JP4885723B2 - Harness manufacturing equipment - Google Patents

Description

【Technical field】
[0001]
The present invention relates to an apparatus for manufacturing a set of harnesses.
[Background]
[0002]
Many harnesses are used for electricity, electronic devices, home appliances, automobiles, and other devices using electricity. As for the harness, for example, a 1-1 type (see FIG. 10), a 1-N type (see FIG. 11), or a multi type having different wire lengths, a wire extending from one connector is connected to the other connector. It is classified into several types by changing the length of the wire by pressing (or crimping) to which position.
On the other hand, in order to press-contact (or pressure-bond) the wire to the connector, the end of the wire is sequentially driven into each pole of the connector using a stuffer (anvil or crimper during crimping). In this case, the raising / lowering speed of the stuffer is selected so as to break the shield as the skin of the wire but not cut the wire.
[0003]
[Patent Document 1]
Japanese Patent Publication No. 6-56787 [Patent Document 2]
Japanese Patent Publication No. 6-105564 [Disclosure of the Invention]
[Problems to be solved by the invention]
[0004]
For example, one set of 1-1 type harness, one set of 1-N type harness, and two sets of multi type harness are installed in a specific place of electrical and electronic equipment. Suppose that 10,000 units are produced.
The harness manufacturer produces 10,000 type 1-1 harnesses in one machine, 10,000 1-N harnesses in another machine, and 20,000 multi-type harnesses in another machine, totaling 40000 pieces. The harness is delivered to the assembly manufacturer at the end of every month.
[0005]
In the above-described conventional example, the harness manufacturer purchases production equipment according to the type of harness, stores the required number of harnesses according to the number of orders in the required parts warehouse, and then delivers the assembly to the manufacturer. Therefore, a large number of machines will be prepared for each connector manufacturer, and orders will be handled, resulting in large capital investment and high risk.
Prior to delivery, the harness manufacturer takes out the required number of harnesses from the harnesses stored in the parts warehouse and bundles them together to create a predetermined harness set, requiring a lot of parts storage space. .
[0006]
In the conventional example, since the speed of the stuffer for driving the wire into the connector is limited to a speed at which the stuffer does not break the wire, it is considered that the driving speed, that is, the wire harness manufacturing speed is limited.
[0007]
Therefore, an object of the present invention is to solve the problems of the prior art described above.
[Means for Solving the Problems]
[0008]
In order to solve the above-mentioned problems, the present invention enables a harness manufacturer to manufacture a harness of a type that conforms to an order from an assembly manufacturer with the necessary number of devices and deliver it immediately, thereby minimizing storage space. Adopt means.
In order to solve the above-described problems, the present invention provides an apparatus suitable for a cell system in which a necessary number of harness sets are manufactured by one apparatus and the harness sets can be delivered as much as necessary per day.
Furthermore, the present invention increases the speed of the stuffer, reduces the speed of the stuffer when driving the wire into the connector, and improves the work efficiency for the increased speed.
[0009]
[0010]
According to the present invention, a ram having a stuffer that presses a wire into each connector, a guide having a groove that is supported by the ram and extends in a horizontal direction, a supporter that reciprocally supports the ram, and a drive unit. a cam shaft is rotated, rolls arranged is in the groove in the guide and a cam which is supported eccentrically to the axis of the camshaft, reciprocating the ram by rotation about center axis of the camshaft And a press welding machine characterized in that the speed of the stuffer is reduced when the stuffer presses the wire into the connector.
[0011]
In addition, there is a ram having a stuffer that presses the wire into each connector, a cam follower supported by the ram, a supporter that supports the ram in a reciprocating manner, a camshaft that is rotated by a drive unit, and an annular groove. And a cam follower that is eccentrically fixed to the camshaft. A cam follower is arranged in the groove of the cam. The cam follower moves up and down by the rotation of the cam to reciprocate the ram, and the stuffer presses the wire into the connector. A press welding machine characterized in that the speed of the stuffer is sometimes reduced.
