JP3389122B2 - Spark plug manufacturing method and apparatus - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a center electrode arranged in an insulator, a metal shell arranged outside the insulator, one end of which is coupled to an end face of the metal shell on the tip side. A spark plug (generally a parallel electrode) provided with a ground electrode whose other end is bent back to the side and a side surface faces the tip surface of the center electrode to form a spark gap with the tip surface of the center electrode. (Commonly called type spark plug)
Manufacturing method and manufacturing apparatus.

[0002]

2. Description of the Related Art In the parallel electrode type spark plug as described above, the formation of the spark gap and the adjustment of the gap are generally performed by bending the ground electrode. As a method for performing such bending, for example, there are the following methods. First of all, bend spacers (in the industry, "Makura") to face the tip surface of the center electrode of the spark plug to be processed.
Or it is also called "lower mold"). Then, the tip side of the ground electrode is pressed against the bending spacer from the side opposite to the center electrode using a bending punch (also referred to as “upper die”). Next, in the main bending step, the bending spacer is retracted from between the ground electrode and the center electrode, and the tip side of the ground electrode is fixed so that a final spark gap distance can be obtained between the ground electrode and the center electrode. Bend the required amount toward the tip of the center electrode.

[0003]

In carrying out the above-described bending process, conventionally, as shown in FIG. 21 (a), a bending spacer 42 is provided from the side of the center electrode W1 toward the ground electrode W2. It was arranged to move and position along the arrangement direction of. In this case, if sagging or the like occurs at the tip of the bending spacer 42, the spacer tip may interfere with the center electrode W1 and damage it. Further, when the spacer 42 is positioned, it is necessary to position the lower edge of the distal end of the spacer 42 below the distal end surface of the center electrode W1 because interference with the center electrode W1 occurs as shown in FIG. 21 (c). It is impossible. Therefore, as shown in FIG. 19 (b), the starting point K of the bent portion of the installed electrode W2 after bending is the center electrode W1.
There is no choice but to position it on the front side of the tip surface of the. In this case, the ground electrode W2 after the main bending has an angular shape as a whole, and the radius of curvature of the bent portion is considerably small. Therefore, when vibration is applied when the plug is used, stress is likely to be concentrated in the bent portion, and the electrode is broken. There is a drawback that the problem of (3) is likely to occur.

SUMMARY OF THE INVENTION An object of the present invention is to provide a spark plug manufacturing method and a manufacturing apparatus which can prevent the center electrode from being damaged when positioning the bending spacer and can impart a relatively large radius of curvature to the bent portion of the ground electrode. is there.

[0005]

In order to solve the above problems, the spark plug manufacturing method of the present invention is a method for manufacturing a parallel electrode type spark plug as described above, wherein the center electrode of the spark plug to be processed is The bending step is performed by arranging a bending spacer so as to face the tip surface, and bending the tip side of the ground electrode by pressing the bending spacer from the side opposite to the center electrode with a bending punch. In the lateral direction from the retracted position set laterally away from the arrangement direction of the center electrode and the ground electrode to the bend receiving position facing the tip end face of the center electrode and receiving the bending force of the bending punch at It is characterized in that it is moved to and positioned.

Further, in the spark plug manufacturing apparatus of the present invention, the bending spacer is arranged so as to face the front end surface of the center electrode of the spark plug to be processed, and the front end side of the ground electrode with respect to the bending spacer is formed by using a bending punch. Including a bending device for bending by pressing from the opposite side of the center electrode, the bending device, the bending spacer, from the retracted position set laterally away from the arrangement direction of the center electrode and the ground electrode, A bending spacer positioning mechanism for laterally moving and positioning to a bending receiving position facing the tip end surface of the center electrode, and a bending punch for driving the bending punch so as to press the ground electrode toward the bending spacer in that state. And a drive mechanism.

When attempting to move and position the bending spacer from the center electrode side along the above-mentioned arrangement direction, if the tip of the bending spacer is sagging, the tip of the spacer interferes with the center electrode and damages it. It is easy for problems such as wear. However, by laterally positioning the bending spacer as described above,
There is almost no fear of causing such interference.

Further, even if the above-mentioned movement is performed in a state where the facing surface of the bending spacer is considerably close to the tip end surface of the center electrode, interference is unlikely to occur between the spacer and the tip end portion of the center electrode.
In other words, the position of the outer surface of the bending spacer on the side where the ground electrode is pressed, that is, the bending mold surface can be brought closer to the base end side of the ground electrode as a whole. The bending mold surface has a curved surface shape corresponding to the bending shape of the ground electrode, and specifically, often includes a rounded surface portion for forming a rounded bent portion with respect to the ground electrode. . By bringing the position of the bending surface closer to the base end side of the ground electrode in this way, the radius start portion of the ground electrode can be moved closer to the base end of the electrode. As a result, it is easy to increase the radius of the bent portion of the ground electrode, and it is possible to prevent breakage or the like due to stress concentration even when vibration is applied when the plug is used. Further, if the radius is increased, the length of the entire ground electrode can be shortened. As a result, the effect of reducing the bending moment when vibration is applied and preventing breakage etc. is further enhanced. In addition,
In order to enhance the above effect, it is effective to form a rounded surface corresponding to the inner surface of the bent portion of the ground electrode at the tip of the bending die surface in the direction from the center electrode side to the ground electrode side.

