DE1266248B - Tool for driving in an electrical connector pin - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. CL:

B25b

German AI .: 87 a-22

Number: 1 266 248

File number: A 316591 c / 87 a

Filing date: March 23, 1959

Open date: April 11, 1968

There is a tool for driving a plug pin into a plug hole has become known, the one Has tubular housing part in which a firing pin actuated by a spring is displaceable. The firing pin has at its front end a lateral recess for receiving the connector pin on. The plug pin inserted into the front end of the firing pin is inserted into its plug hole, and then pressure is applied to the tubular housing handle, and thereby the Firing pin pushed into the housing handle and the spring of a hammer provided in the handle tense. When the handle is withdrawn, the hammer is released so that it hits the firing pin and exercises the inserted connector pin.

The known tool also allows an inserted plug to be removed from its plug hole pull out.

The tool according to the invention not only has the task of driving a connector pin into a contact hole, but the tool should also serve as a test device and allow a check to be made as to whether the The driven pin is seated firmly enough in the contact hole. For this purpose is on the tool a holding device is provided for the connector pin, which separates the connector pin from the tool only allowed if a tensile force of a predetermined strength is applied to the plugged-in connector is exercised.

A tool for driving an electrical connector pin or the like into a connector hole with a in a tubular housing part displaceably mounted firing pin, which at its front end a lateral recess for receiving the connector pin and forward with a predetermined force is drivable, is characterized according to the invention in that the plug pin in the recess of the The firing pin can be locked by a retaining rail partially covering the recess and that spring-loaded locking means are provided between the firing pin and the retaining rail, which exerted on the connector pin when a certain level was reached by pulling back the tool Tensile test force the firing pin against the retaining rail and thus the connector pin out of the recess release.

A preferred embodiment of the invention provides that the front part of the firing pin is a Has a longitudinal groove which the holding rail attached to a front housing part of the tool is engaged in Can engage the state of the locking means in the recess.

Driving tool
an electrical connector pin

Applicant:

AMP Incorporated, Harrisburg, Pa. (V. St. A.)

Representative:

Dr. phil. GB Hagen, patent attorney,
8000 Munich 71, Franz-Hals-Str. 21

Named as inventor:
Harold Edwin Cootes,
Paul Turner Hahn, Harrisburg, Pa. (V. St. A.)

Claimed priority:

V. St. v. America March 27, 1958 (724 352)

There are already known tools that serve as a test device and allow to check whether a The driven-in connector pin sits firmly enough in its insertion hole. However, these tools are considered pure Test equipment is formed, and another tool is used to insert the plug into its insertion hole needed.

A test device according to the invention is described in one embodiment of the following and the drawings. The illustrated embodiment serves the purpose of a predetermined To apply tensile force as a test force on an object, but it is obvious that in a similar way mechanical test devices are also designed for the application of other test forces can. From the figures shows

F i g. 1 is a perspective view of a tool according to the invention,

FIGS. 2 to 5 are longitudinal sectional views of the FIG. 1 reproduced tool, with the various Parts are shown in different working positions,

Fig. 6 is a perspective view of a Part of the test device in exploded form, F ί g. 7 is a sectional view along the lines shown in FIG. 2 section line marked VII-VII,

FIG. 8 shows a sectional illustration along the line in FIG. 4 Section line marked VIII-VIII on a larger scale,

809 538/167

3 4

Fig. 9 is a sectional view along the in Fig. 5 The projection 68 of the hammer is so long that it

with IX-DC designated cutting line in a larger through the connecting opening 62 in the second drilling

Scale. tion protrudes when the hammer is to the left

The test device shown serves the purpose of moving one to the end. The aforementioned conically tapered connector pin, which should be so with an elec- 5 free possibility of movement of the bolt 14

Trical wire 10 is connected to be large in a plug hole 12 that the head 60 of the bolt 14 against

to get stuck. The pin has a conically tapered abutment that can be placed between the drilling

Part 2, which is inserted into the Steekerloch, tion and the connection opening 62 is formed so

and has a circumferential rib 4; that the extension 68 of the hammer on the head part 60 The pin has a rolled-on part 6 that can hit the anio.

press on the wire of the cable 10 is used, and further the hammer 66 and the hollow cylinder 26 have

rolled-on flaps 8, which for attachment to the one slot 69, through which a pin 70 goes

