JP2001071220A - Heat press fit device for metal part - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a heat press fit device for a metal part capable of quickly solidifying a fused workpiece when press-fitting the metal part. SOLUTION: In a heat press fit device for a metal part constituted by heating the metal part to a temperature capable of melting a workpiece formed of thermoplastic resin material to melt a press fitting position of the workpiece by heat of this metal part in this way so as to press fit it to the workpiece, an air injection nozzle 31 blowing air is provided for solidifying the workpice melted according to press fitting of the metal part.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for heating and press-fitting a metal part into a work made of a thermoplastic resin material.

[0002]

2. Description of the Related Art Conventionally, when a metal part such as a nut is press-fitted into a work made of a thermoplastic resin material, a heating press-fitting device has been used. As this heating press-in device, a press-in device for metal parts disclosed in Japanese Patent Application Laid-Open No. 9-267223 previously created by the applicant is known. This press-fitting device arranges metal parts in a cylindrical storage pipe extending vertically,
By heating the storage block to which the storage pipe is connected by an electric heating element, the metal parts below the storage pipe are heated, and the heated metal parts are separated and supplied to the chuck unit one by one by the separation supply means. Supply hold,
The metal part is configured to be extruded and press-fitted onto a work by a stem that operates in response to the driving of the reciprocating drive source. At the time of press-fitting, the metal component is press-fitted to a predetermined position by melting the work with its own heat.

[0003]

However, in the above-described conventional metal part press-fitting apparatus, since solidification of a melted work at the time of press-fitting a metal part relies on natural cooling, it takes time to complete solidification. If the metal part is released by returning the press-fitting tool before the work is completely solidified, the metal part will be displaced or the metal part will be lifted off the work surface due to solidification and expansion of the work. Had occurred. In order to cope with such a problem, in the conventional press-fitting device, the press-fitting tool has to be stopped and held for a while at the stage when the metal component is press-fitted into a predetermined position. New problems such as a long time have occurred. In addition, in the above-mentioned conventional press-fitting device, the press-fitting tool is heated and kept in advance for the purpose of preventing heat loss of the metal parts. It was getting longer.

[0004]

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned problems, and is directed to an apparatus for heating and press-fitting a metal part capable of early solidifying a molten work by heating and press-fitting the metal part. It is intended to be provided. In order to achieve this object, the present invention heats a metal part to a temperature at which a work made of a thermoplastic resin material can be melted, and melts the press-fitting position of the work by the heat of the metal part, thereby connecting the metal part to the work. A heating and press-fitting device for press-fitting a metal component, characterized by comprising cooling means for blowing air to solidify a work melted by the press-fitting of the metal component.

Another object of the present invention is to provide a metal component heating press-fitting device for press-fitting a metal component having a hollow hole opened at at least one end surface into a work made of a thermoplastic resin material.
A pressing bush that can reciprocate in response to the driving of the reciprocating drive source is provided, and a holding rod that can be inserted into the hollow hole of the metal component is arranged on the pressing bush so as to always urge it to protrude toward the distal end, The holding rod is provided with a locking member that extends in the hollow hole when the holding rod is inserted into the hollow hole of the metal component, and the locking member extends in the hollow hole of the metal component, whereby the metal component is attached to the tip of the holding rod. A heating unit capable of heating the metal component held at the tip of the holding rod is provided while holding the metal component, and the metal component heated by the heating unit is configured to be press-fitted into a work. This can also be achieved by a configuration in which cooling means for blowing air near the press-fitting position is provided to solidify the work melted by the press-fitting. In this configuration, it is preferable that the cooling means operates to blow air in a state where the pressing bush is in contact with the metal component at the time of press-fitting.

[0006]

Embodiments of the present invention will be described below with reference to the drawings. 1 to 10, reference numeral 1 denotes a heating press-fitting device for press-fitting a metal component P having a hollow hole opened at at least one end surface, such as a metal nut component, into a work made of a thermoplastic resin material. A magazine unit 10 for arranging and stocking a plurality of the metal parts P, a three-axis orthogonal coordinate type robot R (hereinafter simply referred to as a robot R) disposed adjacent to the magazine unit, and The apparatus includes a press-fit unit 20 attached to the robot R, a heating unit 50 for heating the metal component P, and a work holder 60 for holding a work at a predetermined position. Hereinafter, these components will be described in detail.

The magazine unit 10 has a magazine table 12 for holding a magazine 11 in which a plurality of metal parts P are arranged. The magazine table 12 is located at a magazine receiving position M adjacent to a magazine supply conveyor (not shown).
1 and a component take-out position M2 by the press-fit unit 20 are configured to be slidable, and a magazine receiving position M
In 1, the magazine 11 is exchanged with a magazine supply conveyor.