Further, the bending spacer has a tip position of the bending die surface in the direction from the center electrode side to the ground electrode side,
The center electrode may be positioned so as to be located on the rear side of the front end surface of the center electrode in the axial direction. As a result, the radius start portion of the ground electrode can be moved further toward the electrode base end, and the above-described effect can be further enhanced.

In the above-described method (and apparatus) for manufacturing a spark plug of the present invention, the pre-bent spacer is arranged so as to face the tip end surface of the center electrode of the spark plug to be processed, and the pre-bent spacer is connected to the ground electrode. A pre-bending step of performing a pre-bending process by pressing the tip side from the side opposite to the center electrode using a bending punch, and retreating the pre-bending spacer from the ground electrode and the center electrode to the side, In this state, a main bending step is performed in which the tip side of the ground electrode is subjected to main bending so that a final spark gap distance is obtained between the ground electrode and the center electrode. be able to. In this case, in the pre-bending step, the pre-bending spacer receives the bending force of the bending punch from the retracted position set laterally away from the arrangement direction of the center electrode and the ground electrode, facing the tip end surface of the center electrode. It can be laterally moved and positioned to the bending receiving position.

[0011]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The embodiments of the present invention will be described below with reference to the examples shown in the drawings. 1 (a) and 1 (b) are a plan view and a side view conceptually showing one embodiment of a spark plug manufacturing apparatus (hereinafter, simply referred to as a manufacturing apparatus) of the present invention. The manufacturing apparatus 1 is a linear conveyor as a transport mechanism that intermittently transports a spark plug to be processed (hereinafter also referred to as a work) W along a transport path C (which is linear in this embodiment). 300 is provided, and each process execution part for forming the spark gap of the work W, that is, the work carry-in mechanism 11 as a spark plug carry-in mechanism to be processed, and the ground electrode of the work W are positioned at fixed positions along the transport path C. Ground electrode alignment mechanism 12, tip surface position measuring device 13 for measuring tip surface position of center electrode, bending device 14 for pre-bending the ground electrode, main bending device 15, and work W for discharging work W after processing. The discharging mechanism 16 is arranged in this order from the upstream side in the transport direction. In the linear conveyor 300, a carrier 302 to which a work W is detachably mounted is attached to a chain 301 as a circulating member at predetermined intervals. By intermittently cyclically driving the chain 301 by the conveyor drive motor 24, each carrier 302, that is, the work W is intermittently transported along the transport path C.

As shown in FIG. 2, the work W has a cylindrical metal shell W3, and an insulator W4 and an insulator W4 fitted inside the metal shell W3 so that the leading end and the rear end of the workpiece W project.
Is provided with a center electrode W1 inserted in the axial direction, and a ground electrode W2 having one end joined to the metal shell W3 by welding or the like and the other end extending in the axial direction of the center electrode W1.
The tip of the ground electrode W2 is bent toward the tip surface of the center electrode W1 in the following steps to form a spark gap, thereby forming a parallel electrode type spark plug. A cylindrical holder 23 having an open upper end is integrally attached to the upper surface of the carrier 302. The work W is removably inserted into the holder 23 from the rear end side, and the hexagonal portion W6 of the metal shell W3 is supported by the peripheral edge portion of the opening of the holder 23 so that the ground electrode W2 side faces up. It is conveyed together with the carrier 302 in the state of standing upright.

The linear conveyor 300 as described above is used.
By arranging each device along the transport direction of, the pre-bending device 14 is arranged at a second position horizontally separated from the first position with the arrangement position of the tip surface position measuring device 13 as the first position. It has become a shape. The linear conveyor 300 plays a role of a transfer mechanism that transfers the work W together with the holder 23 from the first position to the second position.

The work carrying-in mechanism 11 and the work discharging mechanism 16 of FIG. 1 are, for example, as shown in FIG. 2, a work supply unit or a work discharging unit set to the side of the linear conveyor 300 (FIG. 1) in the carrying direction C. It is configured as a transfer mechanism for transferring the work W between the holder 23 (provided at the position J in the drawing) and the holder 23 positioned in the carry-in or discharge mechanism. The transfer mechanism 35 includes a chuck hand mechanism 36 that is held by an air cylinder 37 so that it can be moved up and down, and an advance / retreat drive mechanism 39 that drives the chuck hand mechanism 36 forward / backward in the radial direction of the circumferential path C by an air cylinder 38 or the like. Composed of. The chuck hand mechanism 36 is adapted to be opened and closed by an air cylinder (not shown),
The work W is lowered by the air cylinder 37 to hold the work W, and then the work W is raised and then driven forward and backward by the air cylinder 38 to move to the transfer destination, and then descends again to release the hold of the work W and complete the transfer. Then, in the case of loading the work, the work W receives the work W, transfers it to the holder 23 of the linear conveyor 300, and mounts it on the holder 23. On the other hand, in the case of discharging a work, the work W is extracted from the holder 23, transferred to a work discharging unit (for example, a work collecting box, a shooter, etc.), and discharged.