[0012]
【Effect of the invention】
[0013]
[0014]
As a feature of the present invention, the raising / lowering speed of the stuffer for driving the wire into the connector is variable, the driving speed is reduced to a speed that does not cause breakage of the wire, and the other lifting / lowering speed is increased to increase the working time. Can be shortened.
[0015]
[Brief description of the drawings]
[0016]
FIG. 1 is a plan view showing an example of a wire harness.
FIG. 2 is a plan view showing a connector juxtaposition system for the example shown in FIG. 1;
FIG. 3 is a perspective view showing a state in which a connector group is supplied to a press contact station.
FIG. 4 is a side view of an example of a pressure welding machine.
5 is a plan view of the pressure welding machine shown in FIG. 4. FIG.
FIG. 6 is a front view of another example of a pressure welding machine.
7 is a side view of the pressure welding machine shown in FIG. 6. FIG.
8 is a diagram showing the amount of movement of the blade (stuffer) in the example of FIG.
9 is a diagram showing the amount of movement of the blade (stuffer) in the example of FIG. 6;
FIG. 10 is a plan view of a 1-1 type harness.
FIG. 11 is a plan view of a 1-N type harness.
BEST MODE FOR CARRYING OUT THE INVENTION
[0017]
1 shows a connector group 1 in which 5 poles, 10 poles and 9 pole connectors are juxtaposed on the left side, and a wire having a connector group in which 4 pole connectors are juxtaposed on the right side and 3 poles, 5 poles and 8 pole connectors are juxtaposed. An example of the wire harness 3 which has the harness group 2 is shown.
An example of the juxtaposition of connectors in the example of the wire harness 3 shown in FIG. 1 is shown in FIG.
Nine tubes are arranged in parallel on the left side. The connectors of the poles exemplified in each tube are accommodated, and a plurality of connectors are fed out by a rod and cylinder extruder or the like. Each tube is multi-staged up and down, and when all the connectors in one tube are sent out, the empty tube is moved to another place, then the waiting tube moves to a predetermined position, Enable connector supply.
[0018]
An example of the connector group 1 will be described. First, the 9-pole connector 4 is sent out as operation A, and then the 10-pole connector 5 is sent out as operation B so as to be juxtaposed with the connector 4. The connectors 4 and 5 are moved to the front of the tube of the 5-pole connector 6 as operation C, and the connector 6 is juxtaposed with the connector 5 to form the connector group 1.
The connector group 2 sends out an 8-pole connector 7 as an operation A, moves the connector 7 to the front of the tube of the 5-pole connector 8, and further moves to the front of the 3-pole connector 9, so that the connectors 7, 8 , 9 are juxtaposed.
In operation D, these connectors 7, 8, 9 move to the front of the tube of the two-pole connector 10. Four two-pole connectors 10 are sent out from the tube to form a connector group 2.
[0019]
The selection number, arrangement, and order of connectors are made exactly according to the instructions of the programmed computer. The connector groups 1 and 2 are supplied along the rails 11 and 12 to the pressure welding machine side.
Each wire 13 is length-measured in advance and length-cut to a length necessary for each pole of each connector.
[0020]
An example of the pressure welding machine 14 is shown in FIGS. The pressure welding machine 14 is a reciprocating ram 16 having a stuffer 15 as a pressure welding blade, a guide 18 having a groove 17 supported by the ram 16 and extending in the horizontal direction, and a reciprocating movement of the ram 16 in the vertical direction. A supporter 19 supported by the supporter 19, an electric motor 20 as a driving part held by the supporter 19, a camshaft 22 coupled to the driving part 20 via a coupling 21, and a shape eccentric to the axis of the camshaft 22. And a cam 23 supported by the camshaft 22.
[0021]
The rotation of the camshaft 22 by the drive unit 20 causes the cam 23 to rotate about the axis of the camshaft 22. The cam 23 moves up and down the guide 18 and the ram 16 while rolling in the groove 17 of the guide 18. As a result, the stuffer 15 moves up and down, and the wire 13 is pressed (or pressure-bonded) to the connector 24 (any one of the connectors 4 to 10). Reference numeral 25 denotes a wire guide.
