KR20130135105A - Container socket - Google Patents

Abstract

The present invention relates to a switch type socket which is used for a container socket for vessel, which includes: a housing which surrounds the internal space of the housing and has a housing opening; an electrical socket which is arranged independently in the housing opening and has multiple electrical connection parts which are all arranged in a plug connection direction; a circuit breaker which is arranged in the internal space of the housing and has a mechanical actuator; and a mechanical coupling element which enables the operation of the circuit breaker by a plug which is inserted into the socket by connecting the actuator of the circuit breaker with the electrical socket. Based on the present invention, the coupling element is extended in the plug connection direction in parallel at one end side, has an actuating pin which is guided for the switching movement of the plug connection direction, and is connected with the actuator at the other end side of the coupling element.

Description

Container socket {CONTAINER SOCKET}

The present invention relates to a switched socket used as a container socket for ships, comprising: a housing surrounding a space inside a housing, the housing having a housing opening, and a plurality of electrical devices disposed independently of each other in the housing opening and all arranged in a plug connection direction. An electrical socket having a contact, and arranged in a space inside the housing, connected to at least one pair of electrical contacts, the electrical connection between the at least one power connection line and the electrical contact of the electrical socket in the OFF state. Circuit breakers with mechanical actuators for disconnecting electrical contact pairs and, in the ON-state, to make electrical contact between the electrical contact pairs such that at least one power connection is made between the electrical contacts of the electrical socket. Electric actuator Given by connecting the jacket consists of a mechanical coupling element which allows control the circuit breaker by means of a plug that is inserted into the socket.

This type of socket is for example supplied to a power connection for powering a ship's cooling container and cooling the container. Because of their special purpose in ship environments, these sockets must be able to prevent the generation of currents and voltages that can harm humans. Therefore, in the case of such a socket, in addition to safety measures such as physically blocking the electrical contact, the power supply can be cut off, that is, the plug must be designed so that no voltage exists in the electrical contact portion of the socket. This can be realized by having a circuit breaker to block the power supplied from the power source to the electrical contacts. In essence, the breaker can cut off the power supply to all electrical contacts of the electrical socket. Of course, it is also possible to cut off only the power supply to some sockets, and such modified forms are included in the present invention.

Container sockets with such power cut-off have been disclosed in EP 1 766 731 B1 and DE 20 2008 011 268 U1. In the case of the container socket disclosed herein, the breaker is automatically controlled by the movement of the plug in the socket. That is, the breaker is activated through the movement of inserting the plug into the socket to supply power to the electrical contact of the socket. In the case of the socket specified in EP1 766 731 B1, a socket is installed on the wall of the housing, and a circuit breaker is fixed at the bottom of the housing. The circuit breaker is controlled by the rotational movement of the plug in the socket. In the case of EP 1 766 731 B1, the socket is fixed to the rear wall of the housing, and the socket is installed in front of the wall. The breaker is activated through the rotational movement of the plug inside the socket through the mechanical coupling element.

Basically, for the special use of sockets with this type of power-off function, an important premise is that electrical connections should be made only when safe power transfer between the contacts of the socket and the plug is possible. This is a prerequisite for preventing the occurrence of flashover voltage, which can damage both the socket and the plug and injure the human body indirectly or directly to the person handling the plug and the socket.

It is an object of the present invention to achieve an improved container socket on the basis of this fact which is an improvement over the previously known sockets in terms of assembly and production costs, and at the same time having the same or higher mechanical robustness.

This object is in accordance with the present invention, in which the coupling element has an actuating pin at one end and the actuating pin is directed in the plug connection direction for the switching movement in the plug connection direction, and at the other end the actuator Achieved when connected to The socket according to the invention is characterized by the fact that the plug is inserted and fixed in the socket connection direction only through linear movement. As is known in the art, additional rotational movements for the breaker control around the axis of the plug connection direction do not occur in the case of sockets according to the invention. This simplifies the operation of the socket since the electrical connection is only caused by the insertion movement that occurs only when the plug is inserted and does not require additional rotation. It has been found that in the socket according to the invention, the voltage generation at the electrical contacts of the socket can be achieved sufficiently safely with only a linear insertion movement.