Further, FIG. 3A shows a ground electrode alignment mechanism 4
The configuration example of is conceptually shown. The ground electrode alignment mechanism 4
Can be moved toward and away from the tip of the work (spark plug) W in the axial direction thereof, and is rotated at a predetermined angle (180 ° 180 in this embodiment) about the axis by the motor 151 or the like.
Rotating member 15 provided so as to be intermittently rotatable in units of °)
A groove 152 having a width and a depth corresponding to the ground electrode W1 of the work W is formed on the bottom surface of the rotating member 150. When the work W is carried into the ground electrode alignment mechanism 4, the rotating member 150 falls on the tip of the work W.
At this time, the direction of the groove 152 of the rotating member 150 is positioned so as to correspond to the aligned position. Since the position of the ground electrode W1 is indefinite when it is carried into the ground electrode alignment mechanism 4, even if the rotating member 150 is dropped, the groove 152 does not fit with the ground electrode W1 in many cases, and the rotation is reduced. The member 150 has a bottom surface on which the ground electrode W1 is mounted. Then, the motor 151 is activated to rotate the rotating member 15
0 rotates around the axis while sliding on the ground electrode W1 on the bottom surface. The ground electrode W1 has a groove 152 during its rotation.
After that, the work W is rotated together with the rotating member 150. Then, the rotating member 150 stops rotating when it has just rotated once from the initial position. As a result, the ground electrode W1 is positioned at the predetermined alignment position. The drive unit of the rotating member 150 may be a rotary actuator that uses air or hydraulic pressure.

Next, the tip end surface position measuring device 13 is for measuring the tip end surface position of the center electrode W1 prior to bending, which will be described later, and is provided with a position detecting sensor 115 as shown in FIG. Work W is linear conveyor 300
For the holder 23 that is mounted on the and fixed in the height position,
The ground electrode W2 is mounted in an upright position so that it is on the upper side. Then, the position detection sensor 115 is held at a constant height by the frame 40 for measuring the height position of the tip end surface, and thereby measures the tip end surface position of the center electrode W2 with respect to the loaded work W from above. . As such a position detecting sensor, various non-contact type sensors such as an optical type and an ultrasonic type can be adopted, but in the present embodiment, a known laser displacement sensor is used. The operation outline is as follows. That is, laser light is emitted from the laser light source 115a toward the tip surface of the center electrode W2 at a constant angle, and the reflected light is emitted from a semiconductor position detector (Position).
Sensitive Detector: PSD) 115b. The light receiving position of the reflected light changes depending on the height position of the reflecting surface, and the detection output of the PSD 115b becomes information reflecting the light receiving position of the reflected light, that is, the height position of the reflecting surface. By reading this, the position of the tip surface of the center electrode W2 can be known.

FIG. 12 is a block diagram of the analysis unit 110 of the tip surface position measuring device 13. The analysis unit 110
O port 111 and CPU 112, RO connected to it
It is composed of a microprocessor including M113 and RAM 114, and the ROM 113 stores a position analysis program. RAM114 is CPU1
Functions as 12 work areas. Further, the position detection sensor 115 is connected to the I / O port 111 via an A / D converter 116. P of the sensor 115
The detection output of SD115b (FIG. 4) is the A / D converter 11
6 digitally converted and input to the analysis unit 110. CP
The U 112 receives this and converts it into height information of the tip surface of the center electrode by an analysis program, and outputs this as height measurement data from the I / O port 111.

FIG. 5 shows an example of the pre-bending device 14. As shown in FIG. 8, the pre-bending device 14 arranges the pre-bending spacer 42 so as to face the tip surface of the center electrode W1 of the work W, and the tip side of the ground electrode W2 with respect to the pre-bending spacer 42 is The pre-bending process is performed by pressing the pre-bending punch 43 from the side opposite to the center electrode W1. In FIG. 5, the pre-bending device 14 includes a pre-bending spacer positioning mechanism 45,
The bending mechanism 46 is provided. As shown in FIG. 8, the pre-bending spacer positioning mechanism 45 has a predetermined gap d between the pre-bending spacer 42 and the tip surface of the center electrode W1.
It is for positioning so as to cause Also,
The bending mechanism unit 46 presses the ground electrode W2 toward the pre-bending spacer 42 in this state so that the bending punch 43 is pressed.
Is for driving.

Returning to FIG. 5, the pre-bending spacer positioning mechanism 45 includes a forward / backward drive mechanism 47 and a spacer position adjusting drive unit 4.
8 and. As shown in FIG. 8B, the advancing / retreating drive mechanism 47 causes the preliminary bending spacer 42 to cross the bending receiving position PA1 facing the tip end surface of the center electrode W1 of the workpiece W and the axial direction of the center electrode W1. At the retracted position PA2 which is out of the bending receiving position. Further, the spacer position adjustment drive unit 48 is
By moving the pre-bending spacer 42 in the axial direction of the center electrode W1 (in this case, in the vertical direction), the center electrode W1
This is for adjusting the distance between the tip surface of the and the pre-bending spacer 42 to the predetermined distance d.