圧 Press-fit unit The press-fit unit 20 is a Z-axis movable portion R1 of the robot R.
The work tool 22 and the air cylinder 23 are rotatably arranged on a main frame 21 connected to the main frame 21. The work tool 22 includes a main frame 21.
A rotating frame 24 rotatably supported by a support shaft 21a, an air cylinder 25 disposed on the rotating frame 24, and a press-fit head 26 connected to a piston rod 25a of the air cylinder 25. The tip of the piston rod 23a of the air cylinder 23 is rotatably connected to the rotating frame 24. That is, the work tool 22 is
90 ° when the piston rod 23a extends.
The heating unit and the work holder are configured to rotate in a rotation area T adjacent to the heating unit and the work holder.

The press-fit head 26 includes a support table 27 connected to the tip of a piston rod 25a of the air cylinder 25, a centering device 28 connected to the support table 27, and a centering device 28.
Heat insulation block 29 attached to the
9 and an air injection nozzle 31 supported by the centering device 28
It is composed of

The centering device 28 is configured to support the heat insulating block 29 in a floating state, so that the heat insulating block 29 and the component holding unit 30 can move a little in a horizontal plane. The heat insulating block 29 is made of a heat insulating material 2 made of a material having a low thermal conductivity, such as a heat insulating ceramic.
9a is incorporated in the connection position of the component holding unit 30, so that heat conduction from the component holding unit 30 is minimized. Further, the air injection nozzle 31 is disposed near the lower end of a later-described reference member 34 toward the distal end, and is configured to inject air from the distal end in response to the operation of an air supply source (not shown). It is configured. In the embodiment of the present invention, the air supply source and the air injection nozzle 31 correspond to a cooling unit described in the claims.

Further, the component holding unit 30 has a pressing bush 3 whose upper part is covered with the heat insulating material 29a and which is integrally fixed to the heat insulating block 29 by a screw part 29b.
2 and a holding rod 3 inserted in the pressing bush 32.
3 and a sleeve-like reference member 34 externally inserted into the pressing bush 32.

The holding rod 33 has such a shape that it can enter the hollow hole of the metal part P, and is urged by the spring 35 housed in the pressing bush 32 so as to always protrude from the pressing bush 32. A storage groove 33a is formed in the holding rod 33, and a locking member 36 is rotatably supported in the storage groove 33a. The locking member 36 is configured such that the locking piece 36a at the tip is
The retaining piece 33 is urged by a spring 37 so as to always protrude from the vicinity of the distal end of the metal component 3, so that when the holding rod 33 is inserted into the hollow hole of the metal component P, the locking piece 36a is pressed against the hollow hole.

The reference member 34 is formed on a work grounding piece 34a, the tip of which slightly projects from a surface including the front end face of the pressing bush. The pressing bush 32 is constantly urged by a spring 38 so as to slightly protrude from the surface including the pressing bush 32. In addition, on the upper part of the reference member 34,
A detection piece 39 is integrally attached, and a displacement sensor 40 is attached to a side of the heat insulating block 29 facing the detection piece 39. The displacement sensor 40 is configured to be turned ON only when the distance between the detection surface and the upper surface of the detected piece 39 is within a preset proximity range.

Heating Unit The heating unit 50 has a heating system (not shown) built in a housing 51, and a heating coil 52 projecting from the housing 51 is connected to the heating system. The heating coil 52 is formed to have an inside diameter and a full length that can include a heated portion of the metal component P.
2, a high-frequency current is supplied from the heating system 51 to generate a magnetic flux, and the magnetic flux concentrates on the metal component P inserted into the heating coil 52, so that the magnetic component P
An eddy current is generated in the metal part P, and the metal part P is heated by the heat generated by the metal part P itself. Also,
A non-contact type temperature sensor 54 is arranged on the housing 51 via a bracket 53 with its detection surface facing the sky above the heating coil 52, and is taken out of the heating coil 52 by the temperature sensor 54. The configuration is such that the temperature of the metal component P can be detected.

The work holder 60 includes an index table 62 connected to a slide unit 61, a pedestal 63 disposed on the index table 62, and a pedestal 63.
And a work table 64 arranged on the upper side and configured to hold the work W.
The work table 64 is horizontally moved by the operation of (1), and the work table 64 is positioned at the work acquisition position W1 and the press-fitting work position W2 adjacent to the rotation area T, and the work table 64 is moved at the press-fitting work position by the operation of the index table 62. The work W is rotated on a horizontal plane, and the work W held on the work table 64 can be changed in direction and positioned.