Serve insulation of the cable. is provided in the outer handle part 72. One

The tool has a bolt 14 which closes a cap 74 on the upper end of the handle part 72 Has longitudinal slot 16 at one end, with 15 from. The cap 74 includes a pin 80 and a

which the clamping part 6 of the connector pin grasped- locking bolt 82. The pin 80 acts against the

will open. The longitudinal slot 16 is widened on the inside, and helical spring 84, which extends in an axially

the extension 20 is located with a larger cavity running bore of the hammer 66. One

18 in connection so that when the connector pin, such as second spring 78 is between the cap 74 and the F i g. 2 shows, inserted, the rib 4 of the pin 20 hollow cylinder 26 is provided so that the cylinder 26

closes on the bolt while the clamp is under spring force with respect to the handle part 72,

part 8 fits into the extension 20 and the conductor A transverse hole in the hammer 66 contains a

10 lies in the enlarged cavity 18. cylindrical locking member 90, which under the force

A clamping cartridge 24 surrounds the bolt 14 and a spring stands and partly through a round opening screwed into a handle part, which partially protrudes from 25 opening 102 in the hollow cylinder 26.

consists of a hollow cylinder 26 and a shock hammer locking member 90 has a projection 94, which

mer 66 contains a compressive force normally applied to the bolt in a groove 96 of the handle part 72

exercise to insert the plug. The bolt engages. The diameter of this extension 94 is something

itself is smaller than the width of the slot 100 with respect to the handle part of the tool. The groove 96 is displaceable. The cartridge 24 contains a sleeve 30, 3 ° has a sloping curved surface so that,

in which the bolt 14 moves. The bolt when the handle is moved towards the connector,

also moves through a nut 32, which in order to insert the same into its seat hole, the locking

with notches 33 for attaching a screwdriver organ 90 inwards against the force of its spring

is provided. In the cartridge 24 is partially and is pushed under.

Pressure a locking body 34 is provided, which against 35 To the tapered plug in the factory

the thread turns of the nut 32 acts and use the same tool, the bolt 14 is moved outwards

prevents it from turning. pulled out of the handle part of the tool, like this

A spring 36 surrounds the bolt 14 and lies that the balls 46 emerge from the groove 48 and between the end faces of the sleeve 30 and that of the bolts 14, as shown in FIG. 5 shows from the cartridge Threaded sleeve 32. The opposite surface of the sleeve 40 protrudes. It can then be tapered 30 has a recessed conical surface 38 with a plug pin inserted into the slot 16; in flat Mantle surface 40, which is on the circumference of which one presses on the connector pin, is the bolt Sleeve extends around. A socket 42 has a 14 pushed back into the handle part, so that the Flange ring 44 and leads the bolt 14 on the rail 52 from an emergence of the connector pin front end of cartridge 24. Multiple balls 46 45 prevented the slot; this arrangement is shown in FIG. 1 are shown in an annular groove through the face.

38, the flange 44 and the inner wall of the pin is then inserted into its pin hole, cartridge 24 is formed. Since this sleeve 30 is gripped by the handle part 72 and is pressed against the body in which the stem hole is located by the spring 36 against the flange 44, the balls are pressed inwards against the 50. As shown in FIG. 3 to be seen, bolts 14 are then pressed and act against the annular groove 48. the head part 60 of the bolt 14 against the abutment-The groove is slightly wider than the diameter of the surface in the connecting hole 62. The handle part corresponds to 72 balls, so that to a certain extent one is displaced with respect to the bolt 14 and the longitudinal movement of the bolt 14 is possible; the groove springs 78 and 84 pressed together. At the same time, however, if it is not deeper than the radius of the balls, the locking bolt 90 is pushed back until it is addressed. A rail 52 can slide in the groove 16 and set 94 in the slot 100 occurs. In this way, and the hammer 66 extends into a slot 54 in the longitudinal released, the The rail under the force of the processing of the bolt 14 has a spring fast forward 84, so that its extension 68 flap 56 which in a radial slot which strikes the head part 60 of the bolt 14 engages on the sleeve 30; when the bolt 14 is as shown in FIG. 1 60 this way, the kinetic energy of the hammer has the position shown, the rail 52 partially closes on the bolt and from this to the plug pin the groove 16 and places the tapered plug transmitted over the circumferential rib 4, pin in the groove fixed. The low freedom of movement of the bolt 14 in loading

The hammer 66 has a projection 68 to train on the other parts of the tool leaves a

its one end and is in a height-free movement of the same to a small extent,

ment, which has a connection opening 62 with a and in this way the energy of the hammer

second hole is in connection, in which the transferred directly to the connector pin and is not

extended head part 60 of the bolt 14 moves. intercepted by the tool via the balls 46.

