JPH0261335B2 - - Google Patents

Description

[Detailed Description of the Invention] [Field of Industrial Application] The present invention relates to a method for hot bending pipes and an apparatus therefor, and in particular, a method using high-frequency induction heating aimed at suppressing thinning of the bent portion. , relates to a method for hot bending pipes and an apparatus therefor.

[Conventional technology]

First, we will discuss the method and equipment for hot bending of pipes using conventional high-frequency induction heating.
This will be explained with reference to FIGS.

FIG. 1 is a plan view showing an outline of an apparatus used for carrying out a conventional hot bending method for pipes using high-frequency induction heating, and FIG.
The cross-sectional view, FIG. 3, is a bending radius ratio-thickness reduction rate characteristic diagram showing the relationship between the bending radius ratio and the thickness reduction rate of a pipe according to a conventional pipe hot bending method.

In FIG. 1, 1 is a pipe to be bent, and 2 is a perfectly circular heating coil disposed around the outer periphery of the bent portion of the pipe 1. In FIG. For example, the outer diameter of pipe 1 is D ₀ =90mmφ, and the inner diameter of heating coil 2 is
100mmφ, coil gap 5mm (uniform on the circumference). 5 is a rotating arm 9 that clamps one end of the pipe 1 and can freely rotate around a pivot 6;
are guide rolls that support the pipe 1 and restrict the moving direction of the pipe 1 to the straight direction.

According to the conventional pipe hot bending method using the apparatus shown in FIG. 1 having such a structure, the pipe 1 is uniformly heated in the circumferential direction by the perfectly circular heating coil 2. By soaking, pipe 1
By suppressing the average deformation resistance of the pipe 1 to a small value and reducing the processing force, the processing force 4
By applying a load to the rotary arm 5, the rotary arm 5 can be rotated around the pivot 6, and the pipe 1 can be bent.

[Problem to be solved by the invention]

According to the above-mentioned conventional technology, the outer bent portion 1a of the pipe 1 is thinned due to the axial tensile stress generated by the processing force 4 (the inner bent portion 1b is
On the contrary, the meat increases). In particular, when the bending radius r is made smaller, the rate of thinning increases.

Thickness reduction rate = (t ₀ - t) / t x 100% where t ₀ = thickness of pipe before bending t = thickness of pipe after bending For example, if r = 1.5D ₀ , Fig. 3 As is clear from the above, the thickness reduction rate was 19%, and there was a problem in that it was not possible to satisfy the required specification for the thickness reduction rate of 12.5% or less in consideration of pressure resistance characteristics.

The present invention has been made to solve the problems of the prior art described above, and it is possible to properly control the temperature difference between the outside of the bend and the inside of the bend in pipe bending using high-frequency induction heating. It is an object of the present invention to provide a method for hot bending a pipe that can suppress thinning of the processed portion, and an apparatus that can be used directly for carrying out the method.

[Means to solve the problem]

In order to achieve the above object, the pipe hot bending method according to the present invention is configured such that the bending part of the pipe is heated by high-frequency induction using a heating coil disposed around the outer periphery of the bending part of the pipe. In the pipe hot bending method, in which the heating coil heats the outside of the pipe at a temperature lower than the heating temperature inside the pipe when bending the pipe, during the bending of the pipe, The gap between the heating coil and the bent portion of the pipe is adjusted so that the temperature of the bent outside portion of the pipe reaches a preset temperature.

In order to achieve the above object, the pipe hot bending apparatus according to the present invention has a structure including a device that moves the pipe in the axial direction, a device that clamps one end of the pipe, and a device that clamps one end of the pipe and freely moves the pipe around the other end. A rotary arm that can be rotated to a certain angle, and a heating coil disposed around the outer periphery of the bending portion of the pipe, such that the gap between the heating coil and the bending portion of the pipe is larger on the outside of the bend than on the inside of the bend. In the pipe hot bending apparatus, the pipe is bent by rotating the pipe with the rotary arm while the heating coil heats the bending part of the pipe using high-frequency induction, The apparatus further includes a coil position control device that controls the position of the heating coil and adjusts the gap so that the temperature of the heating coil reaches a preset temperature.

[Effect]

The working of the above technical means is as follows.