When the metal component P is press-fitted into the work W using the heating press-fitting device 1, first, the magazine table 12 of the magazine unit 10 moves to the magazine receiving position M1, receives the magazine 11, and receives the component take-out position M2. Is positioned backward. At the same time, the work table 64 of the work holder 60 is moved to the work supply position W1 by the operation of the slide unit 61, receives and holds the work W, and is returned to the press-fitting work position W2. When the magazine 11 and the work W are set at predetermined positions in this way, the press-fitting unit 20 is subsequently operated by the operation of the robot R.
Moves to the magazine 11 and inserts the holding rod 33 of the component holding unit 30 into the hollow hole of the predetermined metal component P. As a result, the locking piece 36a of the locking member 36 is pressed into the inside of the metal component P.
Can be held.

Subsequently, the press-fit unit 20 moves to the heating unit 50 by the operation of the robot R, and the heating coil 52
Then, the metal part P is inserted together with the holding rod 33. At this time,
A high-frequency current is supplied to the heating coil 52 by the operation of the heating system, and the metal component P is heated to a corresponding temperature by an electromagnetic induction action. At this time, the component holding unit 30 is provided by the heat insulating material 29a of the heat insulating block 29.
Is suppressed as much as possible, so that the accuracy of the displacement sensor 40 can be prevented from deteriorating, and the thermal degradation of the robot R and each part of the press-fit unit 20 can be prevented.

The heating time of the metal part P in the heating unit 52 is controlled by a control unit (not shown). When the heating time elapses, the press-in unit 20 rises by the operation of the robot R to remove the metal part P. Take out from the heating coil 52. When the metal part P is removed from the heating coil 52, the temperature of the metal part P is measured by the temperature sensor 54. If the metal part P is not heated above a predetermined temperature, the metal part P is excluded,
The press-fit unit 20 returns to the magazine unit 10 again,
The above-described heating operation is repeated by another metal part P.

When the metal part P is heated to a predetermined temperature or higher, the press-fitting unit 20 moves to the work holder 60 by the operation of the robot R, and moves the metal part P to the work W as shown in FIG. It is positioned above a predetermined metal component press-fitting hole h. In this state, the cylinder 25 is operated to lower the press-fit head 26, and the metal part P is moved to the work W
To the hole h entrance. This allows the metal part P
Is pressed into the work W while melting the peripheral portion of the hole h of the work W. At this time, as shown in FIG. 9B, the holding rod 33 escapes into the pressing bush 32 due to the influence of the press-fitting resistance received by the metal component P, whereby the distal end surface of the pressing bush 32 contacts the metal component P.

Immediately before the upper end surface of the metal part P coincides with the surface of the work W due to the press-fitting, the reference member 34 is moved to the position shown in FIG.
As shown in (c), the work ground contact piece 34a abuts on the work surface and cannot be lowered. In response to this, the holding rod 33 and the pressing bush 32 continue to lower while compressing the spring 38. As shown in FIG. 9D, when the upper end surface of the metal component P coincides with the surface of the work W and the distal end surface of the pressing bush 32 is pressed against the surface of the work W, a pneumatic circuit (which controls the air cylinder 25) (Not shown), and in response to this, compressed air is injected from the air injection nozzle 31 for a certain period of time. Thereby, the periphery of the hole h of the work W melted by the heat of the metal component P is cooled and solidified. The air injected at this time also reaches the tip portion of the component holding unit 30, so that the tip portion of the pressing bush 32 whose temperature is slightly increased due to heat conduction from the metal component can be cooled.

When the leading end surface of the pressing bush 32 is not in contact with the surface of the work W due to lack of press input, deformation of the work W, etc., that is, the metal component P is not properly pressed into the work W and rises from the work W. In this case, a pressure change occurs in the above-described pneumatic circuit (not shown). In this case, an abnormality appears in the interval between the displacement sensor 40 and the detection target 39, and this abnormality is detected by the displacement sensor 40. Is detected by In response to this, the operation of the apparatus is temporarily stopped, and a warning lamp, a warning buzzer, or the like notifies the operator of the abnormality.

If the displacement sensor 40 does not detect any abnormality and the metal part P is properly press-fitted, the press-fit head 26
After the air injection from the air injection nozzle 31 is completed, the metal cylinder P is returned to the original position by the reciprocation of the air cylinder 25, and thereafter, the above operation is repeated to press-fit the metal component P into the remaining hole h of the work W. I will do it.

The work W is formed by casting,
When the actual hole position is shifted from the designed hole position, the center of the metal component P is shifted from the center of the hole h in the press-fitting stage. In such a case, when the metal component P is press-fitted, a deviation occurs in the amount of melting at the periphery of the hole h of the work W, so that the metal component P performs a centripetal operation.
At the same time, the component holding unit 30 and the like move on the horizontal plane by the action of the centering device 28, so that the displacement between the metal component P and the hole h can be corrected.

