GR1010339B - Length measurement system practicable for wire or concrete reinforcing bar straightening machines - Google Patents

Abstract

The present invention relates to a system meant for measuring the wire or the concrete reinforcing bar (4) which is aligned in alignment mechanisms (3) and cut by a cutting mechanism (6) into predetermined lengths. The wire or the concrete reinforcing bar (4) is aligned and propelled into a basin (7) until the desired length is completed and the cutting mechanism (6) activated. Along the length of the basin (7) there are sensors (40) at determined points and known distance from the cutting point of the wire or the concrete reinforcing bar (4). As the wire or concrete reinforcing bar (4) passes the sensors (40), the measuring system resets to zero and continues to measure from that sensor’s point by adding the known distance of the sensor (40) from the cutting point of the cutter (6) so that the actual length is achieved. In this way, any measurement error depending on the length of the wire or concrete reinforcing bar (4) is minimized within the limits of the induced measurement error, which limits correspond to the distance between two successive sensors (40).

Description

LENGTH MEASUREMENT SYSTEM IN STRAIGHT STRAINS

WIRE AND BEETWERG MACHINES

DESCRIPTION

The present invention relates to a system for measuring the length of wire or rod (4) which is aligned on alignment mechanisms (3) and cut by a cutting mechanism (6) into predetermined desired lengths. The wire or rod (4) is aligned and advanced into a vessel (7) until the desired length is advanced, at which point the cutting mechanism (6) is activated. The advancing length of wire or rod is measured on a measuring roll (32) connected to an electronic encoder (34). Along the length of the boat (7) there are sensors (40) at given points with a known distance from the cutting point of the wire or the rod (4). As the wire or rod (4) passes the sensors (40), the measuring system resets to zero and continues to measure from that sensor point by adding the known distance of the sensor (40) from the cutting point of the cutter (6) to obtain the actual length advanced. In this way, any measurement error originating from the electronic pulser (34), due to variations in the cross-section of the wire or rod which are often present, depending on the length of the wire or rod (4), is minimized.

Technical level cons

The wire and bettobarga is stored and transported in coils. The wire and rod are aligned in straightening machines and straight sections (9) of desired length are produced.

There are two basic types of alignment. The two-plane roller alignment (20) and the rotor alignment (25). In the two-level alignment with a roller, the wire is advanced into the alignment and with successive repeated bends in two levels it is aligned. Rotor alignment is distinguished into bushing rotors and roller rotors where the wire is bent in each direction and aligned as the rotor rotates.

The coil (2) with the wire or rod (4) is placed on the winder (1). The wire or rod (4) is guided to the straightening mechanism (3), which can be a cross-plane straightening unit (20) or a bushing rotor straightening unit or a roller rotor unit (25) and is then advanced to a vessel (7) . The advancing length of the material is measured by a measuring system (31), usually a measuring roller (32) whose revolutions are measured by an electronic encoder (34). The pulses of the pulsator (34) are transferred to an electronic processing unit (45) and are matched with the length of the propelled material. When the programmed length of wire or rebar (4) to be produced is completed, a cutting command is given to a material cutting mechanism (6). The material is cut, the vessel (7) is opened, the produced material is removed, the measurement is reset and the production of the next piece continues with a new measurement.

The surface of the betoverga is characterized by the transverse and longitudinal nerves. In addition, its cross-section shows ovality and cross-sectional differences along its length. The wire also exhibits ovality and cross-sectional differences along its length. The wire or rod (4) as it is advanced can and does rotate on its axis, particularly in rotor alignment systems.

The measuring roller (32) which drives the pulser (34) is pressed against the wire or rod (4) on a freely rotating roller (33) tracking the linear movement of the wire or rod (4). The accuracy of the measurement is based on the perfect adhesion of the measuring roller (32) to the advancing wire or the rod (4) so that there is no slippage between them. Any twisting of the wire or rod (4) relative to the measuring roller (32) causes the measuring roller (32) to slide on the wire or rod (4). In addition, the nerves on the rod as they pass through the rollers cause the measuring roller (32) to bounce and thus lose contact with the measuring wire or rod (4). These factors cause measurement error which is an increasing function of the advancing length of the wire or rod (4).

Purpose and scope of the present invention

The purpose of the present invention is to present a system for measuring the length of a wire or rod being advanced in alignment machines and mechanisms, minimizing the resulting errors from measuring the length with a pulse transducer.

The invention applies to any type of wire or rebar straightening machine, for any diameter and length for both low and high wire or rebar advance speeds (4).

The system is shown by way of example in the following figures:

Figure 1 : Illustrates a wire or rod alignment system.

Figure 2: Illustrates roller alignment.

Figure 3: Shows rotor alignment.

Figure 4A: Illustrates a roller rotor alignment machine.

Scheme 4B. It depicts the side view of the vessel of drawing 4A.

Plan 4C. Depicts the boat closed.

4D design. Depicts the boat open.

Figure 5A: Illustrates the measurement system with pulser and measurement correction sensors.

Figure 5B: Illustrates the side view of Figure 5A at a sensor point.

Figure 6: Illustrates the measuring system with roller and pulser.