The socket according to the invention does not require a guide element to be formed in the socket for the rotational movement of the plug because of this property. As a result, the socket according to the present invention may exclude main components of the existing socket, and requires only a few components as a whole, and is very robust and easy to assemble. In the case of the socket according to the present invention, the actuating pin is activated and moved in the process of pushing the plug into the socket in the plug connection direction so that the switching movement of the actuating pin is transmitted to the coupling element. The transfer to the coupling element can then be achieved, for example, by constructing an actuating pin in the coupling element integrally with the coupling element. Also included in the present invention is a modified form of socket having two or more actuating pins. The coupling element directs this movement to one actuator of the breaker to control the breaker. The actuator of the circuit breaker is an externally accessible circuit breaker button or switch, and may have various types of switches such as a rotary switch, a toggle switch, or a push switch. By forming the socket in accordance with the present invention, the insertion movement in the plug insertion process is simply transmitted to the breaker, and the breaker is controlled by this movement in the breaker. Only a few components are involved in this delivery, especially through a single component. That is, through a coupling element with a suitably formed actuating pin and a receiving portion for the actuator of the breaker.

In a first preferred embodiment, the electrical contacts and the actuating pins of the socket are enclosed by the socket outer wall, which is arranged parallel to this direction in front of the plug connection direction, thus switching in the plug connection direction. This possibly has one insertion opening.

With this structure, on the one hand, unintended contact with the electrical contacts of the socket is prevented as much as possible. This is because the electrical contacts of the socket are blocked by the socket outer wall. The socket outer wall is preferably extended in the plug connection direction by or longer than the length of the electrical contact. On the other hand, through the form of the actuating pin in accordance with the invention it can act obliquely to the plug connection direction and can prevent unwanted mechanical influences such as the influence of external forces that can damage the actuating pin. It is preferred that the actuating pin does not rise above the socket outer wall in the opposite direction to the plug connection direction, but extends longer than the actuating pin in the opposite direction to the plug connection direction. The socket outer wall may then have the form of a cylindrical wall or structured housing which individually, entirely or individually and wholly encompasses the electrical contacts.

In addition, it is preferred that the coupling elements have two actuating pins which are preferably arranged in parallel at one end and which are formed in the coupling element as one piece. This form, on the one hand, transfers energy from the plug inserted in the plug connection direction to two distant points on the coupling element. This allows the coupling element to perform a more accurate overall and less burdensome guide. In the form of using two actuating pins, above all, the activation of the actuator on the breaker causes the coupling element to transmit energy which acts obliquely in the plug connection direction, in particular the run-up slope of the actuator on the coupling element. Is preferred when controlled by the wedge-shaped face or the like. At this time, it is preferred that the two actuating pins are arranged on the same side as the surface on which the coupling element is arranged and the coupling element performs the movement in the plug connection direction. This side is preferably arranged to encompass the actuator of the breaker or at least be adjacent to the actuator of the breaker. With this type of arrangement, a particularly advantageous reverse line in the guide of the coupling element is created in the plug connection direction, so that the component as a whole has greater load capacity and greater durability against damage and in the plug connection direction. Can be realized less difficult.

Furthermore, when the actuator is realized as a single push switch or toggle switch, it is preferred that the switch is connected directly with the mechanical coupling element and moved in parallel with the plug connection direction through the linear movement of the coupling element. In the case of a breaker having a push switch or a toggle switch as an actuator, it is a breaker as a component for the breaker unit configuration. An economical and technically robust breaker unit is based on the parts as existing products. At this time, the toggle switch extends from the breaker and has a lever that can flip the switch around the toggle axis, so that the switch can control the breaker. In the case of a push switch, it has one or two buttons. In the case of a push switch with a single button, the button is a pushbutton switch or a single press in which the transition from the on-state to the off-state is performed through the elastic return of the button. It can be realized in the form of a resting button switch in which the state is switched to the on-state and then the button is pressed again to return to the off-state. A breaker with a push switch may have a double button. One of the two buttons is then used to switch to the on-state and the other to switch to the off-state. Through direct operation of the push switch or the toggle switch in accordance with the present invention, complicated operation through a plurality of components is omitted, thereby simplifying the assembly and production of the socket in accordance with the invention. Manipulation is accomplished by direct energy transfer to the toggle switch or push switch through openings, run up slopes, wedges or similar elements in the coupling element.