When the hammer has given its kinetic energy to the bolt, the parts are in the in Fig. 4 position shown; the conical connector pin is still on the bolt and cannot be removed from slot 16. Removal takes place by pulling on the handle 72. By pulling on the handle, the tensile force required for the test is generated before the The plug pin separates from the tool. If you pull on the handle 72, the force is on the bolt 14 transferred. There are the balls 46 pushed outward by the groove 48, the Flange 44 and the sleeve 30 are added. When the tensile force is a certain predetermined Exceeds the value, the balls move out of the groove 48. The handle of the Tool together with the rail 52 with respect to the bolt 14 to the one shown in FIG. 5 position shown move. This allows the plug pin to emerge from the slot 16. If the connector pin is not in has been properly inserted into the plug hole or for another grand not the for Test withstands the tensile force used, the connector pin is released from its connector hole before the tensile force corresponds to the tensile force specified for the test and before the balls 46 into the annular Groove 48 were pushed back.

The side walls of the groove 48 should be steep with respect to the surface of the bolt 14, so that the cam action on the balls 46 is sudden is exercised. The tool can be calibrated so that there is a certain tensile force for the Examination results, with a high degree of accuracy by the nut 32 after one or screwed in the other direction.

The balls 46, the groove 48, the sleeve 30 and the spring 36 form a locking member under spring force for the bolt 14, which fixes the same in relation to the handle part of the device until the Tensile force equals the tensile force intended for the test. Until it can exercise this traction comes, the connector pin is firmly connected to the bolt.

The frictional forces between the bolt 14 and the sleeve 42, the sleeve 30 and the nut 32 should be as small as possible by suitable material selection, so that after that under spring force standing locking member has released the bolt, exerted only a very low tensile force on the connector pin will.

The bolt 14 is defined by the rail 52, the bushing 42 and the sleeve 30, and the sleeve and the Socket can rotate in cartridge 24 so that when handle 72 is rotated, the plug pin does not is rotated.

Claims (5)

Patent claims: 1. Tool for driving an electrical plug pin or the like. In a plug hole with a in a tubular housing part displaceably mounted firing pin at its front end has a lateral recess for receiving the connector pin and with a predetermined force can be driven forward, characterized in that that the plug pin in the recess (18, 20) of the firing pin (14) by a the recess partially covering the retaining rail (52) can be locked and that between spring-loaded locking means (30, 36, 38, 46, 48) for the firing pin and the retaining rail are provided that when reaching a certain, by pulling back the tool on the tensile test force exerted by the connector pin the firing pin (14) opposite the retaining rail (52) and thus release the connector pin from the recess (18, 20). 2. Tool according to claim 1, characterized in that the front part of the firing pin (14) has a longitudinal groove (16) which is located on a front housing part (24, 26) of the tool attached retaining rail (52) in the locked state of the locking means (30, 36, 38, 46, 48) can engage in the recess (18, 20). 3. Tool according to claim 1 or 2, characterized in that the locking means from a rounded annular groove (48) arranged on the firing pin (14) and at least one by the force of a spring (36) in this annular groove (48) pressable ball (46) exist. 4. Tool according spoke 3, characterized in that one in the front housing part (24, 26) arranged axially displaceable sleeve (30) at the front end an annular, beveled and cam surface (38) pressing against the balls (46) and between them front housing part (24, 26) and the rear end of the sleeve (30) a compression spring (36) is arranged is. 5. Tool according to claim 3 or 4, characterized in that the tension of the compression spring (36) is adjustable. Considered publications:
U.S. Patent Nos. 985 213, 1961 368,
2774133, 2782635, 2 835128. 1 sheet of drawings 809 538/167 4. 68 © Bundesdruckerei Berlin