KR20050112002A - Apparatus and method for brazing a diamond tool - Google Patents

Abstract

The present invention relates to an apparatus and method for brazing a diamond tool by high frequency induction heating, and more particularly, in order to maintain a molten state of a filler metal and to prevent melting of the filler metal due to excessive melting. A diamond tool brazing apparatus and method for controlling the waveform of a heating current. The diamond tool brazing apparatus according to the present invention comprises: a plurality of temperature measuring means for measuring a temperature value of the brazing object in order to braze the brazing object in which the filler metal is located between the diamond sintered body and the shank by high frequency induction heating; Melt state predicting means for determining whether or not the filler metal is melted and a predicted temperature value from the temperature values measured by the temperature measuring means; And current control means for changing the induction heating current by comparing the predicted temperature value with a set temperature value.

Description

Apparatus and method for brazing a diamond tool}

The present invention relates to an apparatus and method for brazing a diamond tool by high frequency induction heating, and more particularly, in order to maintain a molten state of a filler metal and to prevent melting of the filler metal due to excessive melting. A diamond tool brazing apparatus and method for controlling the waveform of a heating current.

Diamond tool brazing is a method of fixing a diamond sintered body to a shank by using a flame or by melting a filler material placed between the diamond sintered body and the shank using a high frequency induction heating apparatus.

Recently, the method of applying laser welding to the diamond tool brazing has also been used, but it requires an expensive laser oscillator, which requires a large investment of production equipment, and requires ultra-precision welding technology by requiring the dimensional precision of the diamond sintered body. There is a problem that is not easy.

On the other hand, in the diamond tool brazing by high frequency induction heating, the dimensional accuracy of the diamond sintered body is not important, and it is widely used because good quality can be secured by controlling the appropriate temperature and applying the pressing force of the diamond sintered body evenly.

The conventional diamond tool brazing by high frequency induction heating is mainly dependent on the brazing by hand of an experienced operator, and thus the quality of the brazing part varies according to the working environment and skill of the operator.

Diamond tool brazing automation equipment has been developed to solve this problem. However, most of the existing equipment sets a constant high frequency induction heating time and heats it or attaches a temperature sensor to the brazing heating part and stops the induction heating when the set temperature is reached. have. In addition, since the method of measuring the temperature predicts the melting part temperature of the filler metal by solving a simple thermal conductivity equation based on the temperature value of one point, it is difficult to accurately determine the melting state of the filler metal.

That is, the induction heating is performed without considering the brazing characteristics of the filler metal, and the quality of the brazing part is deteriorated due to defects due to insufficient melting of the filler metal or melting of the filler metal due to excessive induction heating.

An object of the present invention is to provide a diamond tool brazing apparatus and method which can obtain excellent brazing quality by measuring the temperature change of the brazing heating unit with a plurality of temperature sensors and controlling the induction heating current value for each time.

A diamond tool brazing apparatus according to the present invention for solving the above technical problem, a plurality of measuring the temperature value of the brazing object in order to braze the brazing object in which the filler metal is located between the diamond sintered body and the shank by high frequency induction heating Temperature measuring means; Melt state predicting means for determining whether or not the filler metal is melted and a predicted temperature value from the temperature values measured by the temperature measuring means; And current control means for changing the induction heating current by comparing the predicted temperature value with a set temperature value.

The temperature measuring means is preferably an infrared temperature sensor, and more preferably measures the temperature values of the filler metal and the shank together.

Preferably, the current control means increases the induction heating current when the predicted temperature value is smaller than the set temperature value, and decreases the induction heating current when the predicted temperature value is larger than the set temperature value. It is desirable to step up or down the current.

On the other hand, the diamond tool brazing method according to the present invention for solving the above technical problem, (a) heating the brazing object to braze the high frequency induction heating brazing object in which the filler metal is located between the diamond sintered body and the shank; (b) measuring temperature values of the brazing object at a plurality of points; (c) after a predetermined time elapses, compare the predicted temperature value of the filler metal predicted from the measured temperature values with a set temperature value, and set the induction heating current to increase when the predicted temperature value is smaller than the set temperature value, Setting the induction heating current to decrease when the predicted temperature value is greater than a set temperature value; (d) heating the brazing object with the induction heating current set in step (c); (e) performing steps (b) and (c), wherein the set temperature value is set to a melting temperature value of the filler metal; And (f) heating the brazing object with the induction heating current set in the step (e) for a predetermined time and then ending the heating.

In the step (b), it is preferable to measure temperature values with an infrared temperature sensor, and more preferably to measure temperature values together in the filler metal and the shank.

In the step (c), it is preferable to increase or decrease the induction heating current stepwise.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a view schematically showing a temperature measuring means of a diamond tool brazing apparatus and method according to a preferred embodiment of the present invention, Figure 2 is a flow chart of a diamond tool brazing method according to a preferred embodiment of the present invention.