The bending punch 43 constitutes a bending mechanism portion 46 together with an air cylinder 49 as a punch driving portion, and is used for bending the ground electrode W2 in the axial direction of the center electrode W1 (in this case, the vertical direction). Driven toward and away from each other. The bending mechanism 46 is integrally attached to the plate-shaped movable base 52 together with the preliminary bending spacer 42. The spacer position adjustment drive unit 48 moves the movable base 52 in the axial direction of the center electrode W1. In this way, the bending punch 43 and the pre-bending spacer 4 are
By integrally positioning 2 and 2 with respect to the work W, even if the position of the tip surface of the center electrode W1 changes, the pre-bending spacer 42 and the bending punch 43 can always be positioned at optimal bending positions. it can.

The specific structure of the pre-bending device 14 will be described in more detail below. The work W is carried into the apparatus 14 by the linear conveyor 300 and positioned at a predetermined processing position. Further, it has two struts 51, 51 standing upright at a predetermined interval on both sides of the linear conveyor 300 in the conveying direction, and a support plate 55 is attached to the upper ends of the struts 51, 51 to attach a support frame 55 to the machine frame 60 of the apparatus. Is formed.

As shown in FIG. 7, in the movable base 52, the column guide portions 70, 70 in which the insertion holes 70a, 70a are formed in the vertical direction are attached to the back side by bolts or the like, and the column inserted therein. It is adapted to move up and down along 51, 51. In addition, the spacer position adjustment drive unit 4
8 is configured as follows. That is, the screw shaft 72 is screwed into the female screw member 71 attached to the back surface side of the movable base 52 in the ascending / descending direction of the movable base 52, and the spacer height adjusting motor 73 attached to the support plate 55 attaches both screw shafts 72. Drive in the direction of rotation. As a result, the movable base 52 moves up and down, and the preliminary bending spacer 42 and the bending mechanism portion 46 attached to the movable base 52 move up and down integrally.

Next, the advancing / retreating drive mechanism 47 includes a slider 74 to which the pre-bending spacer 42 is attached, which is attached to the movable base 52 described above. Specifically, as shown in FIG. 5, a horizontal guide 75 is provided along the lower edge of the movable base 52, and the slider 74 slides along the guide 75, whereby the pre-bending spacer 42 is moved. It is adapted to reciprocate between the bending receiving position PA1 and the retracted position PA2 shown in FIG. 8 (b).

The advancing / retreating mechanism may be constituted by, for example, an air cylinder or the like, but in the present embodiment, the advancing / retreating mechanism by the cam 80 described below is adopted. That is, as shown in FIG. 9, the drive arm 63 is rotatably attached to the lower frame 61 provided at the lower portion of the machine frame 60 (FIG. 5) by the pin 62 at the intermediate portion thereof. A roller 63a is attached to one end side of the drive arm 63 and faces a receiving plate 77 as a drive receiving portion provided on the slider 74 to face the receiving plate 77 to form a driving portion.
A roller 63b is attached to the other end side and contacts the sliding surface of the cam 80 to form a cam follower portion. In addition,
As shown in FIG. 5, the cam 80 is attached to the shaft 81, and is rotationally driven by the cam drive motor 78.

Returning to FIG. 9, one end of the guide rods 82, 82 is attached to the rear end surface of the slider 74 in the advancing / retreating direction so that the slider 74 slides integrally with the slider 74. The other ends of the guide rods 82, 82 extend further rearward through a receiving plate 83 as a stopper receiving portion attached to the movable base 52,
A stopper fixing portion 84 is provided at the end portion thereof.
In this embodiment, two guide rods 82, 82 are provided on the upper and lower sides, and the stopper fixing portion 84 is formed in a plate shape that connects these end portions. Then, the stopper fixing portion 84 is brought into contact with the receiving plate 83, so that the forward position limit of the slider 74 (in this case, corresponding to the bending receiving position PA1 of the preliminary bending spacer 42 (FIG. 8B)). A defining stopper 85 is attached.

In the present embodiment, the stopper 85 has a stopper fixing portion 8 whose tip portion projects toward the receiving plate 83.
It is configured by a male screw member that is screwed into the No. 4.
The amount of protrusion of the stopper 85 from the stopper fixing portion 84 can be changed according to the amount of screwing in. For example, when the work W is changed to an order having a different specification, the bending receiving position of the preliminary bending spacer 42. If it is necessary to change the
The forward position limit of can be changed appropriately. Reference numeral 86 is a lock nut for preventing the stopper 85 from loosening.

Next, between the slider 74 and the receiving plate 83, spring members 76, 76 for urging the slider 74 in either one of its advancing and retracting directions (hereinafter referred to as the forward direction) are provided. It is provided. The movement of the slider 74 in the forward direction uses the urging force of the spring members 76, 76 as a driving force, while the movement of the slider 74 in the opposite direction uses the urging force of the spring members 76, 76 by the drive arm 63 as described later. The resisting pressing force is used as the driving force. In this embodiment, the spring members 75, 75 are arranged in a compressed state between the slider 74 and the receiving plate 83 (in this embodiment, the guide rods 82, 82 are inserted inside the spring members 76, 76). The slider 74 is urged in its forward direction (direction toward the bending receiving position).

