JPH0441761B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION Object of the Invention (Field of Industrial Application) The present invention relates to a formwork assembly method using a digital scale.

(Prior art) Conventionally, when assembling formwork at right angles for pouring foundation concrete, first, measure the intersection of the water strings with a curved scale, etc. to find the right angle, and then I was trying to assemble the formwork.

(Problems to be Solved by the Invention) Therefore, assembly requires a lot of time and labor.

This invention uses a digital scale that can very easily determine the right angle when assembling formwork at right angles for pouring foundation concrete, and can save labor in the work of finding right angles. To provide a formwork assembly method.

Structure of the Invention (Means for Solving the Problems) In order to solve the above problems, the present invention includes a detector that detects the amount of tape wound on a take-up reel, and a detection signal of the detector. Input,
a first storage device for storing the amount of tape to be pulled out at any given time; an input key for storing the amount of tape to be pulled out stored in the first storage device as length data of one side of a triangle in a second storage device; A hypotenuse calculation execution key is used to calculate the hypotenuse of a triangle, and two pieces of length data stored in the second storage device are read out based on the operation of the hypotenuse calculation execution key. The hypotenuse is calculated using the data as two sides of a right triangle, and the calculation result is stored in a third storage device as hypotenuse data, and
a first arithmetic processing means for displaying the oblique side on a display device; a key for using the oblique side data in the third storage device as a reference value and calculating a ratio of the tape withdrawal amount with respect to the reference value; Based on the key operation, the tape withdrawal amount stored in the first storage device and the hypotenuse data stored in the third storage device are read out, and based on both data, the ratio of the tape withdrawal amount to the reference value at that time is determined. A formwork assembling method using a digital scale comprising a second arithmetic processing means that calculates and displays on the display device, the length of the two formworks being calculated by the second arithmetic processing means by operating the input key. In addition, by operating the hypotenuse calculation execution key, the length data of both formworks are stored in a third storage device as length data, and the hypotenuse is calculated as the two sides of a right triangle. The data is stored as hypotenuse data, one ends of both the form frames are rotatably connected to each other, the tape is aligned between the other ends of both the form frames, and the amount of tape drawn out relative to the reference value based on the operation of the key is determined. The gist is to adjust the distance between the other ends of both formworks while checking the ratio on the display device.

(Operation) Therefore, in order to assemble two formworks at right angles using the digital scale with the above configuration, the lengths of the two formworks must be stored in the second storage device by operating the input key. At the same time, the user operates the hypotenuse calculation execution key to calculate the hypotenuse, which is the two sides of the right triangle based on the length data of both the formworks, and stores it in the third storage device.
Then, one end of both formworks is rotatably connected to each other, and a digital scale tape is placed between the other ends of both formworks, and the ratio of the amount of tape drawn out to the reference value of the hypotenuse is checked on the display device. While doing so, rotate both formworks to adjust the distance between the other ends.

(Embodiments) Hereinafter, preferred embodiments embodying the present invention will be described with reference to the drawings.

First, to explain the digital scale used in this embodiment, FIG. 1 shows the digital scale, in which a tape 1 is wound up on a reel (not shown) housed in a scale body 2, and is usually installed inside the reel. It is held in the stored state by a spring member. Note that in this example, tape 1
Although the scale is not attached to the scale, it may be implemented.

On the front of the scale body 2 are number keys 3 from 0 to 9, and function keys 4 to 4 for arithmetic calculations.
7 and an equal key 8 are provided. And the minus key 5 of the function keys
is also used as an execution key when calculating the ratio of the amount of tape 1 pulled out with respect to a reference value, which will be described later.

On the upper side of number key 3 is the A side as an input key,
B-side, C-side keys, and memory keys 9 to 12 are provided, and are used to input the length of each side of the triangle, respectively. A right side key 13 as a hypotenuse calculation execution key is provided on the right side of the division key 7, and is used when calculating the length of the hypotenuse C1 of a right triangle as shown in FIG.

Millimeter, shaku, scale, and interval keys 14 to 17 are keys for converting the units of length, and the millimeter key 14 converts units of length, the scale key 15 converts units of scale, and the scale key 16 converts units of length. In the unit that matches the length, also press the interval key 1
7 is used when you want to convert to an intermediate unit.

A display device 18 is provided above each key, and displays the length of the oblique side C1, the actually measured length of the tape 1, the ratio of the amount of tape 1 pulled out to a reference value to be described later, etc. There is.

The clear key 19 is provided on the right side of the plus key 4, and the power switch 20 is provided on the right end.

Next, the electrical circuit of the digital scale constructed as described above will be explained with reference to FIG.