The diamond tool brazing apparatus according to the preferred embodiment of the present invention further includes a plurality of temperature measuring means, melt state predicting means and current control means in addition to the configuration of the conventional diamond tool brazing apparatus.

Conventional diamond tool brazing apparatus includes a heating coil for high frequency induction heating, a device for automatically loading the diamond sintered body (1), a device for fixing the shank (3), the filler metal (2) to the diamond sintered body (1) and the shank (3) It is composed of devices inserted between).

The plurality of temperature measuring means 10 can measure the temperature in a state separated from the point to be measured as an infrared temperature sensor, it is possible to measure from 300 ℃ to 1000 ℃. As a measurement point, the diamond sintered compact 1 part in addition to the filler metal 2 part is measured at two or more points.

The melt state predicting means determines whether the filler metal 2 is melted and the predicted temperature value of the filler metal 2 based on the temperature values measured from the plurality of temperature measuring means 10.

The current control means compares the predicted temperature value with the set temperature value and quickly changes the induction heating current in the form of a step signal. When the predicted temperature value is smaller than the set temperature value, the induction heating current is increased, and when the predicted temperature value is larger than the set temperature value, the induction heating current is decreased to maintain the molten state of the filler metal 2 as much as possible.

On the other hand, the diamond tool brazing method according to a preferred embodiment of the present invention is as follows.

First, the diamond sintered body 1 and the shank 3 to be brazed are supplied and the filler metal 2 is positioned therebetween (S100).

The temperature measurement is made by the infrared temperature sensor 10 at a plurality of points, the filler metal 2 portion (hereinafter referred to as " first measuring point " for convenience) and upward from the filler metal 2 in the diamond sintered body 1 Points separated by a predetermined distance (hereinafter referred to as "second measurement point" for convenience) and points separated by a predetermined distance upward from the second measurement point (hereinafter referred to as "third measurement point" for convenience) are respectively the first to the first. 3 sensors 10a, 10b, and 10c measure.

It is possible to grasp the overall temperature distribution of the diamond sintered body (1) and the filler metal (2) by the temperature values measured at the first to third measurement points, based on the prediction of the melting of the filler metal (2) and prediction of the filler metal (2) The temperature value is determined.

Next, a predetermined induction heating current value is set and the diamond sintered body 1 and the shank 3 are heated by a heating coil. Induction heating current value is set by the method used in the conventional diamond tool brazing apparatus (S110).

The heating proceeds according to the induction heating current value set as described above, and it is determined whether the first step end time arbitrarily set by the user has elapsed (S120).

Induction heating by the initial set current value continues until the end of the first step, and when the first step ends, the predicted temperature value is compared with the set temperature value (S130). If the predicted temperature value is greater than the set temperature value, the induction heating current is reduced (S131). If the predicted temperature value is smaller than the set temperature value, the induction heating current is increased (S132). At this time, the increase and decrease of the induction heating current is made in the form of a step signal, that is, in a stepwise manner, and the same in subsequent steps.

The above processes (S100 to S132) are the first step, which is to base the induction heating current setting in the second and third steps on the predicted temperature value at the end of the first step.

Thereafter, heating continues with the newly induced induction heating current through the first step, and it is determined whether the second step end time arbitrarily set by the user has elapsed (S140).

When the second step ends, the predicted temperature value and the filler metal melting temperature value are compared (S150). If the predicted temperature value is greater than the filler metal melting temperature value, the induction heating current is reduced (S151). If the predicted temperature value is smaller than the filler metal melting temperature value, the induction heating current is increased (S152). Here, the filler metal melting temperature value is changed depending on the material of the filler metal (2).

The above process (S140 ~ S152) is the second step, which is to heat the filler metal 2 to approach the melting temperature of the filler metal (2).

Subsequently, heating continues with the newly set induction heating current through the second step, and it is determined whether the third step end time, that is, the final end time, arbitrarily set by the user (S160).

When the third stage end time is reached, heating is terminated, and the temperature waveform measured by each temperature sensor 10 is stored and used as basic data for subsequent brazing operation. The third step maintains the liquid phase of the filler metal (2) to increase the wettability at the bonding interface between the diamond sintered body (1) and the filler metal (2) and the bonding interface between the shank (3) and the filler metal (2). It is to prevent the melt of the filler metal (2) due to.

Hereinafter, the experimental results by the diamond tool brazing apparatus and method according to a preferred embodiment of the present invention will be described.

3A is a temperature change diagram according to a conventional brazing method performed without changing the induction heating current, and FIG. 3B is a diagram illustrating a method of changing the induction heating current in each step by dividing the brazing time into three steps. This is the temperature change diagram by the brazing method.