As shown in FIG. 8, the vertical movement speed of the stuffer 15 following the movement of the cam 23 is low at the top dead center and the bottom dead center, and the vertical movement speed is high in the middle. Since the start and completion of the pressure welding (or pressure bonding) is performed in the low speed region of the stuffer 15, the fine wire (core wire) in the wire 13 is not cut during the pressure welding (or pressure bonding). However, since the speed can be increased between the top dead center and the bottom dead center (or only the bottom dead center), the working time can be greatly reduced.
[0022]
Another example of a pressure welding machine is shown with reference to FIGS. Components similar to those shown in FIGS. 4 and 5 are denoted by the same reference numerals, and a part of the description is omitted.
The pressure welding machine 26 has a cam follower 27 fixed to the ram 16, and the cam follower 27 is rotated in an annular groove 29 of a cam 28 fixed to the camshaft 22 in a form eccentric to the axis of the camshaft 22. It is housed freely.
[0023]
The rotation of the camshaft 22 by the drive unit 20 rotates the cam 28 while being eccentric about the axis of the camshaft 22. The cam follower 27 moves up and down while rolling in the annular groove 29 of the cam 28 to raise and lower the ram 16. As a result, the stuffer 15 moves up and down, and the wire 13 is pressed (or pressure-bonded) to the connector 24 (any one of the connectors 4 to 10). Reference numeral 25 denotes a wire guide.
As shown in FIG. 9, the vertical movement speed of the stuffer 15 following the movement of the cam follower 27 is low at the top dead center and the bottom dead center, and the vertical movement speed is high in the middle.
Since the start and completion of the pressure welding (or pressure bonding) is performed in the low speed region of the stuffer 15, the fine wire (core wire) in the wire 13 is not cut during the pressure welding (or pressure bonding). However, since the speed can be increased between the top dead center and the bottom dead center, the working time can be greatly shortened. The same applies when a plurality of pressure welding and pressure bonding are performed simultaneously.
[0024]
As shown in FIG. 4, in this example, while the stuffer 15 is moved to the left and right, the wires 13 are pressed against (or crimped to) each pole of the connector one by one. The connector poles that require wire pressure contact (or pressure bonding) may be opposed to the stuffer 15.
The number of poles, the arrangement, and the number of uses of each connector constituting the connector groups 1 and 2 can be arbitrarily selected.
[0025]
In the illustrated example, the combination of the guide 18 and the cam 23 and the cam follower 27 and the cam 28 is used in order to limit the vertical movement speed of the stuffer during the pressure welding (or crimping) operation to a speed that does not break the thin wire of the wire. Using a lever that has a stuffer at one end and a link that follows the cam at the other end, and rotating the cam, the stuffer reciprocates around the fulcrum (vertical movement) via the link. The structure to obtain may be sufficient. By selecting the cam shape, the speed of the stuffer during the pressure welding (or pressure bonding) operation may be reduced, the speed in other processes may be increased, and the work time may be shortened.
[0026]
It should be noted that the term crimping is used in the claims, and this includes crimping.

Claims (3)

A ram having a stuffer that presses the wire into each connector, a guide having a groove that is supported by the ram and extending in the horizontal direction, a supporter that reciprocally supports the ram, and a camshaft that is rotated by a drive unit. , and a cam which is supported eccentrically within the groove disposed in the guide with respect to the axis of the rolling with the camshaft, and thereby reciprocate the ram by rotation about center axis of the camshaft stuffer is a wire A pressure welding machine characterized in that the speed of the stuffer is reduced when being pressed into the connector.   A ram having a stuffer that presses the wire into each connector, a cam follower supported by the ram, a supporter that reciprocally supports the ram, a camshaft that is rotated by a drive unit, an annular groove, and A cam follower that is eccentrically fixed to the camshaft, and a cam follower is arranged in the groove of the cam. The cam follower moves up and down by the rotation of the cam to reciprocate the ram, and the stuffer presses the wire into the connector. The pressure welding machine characterized by reducing the speed of the machine.   3. The pressure welding machine according to claim 1, wherein the speed of the stuffer has an optimum pressure welding speed at the start of pressure welding, and the number of rotations can be freely selected.

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