RU2492561C1 - Removable electric plug ejector - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: ejector consists of a nosepiece and a housing. The nosepiece sits on the housing of the plug. When a small lever (16) is pressed, the housing of the ejector rotates around the nosepiece and, while resting on side members (11) in the housing of the socket, draws the plug (1) from the socket (2). When the cord is accidentally pulled, a collar, while moving together with the electric cord, tightens a cable which rotates the housing of the ejector. Rotation of the housing of the ejector leads to the drawing of the plug from the socket. Tension of the cable can activate a spring which rotates the housing of the ejector and the plug is drawn from the socket.

EFFECT: enabling easy and safe disconnection of an electric plug from a socket, in plug-and-socket connections without built-in means of pulling the plug, as well as for automatic disconnection of a plug and a socket during accidental pulling of the power cable with a force enough to result in the falling of a person or equipment, with negative consequences in form of injuries, damage to equipment or electric mains.

3 cl, 9 dwg

Description

The invention relates to electrical engineering. It can be used to easily and safely disconnect the electric plug from the outlet, in plug connections that do not have built-in means of pushing the plug.

The widest scope of the invention is the plug connections of residential and industrial premises, consisting of a plug with contact pins and sockets with contact sockets.

To ensure good contact, the socket of the socket must fit tightly over the plug pin. In this regard, when connecting or disconnecting the plug connection between the socket and the pin, large frictional forces arise, which can loosen or break the fastening elements of the socket. Moreover, the pulling force on the plug is more dangerous for mounting the socket than the pushing one. Sometimes, when removing the plug from the socket, the socket itself is pulled out of its place of termination. This makes the plugs very dangerous in terms of fire and electric shock.

A known socket with a means of pushing the plug (patent HU 208882), including a pusher in the form of a two-shouldered lever, when you press one shoulder of which, through a pusher with a push button, the second shoulder pushes the plug out of the socket. In this design, the plug is removed from the outlet not by the pulling force of the hand, but by the pushing force transmitted by hand through the button to the ejector of the plug. This design allows to reduce during operation the likelihood of damage to the elements of the plug connection (pull the plug out of the wall or break the contacts of the electrical cord with the contact rods of the plug).

Known plug connection (patent RU 2343608), designed to automatically disconnect the plug from the outlet when pulling the electric cord with a force higher than that which occurs from an accidental jerk of the power cord. On the socket there is a lever with an ejector equipped with a cord holder. Under the action of the pulling force of the electric cord, the lever pushes the plug out of the socket through the ejector. The pulling force from the cord is not transmitted to the outlet, but through the lever creates a pushing force to the plug.

It is known preserving the plug connection (patent RU 2397585), designed to automatically disconnect the plug from the outlet when pulling the electric cord with a force higher than that which occurs from an accidental jerk of the power cord. There is a plug ejector on the socket, there is a cable, one end of which is fixed to the clamp covering the electric cord so that the sliding force of the clamp relative to the electrical cord is greater than the allowable tension of the cord, and a tip inserted into the socket is installed on the second end of the cable. When the cord is tensioned above the permissible limit, the cable tip acts on the plug ejector, which pushes the plug out of the socket.

Known plug (patent DE 19513170) with an ejector. The ejector includes a rod extending in the center of the fork with a thrust pad at the end. If you hold the plug and press (with your finger or through the lever) on the stem, the thrust pad creates a force on the outlet, which compensates for the friction between the contacts. This reduces the load on the outlet. At the same time, this design creates inconvenience when connecting the plugs, since when clicking on the plug, you must be careful not to press the ejector. Removing the plug is also not very convenient. It is necessary to rest against the plug and press the ejector. The stem passing in the center of the fork complicates its design and reduces its reliability.

Known plug (patent DE 29807627) with a push mechanism selected for the prototype. An ejector driven by a two-arm lever is built into the plug. The end of the long arm of the lever is attached to the power cord. When the power cord is pulled in a direction coaxial with the plug being removed from the socket, the long lever turns and the short lever acts on the ejector, which pushes the plug from the socket. Thus, the plug is removed from the socket, without creating a pulling force on the socket, dangerous for fixing the socket in the wall. However, such a mechanism complicates the design of the plug and reduces the reliability of its operation. If you accidentally catch on the cord, it will be pulled to the side, and a force will act on the lever, which will create a moment on the lever, leading to jamming of the plug in the socket and hazardously affecting the socket mounting. Moreover, due to the length of the lever, the harmful effect on the plug connection will be much greater than if a cord was pulled in a connection that does not have built-in means for pushing the plug.