The shape of the heating coil is, for example, an ellipse, and a coil position control device is provided to increase the coil gap on the side where the thickness is reduced (the outside part of the bend) and to make it small on the side where the thickness increases (the inside part of the bend). By providing a temperature distribution in the circumferential direction of the pipe and giving a gradient to the deformation resistance, it is possible to shift the bending neutral axis to the thinning side (bending outer side) and suppress thinning.

〔Example〕

Embodiments of the present invention will be described below with reference to FIGS. 4 to 7.

In FIG. 4, 1 is a pipe to be bent, 5 is a rotating arm that clamps one end of the pipe 1 and can freely rotate around a pivot 6;
is a pusher connected to the other end of pipe 1, 8
is a hydraulic cylinder for applying a working force 4 to the pipe 1 in the axial direction via a pusher 7, and 9 is a guide roll that supports the pipe 1 and restricts the moving direction of the pipe 1 to the straight direction.

2A is an oval heating coil (2c is the major axis, 2d is the minor axis) as shown in detail in FIG. It is arranged around the outer periphery of the bent portion of the pipe 1 so that the diameter is larger than that of the pipe 1. A two-color thermometer 3 is attached to the heating coil 2A to detect the temperature at the neutral part of the pipe 1 (the temperature here is approximately equal to the average temperature of the heating area of the pipe 1) without contact. ing. 11 is a high-frequency oscillator that supplies a high-frequency current to the heating coil 2A, and 10 is a high-frequency oscillator that supplies cooling water to the pipe 1 in order to prevent the heated area by the heating coil 2A from exceeding the area required for bending. This cooling ring 10 is disposed before and after the heating coil 2A (in the left-right direction in FIG. 4).

A method of hot bending a pipe using the apparatus shown in FIG. 4 configured as described above will be explained.

First, pipe 1 (outer diameter D ₀ = 90mmφ, plate thickness 4mm
(carbon steel) is placed between the guide rolls 9, one end of which is clamped to the rotating arm 5, and the other end is connected to the pusher 7. On the outer periphery of the bent part of pipe 1,
Heating coil 2A and cooling ring 10 before and after it
Setting. The heating coil 2A has a major axis 2c (inner diameter) of 110 mm and a minor axis 2d (inner diameter) of 100 mm.
It has an elliptical shape, and the major axis 2c is placed within the plane of the bend, and the coil gap 2a on the outside of the bend is 15 mm, and the coil gap 2b on the inside of the bend is 5 mm.

The high frequency oscillator 11 is energized and its output is input to the pipe 1 via the heating coil 2A. An induced current flows through the pipe 1 due to the alternating magnetic field generated near the heating coil 2A due to the high frequency, and heat is generated due to ohmic loss within the pipe 1. Cooling water is then injected from the cooling ring 10 toward the pipe 1 to prevent the heated area of the pipe 1 from becoming larger than a necessary area (if the heated area expands too much, the pipe 1 will buckle).

When the detected value of the two-color thermometer 3 rises to a predetermined temperature, a working force 4 is applied to the heated pipe 1 in the axial direction by a hydraulic cylinder 8 via a pusher 7. However, since one end is clamped to the rotating arm 5, the pipe 1 is guided around the pivot 6 with a predetermined bending radius r (=1.5D ₀ =135 mm). The pipe 1 is subjected to hot bending by the bending moment generated thereby.

During this hot bending process, the bending outer part 1 of the pipe 1
The temperature of a is 600°C, and the temperature of the bent inner part 1b is 900°C.
(The bending inner part 1b is closer to the coil gap 2.
b is small, resulting in high temperature), and the respective deformation resistances are 11 Kgf/mm ² and 5 Kgf/mm ² , so the bending neutral axis moves from the center of the pipe 1 to the outside.

The thickness reduction rate of the bent outer part 1a of the pipe 1 hot bent in this way is 19
% was reduced to 11% in this example,
Able to meet the required specification of 12.5% or less.

FIG. 7 is a plane view showing an example of the essential parts of an apparatus used for carrying out a hot bending method for pipes according to another embodiment of the present invention, and a pipe to be bent by the apparatus; It is a diagram.

In FIG. 7, parts given the same reference numerals as those in FIG. 4 are the same parts, so their explanation will be omitted.

The embodiment shown in FIG. 7 shows the most typical example of the present invention.

In FIG. 7, 3A indicates a two-color thermometer that is attached to the heating coil 2B and measures the temperature of the bent outer portion 1a of the pipe 1 without contact.