A central processing unit (hereinafter referred to as CPU) 21 serving as first and second arithmetic processing means inputs the ON signal of each of the keys, and also inputs the detection amount of the tape draw-out amount detector 22 as a detector.
This tape draw-out amount detector 22 is provided inside the scale body 2 and measures the draw-out amount of the tape 1.
The measured value is output to the CPU 21 as a detection signal.

Read-only memory (hereinafter referred to as ROM) 2
3, a control program for the CPU 21 is stored. The CPU 21 then operates according to this program.

Readable and rewritable memory (hereinafter referred to as RAM) 24 as the first to third storage devices
is designed to store various data at the time, including a length register that stores the amount of tape 1 to be pulled out, side A, and side B that store the length of each side of the triangle.
Side and C side registers are provided. Also, RAM
A right side register 24 is provided to store the hypotenuse C1 of the right triangle.

Then, the CPU 21 displays a predetermined numerical value on the display device 18 based on the contents of each of these registers. Further, the CPU 21 has a function of calculating the hypotenuse C1 of a right triangle and storing the length of the hypotenuse C1 in a right side register, and displays the calculation result on the display device 18.

Further, the CPU 21 uses the oblique side C1 stored in the right side register as a reference value, and calculates the ratio of the amount of tape 1 being pulled out at that time (the amount of tape being pulled out stored in the length register) with respect to the reference value, The calculation result is displayed on the display device 18.

Next, regarding the formwork assembly method using the digital scale configured as described above, when assembling formworks F1 and F2 for foundation concrete pouring shown in Figure 4 at right angles to each other, find the right angle. I will explain about it.

Now, if you turn on the power switch 20,
After the CPU 21 clears all contents of the RAM 24 and initializes it, it waits for various key operations.

First, in order to find the length A of the formwork F1, operate the clear key 19 once to clear the contents of the length register in the RAM 24, and change the display on the display device 18 to "0".
Set to . Next, pull out tape 1 and formwork F1.
Measure the length A. At this time, the tape pullout amount detector 22 detects the pullout amount of the tape 1 and outputs it to the CPU 21. Then, the CPU 21 stores the detection amount outputted from the detector 22 from time to time in the length register of the RAM 24, and displays the length on the display device 18 based on the contents of the register. At this time, in the initial setting state of the CPU 21, the unit is set to meter, and the displayed unit is meter.

Next, when the storage key 12 is operated and the A-side key 9 is operated, the CPU 21 stores the contents of the length register at this time in the A-side register as the length A of the formwork F1.

Next, in order to find the length B of the formwork F2, after once operating the clear key 19 in the same manner as described above, the tape 1 is pulled out and the length B of the formwork F2 is measured. Then, after operating the memory key 12 in the same manner as described above, when the B-side key 10 is operated this time, the CPU 21 stores the contents of the length register at this time in the B-side register as the length B of the formwork F2.

When the measurement of the lengths A and B of both formworks F1 and F2 is completed and the right side key 13 is operated next, the CPU 21 responds to the ON signal to read each formwork stored in the A side and B side registers. Based on the lengths A and B of F1 and F2, the calculation C1=√ ² + ₂ is executed to calculate the hypotenuse C1 of the right triangle. That is, formwork F
1, F2 is the two sides of the triangle, and those two sides (formwork F
1, F2), the hypotenuse C1 of a right triangle whose interior angle is 90 degrees is calculated.

Then, the CPU 21 stores this calculation result in the right side register, and displays the length of the hypotenuse C1 of the right triangle based on the contents of the right side register.

Next, based on this calculation result, both formworks F1 and F2 are
The case where the two are assembled at right angles to each other will be explained.

First, as shown in FIG. 4a, one ends of the formworks F1 and F2 are rotatably connected to each other.

Next, when you operate minus key 5, CPU2
1, in response to the ON signal of the key 5, the length of the oblique side C1 of the right side register is set as a reference value X, and the amount L of the tape 1 pulled out at that time with respect to this reference value
An arithmetic operation is started to obtain the ratio value Y of (the contents of the length register). That is, the calculation Y=L-X is executed.

At this time, tape 1 has not been pulled out yet and L=0, so the ratio value Y becomes -X,
The value Y (=-X) is displayed on the display device 18.

Next, pull out tape 1 and have one person
Align the tip of the tape with the tip of the formwork F1, and another person holding the scale body 2, align the base end of the tape 1 with the tip of the formwork F2, and tape the length connecting the tips of the formworks F1 and F2. Measure L. At this time, the amount L of the tape 1 is pulled out is stored in the length register in the same way as above, and this amount L of the tape 1 and the reference value
The ratio value Y (=L-X) at each time is calculated and displayed on the display device 18. At this time, for example, if you operate the interval key 17, you can change the ratio value Y in interval units.
is displayed.

