JPH01100412A - Identification of aluminum shape member and apparatus therefor - Google Patents

Abstract

PURPOSE:To simplify the identification of an aluminum shape member, by automatically computing the peripheral length of the cross section and the cross sectional area of the aluminum shape member, and retrieving the aluminum shape member, whose peripheral length of the cross section and the cross sectional area agree with the computed peripheral length of the cross section and cross sectional area, out of a computer. CONSTITUTION:When a frame is formed, a worker takes an aluminum shape member 4 out of a pallet 5. The end surface is photographed with an ITV camera 7. The image signal is sent in to a computer 8, where the image is processed. Thus, the peripheral length of the cross section and the cross sectional area are computed. At the same time, the shape number of an aluminum shape member, whose peripheral length of the cross section and cross sectional area agree with those of the aluminum shape member 4, is retrieved from a host computer 10. The data on the shape number are displayed on a display device 9. At this time, a cross sectional shape 12 of the aluminum shape member and shapes 13 and 14 of a plurality of aluminum shape members are displayed on the display device 9. The worker observes the screen of the display device 9, selects the shape number of the aluminum shape member having the agreed cross sectional shape and inputs the number into the computer 8.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a method and apparatus for identifying the cross-sectional shape of an aluminum profile forming a sash frame or the like when the profile is subjected to alumite treatment.

[Conventional technology]

The alumite treatment of aluminum profiles is generally carried out as follows.

In other words, a long aluminum shape with a predetermined cross section is extruded from an aluminum ingot using an extruder, the long aluminum shape is cut into a predetermined length to form an aluminum shape, and the aluminum shape is placed on a pallet for alumite treatment. Transport to location.

Then, aluminum 15 material is taken out from the pallet transported to the alumite processing site and attached to the electrolytic frame, and the electrolytic frame is lifted with a crane or the like and immersed in the electrolytic tank, and at the same time a current is supplied to the electrolytic frame. I have to.

In this type of alumite treatment, it is necessary to set the current value supplied to the electrolytic frame according to the total surface area of the framed aluminum shape, so conventionally, a collection of mold materials with model numbers corresponding to the cross-sectional shape was prepared in advance. When the worker creates a frame and frames it, he or she looks in the collection of aluminum shapes, searches for the model number of the aluminum shape to be framed, writes the searched model number on a slip, and sends it to the next process.In the next process, an electric current is applied to the electrolytic frame. The supply worker looks at the slip and operates a current regulator, such as a rectifier, to set the current value to match the total surface area.

[Problem that the invention seeks to solve]

In this way, when anodizing an aluminum profile, the operator has to compare the cross-sectional shape of the aluminum profile with the profile collection to identify the model number, that is, the cross-sectional shape, of the aluminum profile, which is a very troublesome operation. . In particular, when aluminum shapes with different cross-sectional shapes are placed on a pallet, the above-mentioned identification operation must be performed for each piece, which is not only very troublesome, but also may lead to mistaken identification. be.

SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide an aluminum profile identification method and apparatus that allows the cross-sectional shape of an aluminum profile to be easily identified.

[Means and effects for solving the problem] Automatically calculate the cross-sectional outer circumference length and cross-sectional area of the aluminum profile, and search the host computer for an aluminum profile that matches the calculated cross-sectional outer circumference length and cross-sectional area. This makes it easy to identify aluminum shapes.

〔Example〕

As shown in Fig. 1, a long aluminum profile with a predetermined cross section is extruded from an aluminum ingot in the extrusion molding section 1 of a molding factory A, and the long aluminum profile is cut into a predetermined length in a cutting section 2. Aluminum shapes are placed on the pallet in the pallet I/placement section 3, and the pallet 5 on which the aluminum shapes 4 are placed
The frames of the alumite processing factory B are transported to department 6.

An ITV camera 7, a small computer 8, and a display 9 are installed in each of the frame units 6, and this computer 8 is connected to a large host computer 10, and the host computer 10 has many types of computers. The cross-sectional outer circumference and cross-sectional area of an aluminum profile with a cross-sectional shape are stored in advance along with the model number of the aluminum profile, and the extrusion molding section 1 stores the model number of the extruded long aluminum profile, that is, the model number corresponding to the extrusion mold. host computer 1
A small computer 11 for inputting data to the computer 10 is installed.