The technical result of the invention is the provision of easy disconnection of the plug and the socket, which do not have built-in ejectors, protection of the socket from damage when pulling the plug by hand or when pulling the electric cord with a force higher than the allowable, which can occur from an accidental jerk of the power cord.

The technical result is achieved by the fact that the ejector consists of a nozzle and the ejector body pivotally connected, the nozzle has a groove that allows the ejector to be mounted on the fork body, so that it can be held firmly on it, while the groove walls are capable of transmitting the disconnecting force of the ejector to the fork, the ejector body is able to rotate on the nozzle about an axis perpendicular to the direction of extraction of the plug, the body has the shape of an arch enveloping the plug, and the sides of the arch have a curved end surface Profile of allowing the ejector body during rotation around the nozzle to interact with the body outlet, creating the buoyancy force on the plug. In the upper part of the arch there is a lever for applying the effort of the user's hand to the ejector. To automatically disconnect the plug from the outlet when the electric cord is tensioned with a force higher than the allowable one, there is a collar on the ejector, covering the electric cord so that the force of sliding of the clamp relative to the electric cord is greater than the allowable cord tension, there is a cable, one end of which is fixed to the clamp and the second end the cable is fixed on the side of the arch of the ejector body, on the nozzle and on the case of the ejector there are guides for the cable, which allow it to rotate to rpus ejector. For a more reliable disconnection of the plug from the outlet when the electric cord is tensioned with a force higher than the allowable one, there is a spring that can rotate the ejector body around the nozzle, ensuring its interaction with the socket body, and there is a latch on the ejector body that can hold the body with the stop on the nozzle of the ejector in a position that does not interfere with the connection of the plug with the socket, the nozzle has a two-arm lever, one end of which is connected via a cable to a clamp on an electric cord, and w The swarm has the ability to release the lock from the stop.

In Fig.1 - ejector mounted on a plug in connection with a socket, side view.

Figure 2 - detail of the ejector with a fork, front view.

Figure 3 - detail of the ejector with a fork, top view.

Figure 4 - ejector mounted on a plug in the plug at the time of disconnection from the outlet, side view.

Figure 5 is a side view of an ejector with a device for automatically disconnecting from the cord tension, mounted on an electric plug in connection with an outlet.

Figure 6 - detail of the ejector with a device for automatically disconnecting from the cord tension, side view.

Figure 7 is a side view of an ejector with a device for automatically disconnecting from the cord tension, mounted on a plug at the time of disconnection from the socket.

On Fig - ejector with a device for automatically disconnecting from the tension of the cord with a spring amplifier mounted on a plug in connection with the outlet, side view.

In Fig.9 - ejector with a device for automatically disconnecting from the tension of the cord with a spring amplifier mounted on a plug at the time of disconnection from the outlet, side view.

The ejector works as follows. To facilitate pulling the plug out of the socket by hand on the plug body, as a rule, there are protrusions (sometimes the surface of the case is simply made ribbed). In the connected state (FIG. 1), the plug 1 is in the socket 2. The ejector 3 has a nozzle 4 that holds it on the plug 2. The nozzle 4 (FIG. 1, FIG. 2, FIG. 3) has an insert 6 in which a groove 7, the width of which is equal to the thickness of the fork 2 in front of the protrusions 8, which facilitate pulling the fork by hand. The presence of protrusions (or ribbed surface) allows the nozzle to transmit a buoyant force to the fork. Different forks have different shapes and sizes. Depending on the thickness of the fork, interchangeable inserts 6 with grooves 7 of different widths can be used. The nozzle 4 has openings 9 for protrusions 10 on the sidewalls 11 of the ejector body 12. The ejector body is made in the form of an arch. The sides 11 have an end surface 13 of a curved profile that touches the socket body 14 at points at the level of the axes of the contact pins of the plug 15. The ejector 3 with the socket body 14 form a cam mechanism in which the rotational movement of the sidewalls 11 is converted into the translational movement of the plug 1. The curvature of the sidewall profile 13 is selected so that when the ejector body 12 is rotated in the holes 9 with a small force, a sufficient buoyant force is created at the points of contact. There is a lever 16 on the ejector body for applying a user's hand force to the ejector. When you press the lever 16 in the direction of the arrow (Fig. 1), the ejector body 12 (Fig. 1, Fig. 2, Fig. 3) begins to rotate in the holes 9 (Fig. 4) using the protrusions 10. In this case, the sidewalls 11 of the ejector body 12 with profiled end surfaces 13 slide along the body of the socket 14. This creates a force acting through the ejector 3 on the protrusions 8 of the plug 1 in the direction from the socket 2. As a result, the rotation of the body of the ejector 12 leads to the removal of the plug 1 from the socket 2. Before inserting the plug back into the socket, the lever 16 must be turned up.

