CABLE CONNECTOR

Abstract

A cable connector providing transmission of electric current from an electrical plug to an electrical device through an electric cable and a supply cable via electrical terminals upon achieving a contact of female terminals to male terminals and it is characterized in that it has at least one locking mechanism containing at least one female socket whereon male terminals are located, at least one male socket whereon female terminals are located and at least one tab providing interlocking of a female socket and a male socket and at least one resilient hook-whereon a tab is installed.

Claims

1. A cable connector transmitting electric current from electrical plug to an electrical device through an electric cable and a supply cable via electrical terminals by enabling contact of female terminals and male terminals characterised by having: at least one female socket whereon the said male terminals are located, at least one male socket whereon the said female terminals are located, and a locking mechanism wherein at least one tab and at least one resilient hook that the tab is locked in that provides interlocking of the said female socket and the male socket with each other.

2. A cable connector according to claim 1 characterized in that it comprises a tab located preferably on a female socket and a resilient hook located on a male socket.

3. A cable connector according to claim 1 characterized in that it comprises at least one inclined tab front surface on the said tab.

4. A cable connector according to claim 1 and it is characterized in that it comprises at least one tab rear surface formed on the said tab preventing backward movement of the resilient hook when mounted.

5. A cable connector according to claim 1 characterized in that it comprises at least one resilient hook housing formed on the said male socket wherein the resilient hook is seated.

6. A cable connector according to claim 1, and it is characterized in that it comprises at least one guide channel formed on the said female socket and a tab, wherein the resilient hook housing is inserted.

7. A cable connector according to claim 1 characterized in that it comprises at least one unlocking point formed on the resilient hook providing movement of the resilient hook in plus (+) and minus directions () on a hook motion axis.

8. A cable connector according to claim 1 characterized in that it comprises at least one tab cavity formed on the said resilient hook wherein the tab is seated.

9. A cable connector according to claim 8 characterized in that it comprises at least one cavity side surface formed on the opposing sides of the said tab cavity preventing lateral movements of the resilient hook when the tab is seated in the tab cavity.

10. A cable connector according to claim 8 characterized in that it comprises a cavity rear surface on the upper part of the said tab cavity located in such a manner to allow complete seating of the tab in the cavity.

11. A cable connector according to claim 8 and characterized in that it comprises a cavity rear surface on the upper part of the said tab cavity that prevents backward movement of the resilient hook.

12. A cable connector according to claim 5, characterized by having: at least one rear compression surface; at least one side compression surface; at least one upper compression surface; and at least one front compression surface; formed on the said resilient hook that provide compression of the resilient hook in the resilient hook housing.

13. A cable connector according to claim 5 characterized in that, formed on the resilient hook housing to compress resilient hook, it comprises: at least one housing rear surface, contacting rear compression surface to provide rear compression; at least one housing side surface, contacting side compression surface to provide side compression; and at least one housing front surface, contacting upper compression surface and front compression surface to provide front and upper compression.

14. A cable connector according to claim 1 characterized in that it has same number of female terminal housings as the number of female terminals located on the said male socket and placed in the same geometric axis as the male terminals and thus providing transmission of electric current between terminals in such a manner to produce minimum electrical resistance.

15. A cable connector according to claim 1 characterized in that it comprises at least one connection bracket formed on the said female socket to provide mounting onto the electrical device.

16. A cable connector according to claim 1 characterized in that the said resilient hook is preferably made in different colour from the male socket and the female socket.

17. A cable connector according to claim 1 characterized in that the said resilient hook is made of a flexible material.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0015] In order to explain the structure and the advantages together with the additional components explicitly, the invention should be assessed with the figures that are explained hereinafter.

[0016] FIG. 1 is mounted view of the cable connector of the invention on the electrical device.

[0017] FIG. 2 is perspective view of the cable connector of the invention.

[0018] FIG. 3 is perspective view of the female socket on the cable connector of the invention disclosed hereunder.

[0019] FIG. 4 is exploded view of male socket on the cable connector of the invention disclosed hereunder.

[0020] FIG. 5 is cross-sectional view of the cable connector of the invention in non-connected status.

[0021] FIG. 6 is cross-sectional view of the cable connector of the invention in connected status.

[0022]

TABLE-US-00001 Part References 10 Cable connector 11 Electrical device 12 Electrical plug 13 Electric cable 14 Supply cable 15 Electrical terminal 16 Locking mechanism 20 Female socket 21 Connection bracket 22 Male terminal 23 Tab 23a Tab front surface 23b Tab rear surface 24 Guide channel 30 Male socket 31 Female terminal housing 32 Female terminal 33 Resilient hook housing 33a Housing side surface 33b Housing rear surface 33c Housing front surface 40 Resilient hook 40a Hook motion axis 41 Unlocking point 42 Tab cavity 43 Cavity rear surface 44 Cavity front surface 45 Rear compression surface 46 Side compression surface 47 Upper compression surface 48 Front compression surface 49 Cavity side surface + Plus direction Minus direction

DETAILED DESCRIPTION OF THE INVENTION

[0023] The cable connector (10), which is the subject of the invention explained here, is designed in such a manner to prevent involuntary electric supply interruption and in the meantime allows easy manual mounting and detachment even without observing. In order to achieve this aim, the cable connector (10) in the broadest meaning, consists of at least one female socket (20) whereon male terminals (22) are located, at least one male socket (30) whereon female terminals (32) are located and at least one locking mechanism (16) having at least one tab (23) and at least one resilient hook (40) inserted in the tab (23) to provide interlocking of the female socket (20) and the male socket (30)

[0024] FIGS. 1 and 2 show mounted view of the cable connector (10) on the electrical device (11) and perspective view of the cable connector (10) respectively. The female socket (20) is fixed on the electrical device (11) mechanically by means of the connection bracket (21) and electrically by means of the electrical terminals (15). After connection to the electrical device (11), the female terminals (32) located on the male socket (30) and the male terminals (22) located on the female socket (20) are interconnected and electric current supplied from the electrical plug (12) is transmitted to the electrical device (11) through the electric cable (13), the supply cable (14) and the electrical terminals (15). The female socket (20) is designed to be mounted on the electrical device (11) in fixed manner whereas the male socket (30) is designed to be removable. The male socket (30) supplies electricity from mains by means of the electrical plug (12) connected to it. Electrical connection is provided by interconnection of the male socket (30) and the female socket (20).