The filler metal used in the experiment (2) is Ag-Cu-Zn-Cd alloy filler metal (BAg1), generally set the melting temperature between 620 ℃ 760 ℃ and brazing. In this experiment, both the conventional brazing method and the brazing method according to the present embodiment set the brazing target temperature when the temperature measured by the second sensor 10b became about 700 ° C. and performed the experiment.

As shown in Figs. 3A and 3B, the temperature when the induction heating current was cut off in both methods was similar at 700 ° C. However, looking at the temperature change, in the conventional brazing method, the measured temperature is constantly increased until the induction heating current interruption time point (14 seconds), the brazing method according to the present embodiment the measured temperature is the third step (10 seconds ~) 14 seconds), the difference was reduced.

In this experiment, brazing part quality was examined by using torque value in bending test, one of mechanical property evaluation items, to compare the difference of brazing part quality by both methods. The results are shown in Table 1, and the brazing method according to the present embodiment shows better results.

Brazing method Bending Torque Value (Nm) Conventional Brazing Method 21 Method according to this embodiment 37

To achieve good brazing quality, melt so that the amount of filler metal (2) present in the liquid phase between the diamond sintered body (1) and the shank (3) is sufficient after the melting of the filler metal is started until the final target temperature is reached. The state must be maintained. In the brazing method according to the present embodiment, the molten state is maintained so that the wettability at the bonding interface between the diamond sintered body 1 and the filler metal 2 and the bonding interface between the shank 3 and the filler metal 2 is increased in the third step. The brazing part quality is remarkably improved compared to the brazing method.

Preferred embodiments of the present invention described above are disclosed for purposes of illustration, and the brazing process can be further divided into three or more steps. Furthermore, those skilled in the art having ordinary knowledge of the present invention will be able to make various modifications, changes and additions within the spirit and scope of the present invention, and such modifications, changes and additions should be regarded as belonging to the following claims.

As described above, the diamond tool brazing apparatus and method according to the present invention, by measuring the temperature value with a plurality of temperature sensors to more accurately grasp the molten state of the filler metal, by dividing the brazing process in several stages, the filler metal is diamond It has the effect of producing a diamond tool having excellent strength without defects by maintaining the molten state so as to sufficiently wet the sintered body and the shank.

1 shows schematically a temperature measuring means of a diamond tool brazing apparatus and method according to a preferred embodiment of the present invention.

2 is a flow diagram of a diamond tool brazing method according to a preferred embodiment of the present invention.

Figure 3 is a view comparing the temperature change according to the diamond tool brazing apparatus and method according to a preferred embodiment of the present invention with the temperature change by the conventional brazing method.

Claims (9)

In the diamond tool brazing apparatus for brazing the high frequency induction heating of the brazing object in which the filler metal is located between the diamond sintered body and the shank, A plurality of temperature measuring means for measuring a temperature value of the brazing object; Melt state predicting means for determining whether or not the filler metal is melted and a predicted temperature value from the temperature values measured by the temperature measuring means; And And current control means for changing the induction heating current by comparing the predicted temperature value with a set temperature value. The method of claim 1, wherein the temperature measuring means Diamond tool brazing device, characterized in that the infrared temperature sensor. The method of claim 1 or 2, wherein the temperature measuring means A diamond tool brazing device, characterized in that for measuring the temperature values of the filler metal and the shank together. The method of claim 1, wherein the current control means When the predicted temperature value is smaller than the set temperature value, the induction heating current is increased, And the induction heating current is reduced if the predicted temperature value is greater than the set temperature value. The method of claim 4, wherein the current control means A diamond tool brazing device, characterized by stepwise increasing or decreasing the induction heating current. In the diamond tool brazing method of brazing a high frequency induction heating brazing object in which the filler metal is located between the diamond sintered body and the shank, (a) heating the brazing object; (b) measuring temperature values of the brazing object at a plurality of points; (c) after a predetermined time elapses, compare the predicted temperature value of the filler metal predicted from the measured temperature values with a set temperature value, and set the induction heating current to increase when the predicted temperature value is smaller than the set temperature value, Setting the induction heating current to decrease when the predicted temperature value is greater than a set temperature value; (d) heating the brazing object with the induction heating current set in step (c); (e) performing steps (b) and (c), wherein the set temperature value is set to a melting temperature value of the filler metal; And and (f) heating the brazing object with the induction heating current set in step (e) for a predetermined time and then ending the heating. The method of claim 6, wherein step (b) Diamond tool brazing method characterized by measuring the temperature values with an infrared temperature sensor. The method of claim 6 or 7, wherein step (b) Diamond tool brazing method characterized in that the temperature values are measured together in the filler metal and the shank. The method of claim 6, wherein step (c) A method for brazing a diamond tool, characterized by stepwise increasing or decreasing the induction heating current.