12 is based on the detected value of the two-color thermometer 3A,
This coil position control device is capable of controlling the position of the heating coil 2B by adjusting the coil gap 2a so that the temperature of the bent outer portion 1a of the pipe 1 becomes a pre-measured set temperature.

The cooling ring 10 is fixed at a fixed position so as not to change the cooling effect.

With this configuration, in the embodiment shown in FIG. 7, during the bending process of the pipe 1, the temperature of the bent outer part 1a of the pipe 1 is measured with the two-color thermometer 3A, and the operation is performed based on the detected value. Coil position control device 12
As a result, the coil gap 2a on the outside of the bend is controlled to an appropriate heating coil position larger than the coil gap 2b on the inside of the bend so that the temperature of the outside of the bend 1a becomes a preset temperature.

As a result, during the bending process of the pipe 1, the temperature of the bent outer part 1a of the pipe 1 is always kept constant,
Since the temperature difference between the outside of the bend and the inside of the bend is properly controlled, and the wall thinning rate is also stabilized, it is possible to perform hot bending of the pipe more stably than in the example shown in Fig. 4. Become.

According to each of the embodiments described above, thinning of the bending portion of the pipe 1 can be suppressed, and the processing limit can be significantly improved. In other words, the minimum bending radius r that can suppress the thinning rate of the bent part to 12.5% or less
, from the conventional 3.0D ₀ (D ₀ : outer diameter of the pipe),
The diameter can be reduced to 1.5D ₀ , which greatly contributes to making the shape of molded products more compact.

〔Effect of the invention〕

As explained in detail above, according to the present invention,
Provides a method and apparatus for hot bending a pipe that can appropriately control the temperature difference between the outside and inside of the bend in pipe bending using high-frequency induction heating, and prevent thinning of the bending part. can do.

[Brief explanation of the drawing]

Fig. 1 is a plan view showing an outline of a device used to carry out a conventional hot bending method for pipes using high-frequency induction heating, Fig. 2 is a cross-sectional view of Fig. 1, and Fig. 3 is a cross-sectional view of Fig. 1. 4 is a bending radius ratio-thickening rate characteristic diagram showing the relationship between the bending radius ratio and the thinning rate of a pipe according to a conventional pipe hot bending method, and FIG. FIG. 5 is a plan view showing an example of an apparatus used for hot bending a pipe and a pipe to be bent by the apparatus. FIG. 5 shows details of the vicinity of the heating coil in FIG. 4. The plan view shown in FIG. 6 is a cross-sectional view of FIG.
The figure is a characteristic diagram showing an example of a main part of an apparatus used for carrying out a hot bending method for pipes according to another embodiment of the present invention, and a pipe to be bent by the apparatus. be. 1...pipe, 1a...bending outer part of the pipe,
1b...Bending inner side of the pipe, 2A, 2B...Heating coil, 2a...Coil gap on the outside bending,
2b... Coil gap on the inside of the bend, 2c... Long diameter of the heating coil, 2d... Short diameter of the heating coil,
3,3A...Two-color thermometer, 11...High frequency oscillator, 12...Coil position control device.

Claims (1)

[Claims] 1. When bending the pipe while heating the bending part of the pipe with high-frequency induction heating using a heating coil disposed around the outer periphery of the bending part of the pipe,
In the pipe hot bending method in which the heating temperature of the outer side of the pipe is bent by the heating coil to be lower than the heating temperature of the inner side of the pipe, during the bending process of the pipe, the temperature of the outer side of the pipe is set in advance. To achieve the set temperature,
A method for hot bending a pipe, characterized in that a gap between the heating coil and the bending portion of the pipe is adjusted. 2. A device for moving the pipe in the axial direction, a rotating arm that clamps one end of the pipe and can freely rotate around the other end, and a heating coil disposed around the outer periphery of the bent portion of the pipe, The heating coil is configured such that a gap between the heating coil and the bent portion of the pipe is larger on the outside of the bend than on the inside of the bend, and while the bent portion of the pipe is heated by high frequency induction with the heating coil. In the pipe hot bending apparatus that bends the pipe by rotating the pipe with the rotary arm, the position of the heating coil is controlled so that the temperature of the outer side of the bent pipe becomes a preset temperature. A pipe hot bending device characterized by being equipped with a coil position control device for adjusting the gap.