Note that the model number and the like may not be stored in advance in the host computer 1o, but may be stored from the computer 11 described above.

When framing, the worker takes out the aluminum profile 4 from the pallet 5, photographs its end face with the ITV camera 7, sends the image signal to the computer 8, processes the image, and calculates the cross-sectional outer circumference length and cross-sectional area. At the same time, the host computer 10 searches for the model number of the aluminum profile that matches the cross-sectional outer circumference length and cross-sectional area, and displays the model number data on the display 9.

At this time, the cross-sectional shape 12 of the aluminum profile and the host computer 10 are displayed on the display 9, as shown in FIG.
More searched cross-sectional shapes of multiple similar aluminum profiles 13
．． 14 is displayed.

This is the case when there are multiple aluminum shapes that match the calculated cross-sectional outer circumference length and cross-sectional area; otherwise, the cross-sectional shape of one aluminum shape is displayed.

The operator looks at the screen of the disc brace 9, selects the model number of the aluminum profile with the matching cross-sectional shape, in this case, the model number of the aluminum profile with the cross-sectional shape (13), and inputs it into the computer 8.

The computer 8 calculates a current value corresponding to the surface area of the model number, outputs a control signal to the current regulator 16 of the alumite processing section 15, and sets the current value to be supplied to the electrolytic frame.

The current value is set so that the current value corresponds to the total surface of the aluminum shapes when the aluminum shapes are suspended from the electrolytic frame and immersed in the electrolytic bath.

In addition, in the example, the model number of the extruded long aluminum profile is input into the host computer 10, so the model number of the aluminum profile can be searched based on the cross-sectional outer circumference and cross-sectional area from the computer 8. Since the model number is determined, not only can searches be made more smoothly, but the number of searches for aluminum shapes with similar cross-sectional shapes can be minimized.

As shown in FIG. 3, the ITV camera 7 is installed at one end of a cylindrical body 20, and a translucent filter 21 is attached to the middle of the cylindrical body 20, so that light from a light source 22 passes through the translucent filter. 21 is irradiated obliquely, and the end of the aluminum profile 4 is inserted toward the translucent filter 21 from the other end of the cylindrical body 20.

In this way, the light will weakly hit the end face of the aluminum profile 4 and will be reflected diffusely, and the hand holding the aluminum profile 4 will not be exposed to ITV.
The cross-sectional shape of the aluminum profile 4 can be accurately photographed without being photographed by the camera 7.

The semi-transparent filter is preferably a material that reflects as little light as possible from the light source, such as ground glass or celluloid.

〔Effect of the invention〕

Since aluminum shapes can be searched by the host computer 10, there is no need for the operator to identify aluminum shapes while looking at a collection of shapes as in the past, and the operation is simplified.

[Brief explanation of the drawing]

The drawings show an embodiment of the present invention; FIG. 1 is an explanatory diagram of the overall configuration, FIG. 2 is a display example of a display, and FIG. 3 is an IT
FIG. 3 is a cross-sectional view of the mounting portion of the V camera. 7 is an ITV camera, 8 is a computer, and 10 is a host computer.

Claims (1)

[Claims] 1. Automatically calculate the cross-sectional outer circumference length and cross-sectional area of the aluminum profile, and select the aluminum profile that matches the calculated cross-sectional outer circumference length and cross-sectional area by combining the cross-sectional outer circumference length and cross-sectional area of a large number of aluminum profiles. A method for identifying aluminum profiles, characterized in that a search is performed using a host computer 10 that stores the area. 2. An ITV camera 7 that photographs the end face shape of the aluminum profile, a computer 8 that processes the image signal to calculate the cross-sectional outer circumference length and cross-sectional area, and a computer 8 that stores the cross-sectional outer circumference length and cross-sectional area of a large number of aluminum profiles. An aluminum profile identification device comprising a host computer 10 that searches for an aluminum profile corresponding to the cross-sectional outer circumference length and cross-sectional area inputted from the computer 8.