With a slight improvement, the ejector can be used to automatically disconnect the plug from the outlet when the cord is pulled with a force higher than that which arises from an accidental jerking of the power cord. Such an ejector works as follows. In the connected state (Fig. 5), the plug 1 with the cord 17 is located in the socket 2. A collar 18 is installed on the cord 17 (Fig. 5 of Fig. 6), on which one of the ends of the cable is fixed 19. The cable passes through the guide hole on the nozzle 20 and along the guide in the form of an arc 21 on the sidewall 11 of the ejector body, on the protrusion 22 of which the second end of the cable is fixed. The length of the cord portion 17 (FIG. 5) from the plug 1 to the clamp 18 should be so much longer than the cable 19 so that when the cable is pulled in any direction, the cord does not stretch and allows you to freely pull the plug out of the socket.

When pulling the cord 17 (Fig. 5) from a random jerk in the direction of the arrow, the clamp 18 (Fig. 7), moving together with the electric cord, pulls on the cable 19, which rotates the housing of the ejector 12, just as when you press the lever 16 with your hand (Unlike the ejector described above, the lever must be pressed from the bottom up). As a result, as when pressed by hand, when pulling the cable, the rotation of the housing of the ejector 12 leads to the removal of the plug 1 from the socket 2.

For more reliable disconnection of the plug when pulling the cord, you can use a spring amplifier. A pusher with a device for automatically disconnecting from the tension of the cord with a spring amplifier works as follows. On the protrusion 10 of the ejector body (Fig. 8), a torsion spring 23 is installed with hooks on the body and nozzle. The spring force is directed to rotate the housing of the ejector 12 toward the socket 2. The latch 24 using the protrusion 25 holds the housing of the ejector from rotation. A two-arm lever 26 is installed on the nozzle, one end of which is in contact with the latch, and the end of the cable is fixed to the second 19. The cable passes through the guide hole 20. The second end of the cable is fixed to the clamp 18.

When pulling the cord 17 (Fig. 8) from a random jerk in the direction of the arrow, the clamp 18 (Fig. 9), moving together with the electric cord, pulls on the cable 19, which turns the end of the lever 26. As a result, the second end of the lever pushes the latch 24 from the stop. Under the action of the spring 23, the housing of the ejector 12 rotates towards the outlet, which leads to the removal of the plug 1 from the outlet 2.

Thus, the proposed removable ejector plug allows you to easily disconnect the plug from the outlet in the plug connections that do not have built-in ejector. It also allows you to disconnect the plug from the outlet when pulling the power cord with a force that is greater than the force that may result from an accidental jerking of the power cord, and prevent the fall of a person or equipment, with negative consequences in the form of injuries, damage to equipment or electrical networks.

Claims (3)

1. A removable ejector plug of the plug in the composition of the plug connection that does not have built-in means of pushing the plug, characterized in that the ejector consists of a nozzle and the housing of the ejector, pivotally connected, the nozzle has a groove that allows you to push the ejector on the body of the plug, so that it can hold it securely, while the groove walls are able to transmit the disconnecting force of the ejector to the fork, the ejector body is able to rotate on the nozzle around an axis perpendicular to the direction To remove the plug, the body has the shape of an arch envelopeing the plug, and the sides of the arch have an end surface of a curved profile that allows the ejector body to rotate around the nozzle to interact with the socket body, creating a buoyant force on the plug, there is a lever in the upper part of the arch for applying hand force user to the ejector. 2. A removable ejector plug of the plug, consisting of a nozzle capable of holding securely on the plug, and the housing of the ejector, able to interact with the housing of the outlet, creating a pushing force on the plug, characterized in that there is a clamp covering the electrical cord so that the sliding force of the clamp relative to the electric cord there is more than the force of the permissible tension of the cord, there is a cable, one end of which is fixed to the clamp, and the second end of the cable is fixed to the ejector body, on the nozzle e and on the case of the ejector there are guides for the cable, which allow him to rotate the case of the ejector when tensioned. 3. The removable ejector of the plug according to claim 2, characterized in that there is a spring that can rotate the ejector body around the nozzle, ensuring its interaction with the socket body, there is a latch on the ejector body that can hold it with the stop that is on the nozzle the ejector body in a position that does not interfere with the connection of the plug with the socket, the nozzle has a two-arm lever, one end of which is connected via a cable to a cable clamp on an electric cord, and the second has the ability to ozhdat lock from lock.

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