The operation of the advancing / retreating drive mechanism 47 is as follows. That is, as shown in FIG.
In the rotation angle section φ1, the cam follower portion 63b of the drive arm 63 retracts and the drive portion 63a advances. As a result, the slider 74 advances due to the urging force of the spring members 76, 76, and moves and positions the preliminary bending spacer 42 to the bending receiving position. On the other hand, in the rotation angle section φ2 of the cam 80, on the contrary, the cam follower portion 63b of the drive arm 63 is reversed.
Moves forward and the drive unit 63a moves backward. As a result, the slider 74 retreats against the biasing force of the spring members 76, 76 and moves the pre-bending spacer 42 to the retracted position.

Returning to FIG. 5, the bending mechanism portion 46 is attached to the movable base 52 at a position corresponding to the bending receiving position PA1 (FIG. 8B) of the pre-bending spacer 42, and the bending punch is performed by the air cylinder 49. 43 for work W
The ground electrode W2 is bent by approaching and separating from above. During the bending process, the work W is sandwiched and fixed between the pressing members 95 and 96 from both sides in the axial direction, as shown in FIG. In the present embodiment, the movable pressing member 96 is provided so as to be movable back and forth in the same direction as the slider 74 with respect to the fixed pressing member 85. Specifically, the movable pressing member 86
Is mounted on a slider 89, and is driven forward and backward by a cam 88 coaxially mounted on the shaft 81 with the cam 80 in conjunction with a slider 74 via a drive arm 87. Since the mechanism is almost the same as the forward / backward drive mechanism 47 of the slider 74, detailed description thereof will be omitted.

Next, as shown in FIG. 8B, the retracting position PA2 of the pre-bending spacer 42 in the bending mechanism 46 is set.
Is set laterally away from the arrangement direction Q of the center electrode W1 and the ground electrode W2 shown in FIG. 7A, and the pre-bending spacer positioning mechanism 45 (advancing / retreating drive mechanism 47) is set to the pre-bending spacer 42. Is moved laterally from the retracted position PA2 to the bending receiving position PA1 for positioning. The work W is aligned by the ground electrode alignment mechanism 12 (FIG. 1) so that the ground electrode W2 is located on the opposite side of the pre-bend spacer 42 with the center electrode W1 interposed therebetween in the advance / retreat direction of the pre-bend spacer 42. And is positioned in the pre-bending device 14.

Further, as shown in FIG. 8A, in the pre-bending spacer 42, the outer surface (the upper surface in this case) on the side on which the ground electrode W2 is pressed has a curved shape corresponding to the bent shape of the ground electrode W2. The bending mold surface 42a is provided. Specifically, in the direction from the center electrode W1 toward the ground electrode W2 side, the tip portion 42a2 of the bending die surface 42a is
It is formed in a rounded surface shape corresponding to the inner surface of the bent portion of the ground electrode W2. Here, a flat surface facing the center electrode W1 of the pre-bending spacer 42 is used as a reference surface 42c, and a projecting portion 42 projecting downward from the reference surface 42c at the tip portion.
b is formed so that the rounded tip 42a2 extends to the lower edge of the protrusion 42a.
The rear side of the bending surface 42a is an inclined surface 42a2 that is further away from the tip surface of the center electrode W1 toward the rear.

On the other hand, the contact surface of the bending punch 43 with the ground electrode W2 is also a bending die surface 43a having a curved shape corresponding to the bent shape of the ground electrode W2. The bending surface 43
The portion of a corresponding to the sloped surface 42a2 of the pre-bending spacer 42 is a sloped surface 43a1 having substantially the same slope as this, while the portion corresponding to the tip end portion 42a2 of the spacer 42 bends the tip end portion of the ground electrode W2. The guide slope 43a2 is steeper than the slope 43a1 for guiding.

In the bending mechanism portion 46, the ground electrode W2 of the work W has the bending punch 43 and the pre-bending spacer 42.
The pre-bending spacer 42 by
Is sandwiched between the inclined surfaces 42a and 43a2 of the bending punch 43, and the tip end faces obliquely upward, and the shape of the bent portion becomes a rounded surface shape corresponding to the shape of the tip end portion 42a2 of the bending die surface 42a. It will be pre-bent as described above.

FIG. 13 shows the controller 12 of the pre-bending device 14.
FIG. 3 is a block diagram showing an electrical configuration example of 0. Control unit 12
The main part of 0 is the I / O port 121 and the C connected to it.
It is composed of a microprocessor 125 including a PU 122, a ROM 123, a RAM 124, etc.
A control program 123a is stored in M123. The RAM 124 functions as a work area for the CPU 122. The spacer height adjusting motor 73 is connected to the I / O port 121 via the servo drive unit 126, and is connected to a pulse generator (PG) 129. On the other hand, the cam drive motor 78 is also PG13 similarly.
0, and is connected to the I / O port 121 via the servo drive unit 127.