[0025] FIG. 3 shows exploded view of the female socket (20) located on the cable connector (10) of the invention disclosed hereunder. The supply cable (14) connected to the female socket (20) has common electrical terminals (15) to provide connection to the electrical device (11). The said electrical terminals (15) can be in various sizes and forms in order to be compatible with the connections in the electrical device (11). The female socket (20) has a connection bracket (21) so as to fix it onto the electrical device (11). The tab (23) located on the female socket is structurally in triangle form. The tab front surface (23a) has a slope so as to fit into the tab cavity (42) in the locking mechanism (16). The tab rear surface (23b) is preferably designed in perpendicular form to prevent involuntary disconnection from the tab cavity (42) while in locked status. The guide channel (24) located on the female socket (20) is in the size and form to tightly surround the resilient hook (40) and the resilient hook housing (33). Thus, contact of the female terminals (32) to the male terminals (22) in a position other than intended is prevented and only proper contact is ensured at all times. The female socket (20) is connected to the male terminals (22) mechanically and electrically. The female socket (20), together with all its components is integrated using plastic moulding method to insulate both electrically and against other external effects.

[0026] FIG. 4 shows exploded view of the male socket (30) provided on the cable connector (10) in the invention disclosed hereunder. The locking mechanism (16) contains a resilient hook (40) located on the male socket (30) and a resilient hook housing (33). The resilient hook (40) consists of a tab cavity (42) where the tab (23) located on the female socket (20) can be inserted in, a cavity front surface (44) limiting backward movement of the tab cavity (42), a cavity rear surface (43) located on the opposite side and cavity side surfaces (49). Thanks to this structure, after the tab (23) is inserted in the resilient hook (40), disconnection of the male terminals (22) and the female terminals (32) due to involuntary movements is prevented. Deactivation of the locking mechanism (16), whenever desired, which disconnects the male socket (30) from the female socket (20) can be achieved by pressing the unlocking point (41) located on the resilient hook (40) that moves the resilent hook in plus direction (+) or minus direction (). When a force is applied onto the unlocking point (41) in minus direction (), the tab (23) is released from the tab cavity (42) and this enables disconnection of the male socket (30) from the female socket (20). When the force applied on the unlocking point in minus direction () is removed, the resilient hook (40) moves in plus direction (+) and takes its initial position.

[0027] All components, other than the resilient hook (40), forming the male socket (30) are integrated mechanically by means of plastic moulding method. The resilient hook (40) is produced separately and mounted into the resilient hook housing (33) after plastic moulding process. The rear compression surface (45), the side compression surface (46), the upper compression surface (47) and the front compression surface (48) on the resilient hook (40) enables fixing of the resilient hook (40) into the resilient hook housing (33). The rear compression surface (45) on the resilient hook (40) rests against the housing rear surface (33b); the side compression surface (46) against the housing side surface (33a); the upper compression surface (47) and the front compression surface (48) against the housing front surface (33c); therefore the resilient hook (40) in the resilient hook gripper housing (33) is constricted in all four directions.

[0028] The resilient hook (40) and the tab (23) are designed in such manner to carry the pull forces required for safety between the male socket (30) and the female socket (20). Thus disconnection of the male terminals (22) from the female terminals (32) due to external forces that may be applied onto the cable connector (10) involuntarily is prevented.

[0029] The resilient hook (40) has preferably different colour than of the male socket (30) and the female socket (20). Particularly, in places where visibility is limited and/or the area the cable connector (10) located has little light, different colour of the resilient hook (40) increases noticeability and facilitates mounting and detaching of the cable connector (10).

[0030] FIG. 5 and FIG. 6 show cross section views of the cable connector (10) of the invention respectively in unconnected and connected situations. While the male terminals (32) and the female terminals (22) provide electrical connection, two components of the locking system (16), namely, the tab (23) and the resilient hook (40) provide mechanical connection. The resilient hook (40) is made of a flexible plastic material and designed in such a way to flex easily in plus (+) and minus () directions on the hook motion axis (40a). During connection of the male socket (30) to the female socket (20), the tab front surface (23a) gets in touch with the resilient hook (40) and moves the resilient hook (40) in minus direction () with surface pressure and the tab (23) fully enters in the tab cavity (42) as a result of axial motion, and the resilient hook (40) moves back in plus direction (+) under spring effect and traps the tab (23) in the tab cavity (42). During this procedure, the resilient hook housing (33) and the resilient hook (40) fit completely into the guide channel (24). Thus locking of the male socket (30) and the female socket (20) is achieved. After locking, the tab rear surface (23b) and the cavity front surface (44) are positioned across each other and resist the extraction force.

[0031] A push force is applied onto the unlocking point (41) in minus direction () in order to deactivate the locking mechanism (16). The male socket (30) may disconnect from the female socket (20) after the cavity front surface (44) moves in minus direction () on the hook motion axis (40a) and goes below the tab rear surface (23b) level. Thus the male terminals (22) move out of the female terminal housing (31) and become disconnected with the female terminals (32) and both electrical and mechanical disconnections are achieved.