If the hole h of the work W is provided extending in the horizontal direction, the metal cylinder P is heated by the heating unit 50, and then the air cylinder 23 of the press-fit unit 20 is turned into a rod in the rotation area T. The operation tool 23a is operated to extend, and as shown in FIG. 10, the work tool 22 is rotated to a position where it comes into contact with the shock absorber 21b. Thereby, the posture of the press-fit head 26 is changed so that the axis of the holding rod 33 is oriented in the horizontal direction. In accordance with this, the work W is rotated and positioned by the operation of the index table 62 so that the formation surface of the hole h extending in the horizontal direction faces the rotation area T, whereby the work W extends in the horizontal direction. The metal component P can be press-fitted into the hole h provided.

In the above description, the heating unit for heating the metal component P itself by the electromagnetic induction effect by energizing the heating coil is shown. However, the heating unit heats the heating coil itself to a high temperature, and this heat causes It may be of a type that heats a metal part secondarily.

[0026]

According to the heating and press-fitting apparatus for metal parts of the present invention, since the work melted by the press-fitting of the metal parts is solidified by blowing the air with the air injection nozzle, the work can be rapidly performed. To shorten the work cycle time. Further, according to the present invention, the metal component is held at the tip of the holding rod of the component holding unit, inserted into a heating coil, heated, and then pressed into the work, and the work melted by the air is sprayed by the air injection nozzle. It can be solidified by injection. Therefore, it is not necessary to heat and keep the component holding unit in advance, and the heat of the component holding unit does not delay the solidification of the work. further,
The tip of the component holding unit can also be cooled by air injection by the air injection nozzle, which prevents heat accumulation in the component holding unit, and the work is melted by the contact of the pressing bush of the component holding unit even when press-fitting is repeated. There is an advantage that it can be prevented from being lost.

[Brief description of the drawings]

FIG. 1 is a partially cut-away enlarged front view of a press-fitting unit in a metal component heating press-fitting device according to the present invention.

FIG. 2 is a partially cutaway enlarged side view of a press-fitting unit in the metal component heating press-fitting device according to the present invention.

FIG. 3 is a plan view of a heating and press-fitting apparatus for metal parts according to the present invention.

FIG. 4 is a front view of the metal component heating press-fitting device according to the present invention.

FIG. 5 is an enlarged view of a magazine unit in the metal component heating press-in device according to the present invention, wherein (a) is a plan view,
(B) is a front view.

FIG. 6 is a partially cutaway enlarged sectional view of a component holding unit in the metal component heating press-in device according to the present invention.

FIG. 7 is an enlarged view of a heating unit in the metal component heating press-in device according to the present invention, wherein (a) is a plan view,
(B) is a front view.

FIG. 8 is an enlarged front view of a work holder in the metal component heating press-in device according to the present invention.

FIG. 9 is an operation explanatory view of the metal component heating press-in device according to the present invention.

FIG. 10 is an operation explanatory view of the metal component heating press-in device according to the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Heating press-in apparatus of metal parts 10 Magazine unit 11 Magazine 20 Press-in unit 22 Work tool 23 Air cylinder 24 Rotating frame 25 Air cylinder 26 Press-in head 30 Parts holding unit 31 Air injection nozzle 32 Pressing shaft 33 Holding shaft 34 Reference member 50 Heating Unit 52 Heating coil 60 Work holder 62 Index table 64 Work table R Robot W Work

Claims (3)

[Claims] 1. A metal part is heated to a temperature at which a work made of a thermoplastic resin material can be melted, and the heat of the metal part melts the press-fitting position of the work, thereby press-fitting the metal part into the work. A heating and press-fitting device for a metal component, comprising: cooling means for blowing air to solidify a work melted by the press-fitting of the metal component. 2. A heating and press-fitting device for a metal component for press-fitting a metal component having a hollow hole opened at least on one end surface into a work made of a thermoplastic resin material, wherein the metal component can be reciprocated by receiving a drive from a reciprocating drive source. A pressing bush is provided, and a holding rod that can be inserted into the hollow hole of the metal component is disposed in the pressing bush so as to always urge it to protrude toward the distal end, and the holding rod is held in the hollow hole of the metal component. A locking member is provided which extends in the hollow hole when the rod is inserted, and the locking member extends in the hollow hole of the metal component to hold the metal component at the tip of the holding rod. A heating unit capable of heating the metal part held by the heating unit is provided, and the metal part heated by the heating unit is configured to be pressed into the work. Heating the press-fitting apparatus of metal parts, characterized in that a cooling means for blowing air workpieces melted even become in the vicinity of the press-fitting position in order to solidify. 3. The apparatus according to claim 2, wherein the cooling means operates to blow air while the pressing bush is in contact with the metal component at the time of press-fitting.