The work W in which the ground electrode W1 is pre-bent is carried to the main bending device 15 by the linear conveyor 300 in FIG. The main bending device 15 is shown in FIG.
As shown in (a), the work W positioned in the device
The grounding electrode W2 is provided with a main bending punch 90 provided so as to be able to approach and separate from above by a driving unit (not shown) such as a screw shaft mechanism. Then, as shown in FIG. 2B, the grounding electrode W2 preliminarily bent with its tip facing obliquely upward by the main bending punch 90 makes the tip end substantially parallel to the tip end surface of the center electrode W1. The main bending process is performed. It should be noted that it is desirable that this main bending process is performed stepwise while monitoring the gap interval with the CCD camera 92 or the like, so that the spark discharge gap g having a desired size is formed.

An example of the operation sequence of the adjusting device 1 will be described below. FIG. 11 is a block diagram showing the electrical configuration of the main control unit 100 of the spark plug manufacturing apparatus 1 and its surroundings. The main controller 100 has an I / O port 101
And the CPU 102, ROM 103 and R connected to this
The ROM 103 is composed of a microprocessor such as an AM 104, and the main control program 103a is stored in the ROM 103.
Is stored. And, in the I / O port 101,
The drive unit 2c of the linear conveyor 300 (FIG. 1) is connected. The drive unit 2c includes a servo drive unit 2a,
A conveyor drive motor 24 connected to this and a pulse generator 2 for detecting the rotational angle position of the motor 24
b and the like. Also, I / O port 10
Reference numeral 1 denotes an implementation part of each process of manufacturing the spark plug, that is, a work loading mechanism 11, a ground electrode alignment mechanism 12, a tip end surface position measuring device 13, a preliminary bending device 14, and a main bending device 15.
And the work discharge mechanism 16 is connected. RA
M104 functions as a work area 104a of the CPU 102, and is also used as a memory for storing the measurement result of the center electrode tip surface position, a storage area for a control flag, and the like.

The operation of the manufacturing apparatus 1 will be described below. First, FIG. 14 is a flow of the drive processing program MP1 of the linear conveyor 300 by the main control unit 100 of FIG. In the step of M101, the activation signal is transmitted to the execution units 11 to 16 of each process of FIG. In response to this, the control programs are simultaneously activated on each process execution unit side (for example, the analysis unit 110 and the control unit 120 in FIGS. 12 and 13). Each of these control programs returns a completion signal to the program MP1 each time the processing is completed. On the other hand, on the program MP1 side, each time these completion signals are received, the process end flag (see FIG.
1 (formed in the RAM 104) is turned on (M102 to M113). Then, when all the flags are turned on in M115, the linear conveyor 300 (FIG. 1) is driven by a fixed distance required for the work W to move to the next process position, and the flags are reset. Thereafter, the process returns to M101 and the same processing is repeated.

In response to the start signal, the control program on each process execution section side is executed in parallel for the plurality of works W held at each process execution position (FIG. 1). Less than,
In order to facilitate understanding, the flow of processing of each program will be described according to the process execution order when one work W is focused. First, in the process of loading the work W by the work loading mechanism 11, the presence or absence of the work W to be loaded is confirmed by a sensor or the like not shown, and if the work W is present, the work loading mechanism 3 of FIG. As a result, the new work W is mounted on the work holding portion 23 (FIG. 2). When the operation is completed, a completion signal is transmitted. The loaded work W is carried to the ground electrode alignment mechanism 4 of FIG. 1, and the ground electrode W2 alignment process described above with reference to FIG. 3 is performed. Then, it is carried to the next position, and the tip surface position measuring device 13 executes the step of measuring the tip surface position of the center electrode W1. FIG.
As shown in (a), the position of the tip surface is measured by the laser displacement sensor 115 in the form of a height position h viewed from a predetermined reference position X0. The data of the measured tip surface position is transmitted to the main controller 100 (FIG. 11).

The position of the measured tip surface is measured by the pre-bending device 14
(FIG. 1). In response to this, the pre-bending device 14 carries out the pre-bending step according to the flow shown in the flowchart of FIG. First, when the activation signal is received in S1, S
2, the tip position of the center electrode W1 from the main controller 100 in S3, and the reference position set in the pre-bending spacer 42, for example, the position of the lower reference surface 42c (FIG. 8) and the tip of the center electrode W. The data of the gap amount d to be set with respect to the surface is received. The control unit 120 (FIG. 13) of the preliminary bending device 14 calculates the bending receiving position of the spacer as h + d based on this h and d. That is, the control unit 120 functions as a bend receiving position calculating unit that calculates the bend receiving position of the preliminary bending spacer 42 based on the information on the measured tip surface position. The process of calculating the bending receiving position h + d is performed by the analyzing unit 110 of the tip surface position measuring device 13,
Alternatively, the calculation may be performed by the main control unit 100 and the calculation result may be transferred to the preliminary bending device 14. in this case,
The analyzing unit 110 or the main control unit 100 functions as a bending receiving position calculating unit.