Disclosure of the invention

The wire or rod (4) is stored in a coil (2) on a winder (1). The wire or rod (4) is guided to a straightening unit (3), which can be a flat straightener (20), a bushing rotor or a roller rotor (25).

After the alignment unit (3) the wire is guided to a measuring mechanism (31) consisting of two rollers, the measuring roller (32) connected to an electronic pulser (34) and a freely rotating roller (33). The measuring roller (32) is pressed by springs (37) or by an air cylinder or by an oil cylinder on the wire or rod (4), and then the wire or rod (4) on the roller (33). The measuring roller (32) moves through the shaft (36) and the transmission (35) the electronic pulser (34) which monitors the movement of the measuring roller (32) and the corresponding movement of the wire or the rod (4).

After the measuring unit (31) the wire or rod (4) passes through the cutting mechanism (6). The cutting mechanism can exert cutting force by pneumatic cylinder or hydraulic cylinder or by mechanical action.

After the cutting mechanism (6) there is a vessel (7) into which the wire or bettovarga (4) is guided. The vessel (7) consists of a guide channel and a cover, which can be actively opened or closed by the action of a mechanism such as a cylinder (38).

At selected positions along the length of the vessel (7) there are sensors (40), which detect the passage of a wire or rod (4) within the vessel (7) at the specific point of the sensor.

The measurement of the pulse generator (34) and the signals from the operation of the sensors (40) are transmitted to an electronic processing unit (45). In the electronic processing unit (45) the positions of the sensors (40) are stored with their exact distances from the cutting point

Given that the cut length is known, the sensors (40) containing the end of the cut wire or rod are selected in the processor.

By cutting, the internal counter of the processing unit (45) is zeroed and as the measuring roller (32) rotates entrained by the wire or rod (4), the pulse generator (34) rotates and transmits the measurement to the electronic processing unit (45). When the wire or rod (4) passes the last sensor (40) it will encounter before cutting, the electronic processing unit (45) corrects and continues the measurement from the length corresponding to said sensor. When the measurement completes the programmed length, a cutting command is given by the electronic processing unit (45). The wire or rod (4) is cut, the counter is reset, and the next aligned and cut wire or rod is produced in the same process.

Alternatively, the length measurement in the electronic unit (45) is corrected each time the wire or the rod (4) passes through a sensor (40).

With this procedure, any measurement error depending on the length of the wire or rod (4) is minimized within the limits of the measurement error menu that corresponds to the distance between two successive sensors (40), which is minimal. Depending on the length accuracy we aim for, we place more sensors.

Advantages

According to the invention:

The measuring system provides high accuracy regardless of length, is low cost and is applicable to all types of aligning machines. In machines with two-plane alignment, in machines with bushing rotors and in machines with roller rotors.

It is also applied to alignment mechanisms in various machines such as wire or rebar welding machines for mesh production.

It is applied to any type of cutting, with pneumatic, hydraulic or mechanical application of cutting force.

Generally about protection

The present invention is in no way limited to the embodiment described and illustrated in the drawings, but can be implemented in many forms and dimensions without leaving the scope of protection of the invention.

In the implementation of the invention, the materials used as well as the dimensions of the individual elements can be according to the requirements of the particular construction.

In each claim, where technical features are mentioned and followed by reference numbers, they are included only to increase the comprehensibility of the claims and in this way the reference numbers do not affect the consideration of the elements, which are identified by example with them.

List of names

1 Wind

2. Coil of wire or bettobarga

3. Alignment unit.

4. Wire or bettobarga.

6. Wire or rod cutting mechanism.

7. Boats.

9. Aligned and cut wires or betobars.

20. Two-level alignment unit.

25. Rotor alignment with roller.

31. Propelled wire or rod measuring mechanism.

32. Measuring tape.

33. Free roll.

34. Electronic pacemaker.

35. Transmission of motion to the pulse generator.

36. Measuring wheel shaft.

37. Gauge pressure spring.

38. Vessel opening and closing cylinder.

40. Wire or rod sensor.

44. Local cut of a wire vessel or bettovarga.

45. Electronic processing unit

Claims (3)

1. Length measurement system in wire and rod straightening machines in which the wire or rod (4) is aligned within a straightening unit (3), guided to a measuring unit (31) with length measurement by an electronic encoder (34), then guided to a unit cutting (6) and finally in vessels (7) with the measurement being transmitted to an electronic processing unit (45) characterized in that: along the vessel (7) one or more sensors (40) are placed to detect the wire or the bettobar (4), the exact distance of which from the cut point is known, fixed and stored in the electronic processing unit (45), where with each cut the processing unit (45) resets the measurement of the electronic pulser (34) and starts counting the advancing length of the wire or rod (4), initially and when the wire or rod (4) passes through the last sensor (40) that activates, the electronic processing unit corrects the measurement by continuing it from the stored value corresponding to the position of said sensor, when the measurement of the desired one is not completed length, a cutting command is given, the produced wire or rod is removed from the vessel and the process is repeated for the production of the next one. 2. System as stated in Claim 1 characterized in that: the processing unit resets the measurement from the pulser (34) and continues from the stored value corresponding to the position of each sensor (40) as soon as it is activated. 3. System as stated in Claim 1 and 2 characterized in that: one or more sensors (40) are placed in the vessel (7) depending on the precision sought in the cutting length.