation unit 50.

8 and 9 are plan views schematically illustrating a state in which a grid measurement or concentric floor measurement display unit 90 is formed on an upper surface of the base plate portion 10.

Next, as shown in FIG. 8 and FIG. 9, it is preferable that a lattice-shaped or concentric-shaped floor measurement display unit 90 is formed on the upper surface of the base plate portion 10.

More specifically, when the worker lifts and demolds the slump cone 7 in the upper direction of the base plate portion 10, the concrete sample 5 placed on the base plate portion 10 is gradually lowered by its own weight. At the same time, as shown in FIGS. 8 and 9, the area of the lower surface of the concrete sample 5 gradually increases.

Here, although not shown in the drawings, a display unit made of numbers or the like may be further provided on the grid-shaped or concentric-shaped floor measurement display unit 90 at a predetermined interval.

As such, when the display unit consisting of numbers on the grid-shaped or concentric-shaped floor measurement display unit 90 is additionally provided at a predetermined interval, the area of the lower surface of the concrete sample 5 that is gradually widened, that is, the floor value is transmitted through the display unit. It can be confirmed with the naked eye.

On the other hand, it is more preferable that a plurality of contact sensors (150 in FIG. 7) contacting the lower surface of the concrete sample 5 which is gradually widened are provided at regular intervals on the grid-shaped or concentric-shaped floor measurement display unit 90.

The contact sensor 150, which is provided in a plurality of grid-shaped or concentric-shaped floor measurement display units 90 at a predetermined interval, contacts the lower surface of the concrete sample 5 that is gradually widened to output the signal to the calculation unit 50. The calculator 50 automatically calculates the floor of the concrete sample 5 by interlocking with the known calculation program stored in the memory 130 based on the signal output from the contact sensor 150.

In addition, a floor automatically calculated by the operation unit 50 is stored in the memory 130 and output to the display unit 70, where the control unit 100 receives power from the power supply unit 110. The display unit 70 controls the display unit 70 to display the floor value of the concrete sample 5 by numbers.

As such, the floor measurement display unit 90 formed on the upper surface of the base plate unit 10 may not only easily measure the floor value of the concrete sample 5, but also allow the floor measurement display unit 90 to measure the base. Since the upper surface of the plate is formed in a lattice shape or concentric circles, there is an advantage that it is possible to more accurately measure the floor of the concrete sample (5).

Although not shown in the drawings, the slump value and the floor value displayed by the display unit 70 by numbers, for example, may be transferred to a portable storage medium such as USB through a cable electrically connected to the control unit 100. Can be wired.

In addition, the control unit 100 and the portable storage medium such as USB can perform a short range wireless communication, for example, a well-known Bluetooth communication. As a result, the display unit 70 displays a slump value and a floor value. It can be stored wirelessly in a portable storage medium such as USB.

Next, a temperature sensor (170 of FIG. 7) for measuring the ambient temperature is further provided, and the temperature measured by the temperature sensor 170 is displayed on the display unit 70 as a number.

Here, the temperature sensor 170 is provided on the support member 310 or the horizontal member 330 of the distance measuring unit 30, for example, by measuring the ambient temperature and transmitting the signal to the display unit 70. In this case, the control unit 100 controls the display unit 70 so that the display unit 70 can display the ambient temperature as a number.

As such, the temperature measured by the temperature sensor 170 for measuring the ambient temperature is displayed on the display unit 70, whereby the operator can measure the slump and the floor of the concrete sample 5 according to the ambient temperature. There is an advantage.

Next, the base plate portion 10 is made of a magnetic material, the lower end of the support member 310 of the distance measuring portion 30 is made of a permanent magnet is fixed on the base plate portion 10 (Fig. 5, 313) is more preferably provided.

Here, the base plate portion 10 may be made of iron, but preferably made of stainless steel or the like.

In particular, when the base plate portion 10 is made of stainless material, even if the base plate portion 10 is in continuous contact with the strong alkali concrete, there is no fear of corrosion.

Here, the slump cone 7 accommodated in the concrete sample 5 may also be made of stainless material so as not to corrode the slump cone 7 containing the concrete sample 5, which is a strong alkali.

The base plate part 10 is made of a magnetic material, and the fixing member 313 provided at the lower end of the support member 310 of the distance measuring part 30 is made of a permanent magnet. In the base plate 10, there is an advantage that the support member 310 of the distance measuring unit 30 can be more easily separated.

According to the present invention configured as described above, the calculation unit 50 is located on the base plate unit 10 by a value measured from the distance measuring unit 30 provided at a position spaced a predetermined distance from the base plate unit 10. Since the slump of the concrete sample 5 placed on the slump is calculated, there is no need to measure the slump using a tape measure as in the related art, and the slump of the concrete sample 5 can be measured more accurately, and the structure thereof is simple. Therefore, it can be distributed at low cost in the market, and furthermore, since the display unit 70 displays the slump value calculated by the operation unit 50 as a number, the operator sees the slump value of the concrete sample 5 visually. There is an advantage that can be easily confirmed.

1 is a perspective view schematically showing an apparatus for measuring a concrete slump, which is an embodiment of the present invention;

Figure 2 is an exploded perspective view schematically showing a state in which the horizontal member is separated from the support member,

3 to 6 is a front view schematically showing a process of measuring the slump of concrete,

7 is a block diagram schematically illustrating a control state of a controller;

8 and 9 are plan views schematically illustrating a state in which a lattice-shaped or concentric-shaped floor measurement display unit is formed on an upper surface of the base plate.

*** Explanation of symbols for main parts of drawing ***

5; Concrete sample, 7; Slump Cone,

10; A base plate portion; Distance Measuring Unit,

310; Support member, 311; Armored Gear,

313; Fixing member, 330; Horizontal member,

333; Horizontal plate, 335; Vertical Axis,

337; Hand gear, 350; Laser distance measuring member,

50; A calculating section 70; Display,

90; Follower measuring display 100; Control,

110; A power supply unit 130; Memory,

150; Contact sensor, 170; temperature Senser.

Claims (6)

A base plate portion on which a slump cone for accommodating the concrete sample is seated; A support member provided on the base plate portion or at a position spaced apart from the base plate portion by a predetermined distance, the support member having a height at least greater than the height of the slump cone, a horizontal member formed in a horizontal direction at an upper end of the support member, and the horizontal A distance measuring unit comprising a laser distance measuring member formed on the member; A calculation unit for calculating a slump of the concrete sample placed on the base plate unit by the value measured from the distance measuring unit; And a display unit for displaying the value of the slump calculated by the calculation unit. The method of claim 1, A plurality of laser distance measuring members are formed in the distance measuring unit, and the calculating unit calculates an average slump of the concrete sample based on the values measured from the plurality of laser distance measuring members and outputs the average slump to the display unit. Measuring device for concrete slump. The method according to claim 1 or 2, The upper surface of the base plate portion is a concrete measuring device for measuring the slump, characterized in that the grid-shaped or concentric floor measurement display unit is formed. The method according to claim 1 or 2, A temperature sensor for measuring the temperature is further provided, and the display unit displays the temperature measured by the temperature sensor, characterized in that the concrete slump measuring device. The method of claim 1, The base plate portion is made of a magnetic material, the lower end of the support member of the distance measuring unit is made of a permanent magnet made of a permanent member is fixed to the base plate portion characterized in that the measuring device of the concrete slump. The method of claim 1, Measuring device of the concrete slump, characterized in that the end of the horizontal member is fixed to the upper portion of the support member.

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