Next, in S6, the pre-bending spacer 4
Adjust the height position of 2 to the above h + d. That is, FIG.
At 3, the value of h + d is sent to the servo drive unit 126. The servo drive unit 126 has a PG129
While referring to the current position of the spacer 42 detected by, the motor 73 (see also FIG. 5) is rotated in the forward direction or the reverse direction until it reaches h + d to position the pre-bending spacer 42. As shown in FIG. 16 (a), the position of the tip surface of the center electrode W1 has a different value for each work W depending on, for example, the length of the center electrode W1 or the dimensional variations of the metal shell W3 and the insulator W4. By positioning the pre-bending spacer 42 as described above, as shown in FIG. 16B, a substantially constant gap d is formed between the pre-bending spacer 42 and the spacer 42 regardless of the position of the tip surface. (However,
At this time, the spacer 42 is in the retracted position PA2 shown in FIG. 8B).

Returning to FIG. 15, when the positioning of the pre-bending spacer 42 is completed, the driving of the cam 80 of FIG. 9 is started,
As shown in FIG. 8B, the spacer 42 at the retracted position PA2 is moved to the bending receiving position PA1. here,
In FIG. 13, by transmitting a rotation start signal to the servo drive unit 127, the servo drive unit 12
7 rotates the cam drive motor 78 at a substantially constant speed.
In this case, as shown in FIG. 9A, the spacer 42 is positioned at the bending receiving position in the angular section φ1 of the cam 80. At this time, the control unit 120 of FIG. 13 starts receiving the pulse signal from the PG 130 (FIG. 15:
S7), for example, if the angular position of the cam 80 is the angle section φ1
The execution timing of the bending process is confirmed based on whether or not the predetermined position has been reached. Then, when the timing comes in S8 of FIG. 15, the air cylinder 49
(FIG. 5) is operated to carry out a pre-bending step as shown in FIG. 16 (c).

In the pre-bending step, the pre-bending spacer 42, as shown in FIG. 8B, has the retracted position PA2 which is laterally displaced from the arrangement direction of the center electrode W1 and the ground electrode W2.
To the bending receiving position PA1 by lateral movement. As a result, even if sagging occurs at the tip of the pre-bending spacer 42, there is almost no risk of interference with the center electrode W1. In this case, the position of the bending die surface 42a can be brought closer to the base end side of the ground electrode W2 as a whole. The bending die surface 42a has a curved shape corresponding to the bending shape of the ground electrode W2,
Specifically, the tip portion 42a2 has a rounded surface shape to form a bent portion with respect to the ground electrode W2. By making the position of the bending surface 42a close to the base end side of the ground electrode W2, the radius start portion of the ground electrode W2 can be moved toward the electrode base end. As a result, it becomes easy to increase the radius of the bent portion of the ground electrode W2, and the overall length of the ground electrode W2 can be shortened.

By positioning the pre-bending spacer 42 at the bending receiving position by the lateral movement as described above, as shown in FIG. 17A, the tip position of the bending die surface 42a in the axial direction of the center electrode W1. Can be positioned so as to be located on the rear side of the front end surface of the center electrode W1. As shown in FIG. 21A, the spacer 42
21 is moved to the electrode in the arrangement direction and positioned at the bending receiving position, interference with the center electrode W1 occurs as shown in FIG.
As shown in FIG. 18B (or FIG. 18B), the radius of curvature of the bent portion of the ground electrode W2 after the pre-bending is also considerably reduced. However, in the method of the present invention, FIG.
As shown in (a), the starting point K of the bent portion can be located rearward of the tip surface of the center electrode W1. As a result, as shown in FIG. 18C, the radius of curvature of the bent portion of the ground electrode W2 can be further increased,
The overall length of the ground electrode W2 can be further shortened.

Further, in the pre-bending step of the above-mentioned embodiment, the spacer 42 is not brought into contact with the center electrode W1, so that there is an advantage that the electrode is hardly scratched. Here, the height position of the pre-bending spacer 42 for receiving the bending changes according to the position of the tip surface of the center electrode W1, and the stroke length of the bending punch 43 for pressing the bending also changes correspondingly. It will be. However, in this embodiment, it is the air cylinder 49 of FIG. 5 that drives the bending punch 43, and by setting the driving pressure thereof to be substantially constant, it is possible to apply a constant bending force regardless of the stroke length. The pressure can be applied to the ground electrode W2.

If there is not much concern about scratches or the like, as shown in FIG. 19, the spacer 42 is positioned in a state of being slightly floated from the tip end surface of the center electrode W1,
Next, the spacer 42 is attached to the center electrode W by an air cylinder or the like.
By bringing them closer to the first side, they can be positioned so that they abut each other. In this case, spacer 4
The height position of 2 does not need to be controlled so precisely as compared with the case where a gap is formed between the spacer 42 and the tip surface of the center electrode W1. As a result, an air cylinder mechanism having a simpler structure can be adopted in place of the spacer position adjusting drive unit 48 using a screw shaft, and
The tip surface position measuring device 13 can also be omitted.

When the pre-bending step is completed, the work W in FIG. 1 is transferred to the main bending apparatus 15, and the main bending step shown in FIG. 10 is performed to set the spark gap amount to a final value.
Then, the work W is further conveyed to the work discharge mechanism 16, and the work W
Collect. In addition, in this main bending step, FIG.
As shown in FIG. 5, a knife-shaped spacer 95 that regulates the spark gap amount is sandwiched between the tip surface of the center electrode W1 and the tip portion of the ground electrode W2 to bend the ground electrode W2. Good.