Therefore, when the tape 1 is aligned between the ends of the formworks F1 and F2, by looking at the ratio value Y displayed on the display device 18 at that time, it is possible to determine how much further the formwork F2 should be rotated around the connecting part. You can easily judge whether it is necessary to pull out the tape 1.

Then, in the case of Fig. 4a, when the display on the display device 18 at that time is "-0.18" as shown in Fig. 5a, the formwork F2 is rotated clockwise so that the display becomes "0". I know what I need to adjust.
Conversely, in the case of FIG. 4b, when the display on the display device 18 at that time is "0.234" as shown in FIG. 5b,
It can be seen that the formwork F2 should be rotated and adjusted in the counterclockwise direction so that the display becomes "0".

Then, by adjusting the rotation of the formwork F2, the display device 18
When the display becomes "0.0" as shown in Figure 5c, that is, when the amount of tape 1 pulled out L matches the reference value X, it can be seen that the formworks F1 and F2 are at right angles to each other. .

In addition, in order to clear the A-side, B-side, and right-side registers after completing the work, it is sufficient to operate the 0 number key 3 and then operate the memory key 12 or turn off the power switch 20. Further, if the clear key 19 is operated, the display returns to the normal scale display.

In this way, in this embodiment, formworks F1 and F2
Just input the lengths A and B of the formwork F1. F
The length of the hypotenuse C1 of a right triangle whose two sides are 2 can be found. Moreover, this calculated hypotenuse C
When measuring the oblique side C1 with tape 1 using the length of 1 as the reference value X, the ratio Y of the tape pull-out amount L to the reference value X is displayed, so that the formworks F1 and F2 are When adjusting the right angle, it is sufficient to rotate the formwork F2 so that the value displayed on the display device becomes "0", and the assembly work becomes very simple.

Effects of the Invention According to the present invention, when assembling formwork at right angles, adjustment can be made with a simple operation using a digital scale, eliminating the need for troublesome work such as stringing water strings. This has the excellent effect of improving the work efficiency of assembling formwork at right angles to each other.

[Brief explanation of the drawing]

Fig. 1 is a perspective view of a digital scale that embodies this invention, Fig. 2 is an electric block circuit diagram of the digital scale, Fig. 3 is an explanatory diagram for explaining the hypotenuse of a right triangle, and Figs. 4 a and b. are explanatory diagrams to explain how to assemble the formwork at right angles, respectively.
Figures 5 a to c are diagrams showing the display contents of the display device, and Figures 6 and 7 are the central processing unit (CPU).
2 is a flowchart for explaining the operation process. Tape 1, minus key 5 as a key, A side key 9 as an input key, B side key 10 as an input key, right side key 1 as a hypotenuse calculation execution key
3. Display device 18, tape draw-out amount detector 22 as a detector, first to third storage devices
RAM24, formwork F1, F2, lengths A, B, oblique side C1, tape pull-out amount L, reference value X, ratio Y.

Claims (1)

[Scope of Claims] 1. A detector that detects the amount of tape being pulled out from a take-up reel; and a first storage device that receives a detection signal from the detector and stores the amount of tape that is pulled out at any given time. an input key for storing the withdrawal amount stored in the first storage device in a second storage device as length data of one side of the triangle; and a hypotenuse calculation execution key for executing an operation for calculating the hypotenuse of a right triangle. and, based on the operation of the hypotenuse calculation execution key, read two pieces of length data stored in the second storage device, calculate the hypotenuse using the two length data as two sides of a right triangle, and calculate the hypotenuse. a first arithmetic processing means for storing the calculation result as hypotenuse data in a third storage device and displaying the hypotenuse on a display device; a key for calculating the ratio of the tape withdrawal amount; and based on the operation of the key, reading out the tape withdrawal amount stored in the first storage device and the hypotenuse data stored in the third storage device; A formwork assembling method using a digital scale comprising a second arithmetic processing means that calculates the ratio of the tape withdrawal amount to the reference value at that time based on both data and displays it on the display device, the formwork assembling method using two scales. The lengths A and B of the formworks F1 and F2 are stored in the second storage device 2 by operating the input keys 9 and 10.
4 as length data in advance, and by operating the hypotenuse calculation execution key 13, the length data of both formworks F1 and F2 are used to calculate the hypotenuse C1, which is the two sides of a right triangle. Storage device 2
4 as hypotenuse data, one end of both the formworks F1 and F2 is rotatably connected to each other, and the tape 1 is placed between the other ends of both the formworks F1 and F2, and the key 5 is The digital scale is characterized in that the distance between the other ends of the formworks F1 and F2 is adjusted while checking on the display device 18 the ratio Y of the tape draw-out amount L to the reference value X based on the operation. Formwork assembly method.