[Brief description of drawings]

FIG. 1 is a plan view and a side view schematically showing an embodiment of a spark plug manufacturing apparatus of the present invention.

FIG. 2 is an explanatory view of a transfer mechanism.

FIG. 3 is a conceptual diagram showing a ground electrode alignment mechanism together with its action.

FIG. 4 is a front view showing an example of a tip surface position measuring device.

FIG. 5 is a front view showing an example of a preliminary bending device.

FIG. 6 is an explanatory view of the action of the pressing member.

FIG. 7 is an operation explanatory view of a preliminary bending spacer positioning mechanism of the preliminary bending device.

FIG. 8 is an explanatory view of the action of a pre-bending spacer.

FIG. 9 is an operation explanatory view of a forward / backward drive mechanism of the preliminary bending spacer.

FIG. 10 is a conceptual diagram of the bending device.

FIG. 11 is a block diagram showing an electrical configuration of a main control unit.

FIG. 12 is a block diagram showing an electrical configuration of a tip surface position measuring device.

FIG. 13 is a block diagram showing an electrical configuration of a pre-bending device.

FIG. 14 is a flowchart showing the flow of linear conveyor drive processing of the main control unit.

FIG. 15 is a flowchart showing a processing flow of a preliminary bending step.

FIG. 16 is an explanatory diagram of a preliminary bending step.

FIG. 17 is a schematic view showing a first modified example of the pre-bending spacer together with its action.

FIG. 18 is a diagram for explaining the effect of the method of the present invention on the bent shape of the ground electrode in comparison with the conventional example.

FIG. 19 is a view showing a modified example of the preliminary bending step.

FIG. 20 shows a modification of the main bending process.

FIG. 21 is an explanatory diagram of a conventional pre-bending step.

[Explanation of symbols]

1 Spark plug manufacturing equipment C transport route W work (spark plug to be processed) W1 center electrode W2 ground electrode W3 metal shell g Spark Gap 14 Pre-bending device 15 bending device 42 Pre-bending spacer 42a Bending surface 43 Bending punch 45 Pre-bending spacer positioning mechanism 46 Bending mechanism 300 Linear conveyor (transport mechanism)

Claims (6)

(57) [Claims] 1. A center electrode disposed in an insulator, a metal shell disposed outside the insulator, one end coupled to a tip end surface of the metal shell, and the other end laterally. A spark plug manufacturing method, comprising: a ground electrode that is bent back to form a spark discharge gap between the side surface and a front end surface of the center electrode, the side surface facing the front end surface of the center electrode. A bending spacer is arranged so as to face the tip surface of the center electrode of the spark plug, and the tip side of the ground electrode is bent by pressing the bending spacer from the side opposite to the center electrode with a bending punch. In the bending step, the bending spacer is paired with the tip end surface of the center electrode from a retracted position set laterally away from the arrangement direction of the center electrode and the ground electrode. Method for manufacturing a spark plug to the bending force the catch bending receiving position by bending punch is moved laterally, characterized in that so as to positioning. 2. The bending spacer has an outer surface on the side on which the ground electrode is pressed, which is a bending die surface having a curved shape corresponding to the bending shape of the ground electrode, and the ground electrode from the center electrode side. 2. The method of manufacturing a spark plug according to claim 1, wherein a tip end portion of the bending die surface in the direction toward the side is formed into a rounded surface shape corresponding to the inner surface of the bending portion of the ground electrode. 3. In the bending step, the bending spacer is positioned such that the tip end position of the bending die surface is located rearward of the tip end surface of the center electrode in the axial direction of the center electrode. The method for manufacturing a spark plug according to claim 2, wherein 4. A bending spacer is arranged so as to face the tip end surface of the center electrode of the spark plug to be processed, and the tip side of the ground electrode is opposite to the center electrode with respect to the bending spacer using a bending punch. The bending device includes a bending device that bends by pressing the center electrode from a retracted position that is laterally offset from the arrangement direction of the center electrode and the ground electrode. A bending spacer positioning mechanism for laterally moving and positioning the bending spacer to a bending receiving position opposed to the tip end surface of the bending punch, and a bending punch for driving the bending punch to press the ground electrode toward the bending spacer in that state. A spark plug manufacturing apparatus comprising a drive mechanism. 5. The bending spacer has an outer surface on a side on which the ground electrode is pressed, which is a bending die surface having a curved shape corresponding to the bending shape of the ground electrode, and the ground electrode from the center electrode side. 5. The spark plug manufacturing apparatus according to claim 4, wherein a tip portion of the bending die surface in the direction toward the side is formed into a rounded surface shape corresponding to the inner surface of the bending portion of the ground electrode. 6. The bending spacer positioning mechanism is configured such that the bending spacer has a tip position of the bending die surface located rearward of a tip surface of the center electrode in an axial direction of the center electrode. The spark plug manufacturing apparatus according to claim 5, wherein the spark plug is positioned.