It is also preferred that the actuator is controlled by a run-up inclination in which the toggle axis is arranged parallel to the plug connection direction and connected by the actuating pins, particularly preferably by a run-up inclination to some extent parallel to the plug connection direction. It is preferred to be realized as a toggle switch or to be realized as a toggle switch in which the toggle axis is arranged perpendicular to the plug connection direction and received in the coupling element through the opening. This embodiment allows the use of a breaker with a toggle switch, and allows this breaker to be installed in two assembly ways in a container socket according to the invention. In the case of such a breaker, the toggle axis of the toggle switch is arranged in the plug connection direction, so that the linear movement of the coupling element must be changed to the steering direction of the toggle number position perpendicular to the plug connection direction. This is achieved according to the principle of the invention via a run up slope of the coupling element, which causes the toggle switch to move laterally along the plug connection direction. The toggle switch can then be set to return by the spring force from the on-state achieved through plug insertion to the off-state. Another alternative is to arrange two run-up slopes facing each other, ie, one run-up slope for operating the toggle switch on-state and another run-up slope for operating the toggle switch off-state. There is also. In the case of arranging two run-up inclines, the two run-up inclinations may be arranged parallel to each other and installed on the coupling element with some distance in the plug connection direction.

In another form, the toggle shaft of the toggle switch is disposed perpendicular to the plug connection direction. In this case the toggle switch can be operated more simply through linear movement in the plug connection direction, for example by moving the toggle switch around in the opening of the coupling element.

It is also preferred that the actuator consists of one on-button and one off-button, and the actuating pin is realized in combination with a push switch connected to one run-up slope. This run-up incline is operated in one direction through the movement of the actuating pin and combined with another run-up incline. This second run-up incline is operated by the movement of the off-button actuating pin. Operate in the other direction. This embodiment greatly simplifies the assembly technique of incorporating a breaker with a push button consisting of two buttons into a socket according to the invention. At this time, when the coupling element is moved, the on-switch is operated by the run-up inclination of the coupling element in the plug connection direction, and when the coupling element is moved, the off-switch is operated in the opposite direction so that the breaker when the plug is removed from the socket Is switched to the disconnected state. The two run-up slopes may then be arranged in sequence in the plug connection direction or side by side in the plug connection direction, depending on the arrangement of the breakers with respect to the plug connection direction.

In another preferred embodiment the actuator is realized as a rotary switch, which is connected to the actuating pin via a mechanical transmission unit. The transfer unit converts the rotary movement of the rotary switch into a linear movement of the actuating pin. When using this embodiment, an existing embodiment of a circuit breaker in which an actuator is realized as a rotary switch can be used in the container socket according to the present invention, and this can be used in a manner that can be advantageously realized in assembly technology and production technology. Here, the rotary switch extends from the breaker and rotates about an axis, and is an actuator fixed to the rotating shaft outside the breaker housing. In the case of a toggle switch, on the other hand, the toggle lever is fixed to the rotating shaft inside the breaker housing. The mechanical transmission unit which enables the operation of the rotary switch can be realized as a single piece in the coupling element. For example, it may be realized in a rocker arm or the like. It is also possible to realize this mechanical transmission unit in two parts so that, for example, a linear movement from one transmission element is transferred to the second transmission element, causing a rotation of the second transmission element.

It is also preferred that the actuator is realized as a rotary switch which is connected to the actuating pin by the rocker arm and which is operated eccentrically with respect to the rotary axis of the rotary switch. This embodiment allows a special form for the operation of the rotary switch to be realized in a simpler, assembly and production technique. At this time, the rotary switch is guided by a rocker arm guide bent by a pin eccentrically fixed to the rotary switch or arranged at an angle with respect to the plug connection direction so that the linear movement of the coupling element can be changed by the rotational movement of the rotary switch. .

It is furthermore preferred that the actuator be realized as a rotary switch which is connected with an actuating pin which is operated by a gear rack connected with the actuating pin by means of a circular gear unit or gear. This embodiment allows the rotary switch of the circuit breaker to be directly coupled with the gear and the gear unit, and the gear unit can be realized in the mechanical coupling element or also in the mechanical coupling element. The linear movement of the coupling element is thereby transmitted (directly or indirectly) to the gear unit, the gear rack working with the teeth and the gear unit to enable the operation of the rotary switch which translates this linear movement into rotational movement.

It is also preferred to be realized as a rotary switch having a belt that is partially enclosed and coupled to the actuating pin and which is coupled to the rotary switch. This embodiment causes the linear motion to be converted into rotational movement by the belt, which is achieved through frictional engagement conversion or integral conversion, such as the belt having a frictional surface or an integral surface, such as a toothed unit. This embodiment is in the form of an openable rotary switch of a breaker that can be procured as a part, often directly enclosing the actuator, so that additional components for the operation of the breaker can be omitted by the mechanical coupling element.

In addition, this kind of actuating pin is measured and connected to the actuator of the breaker so that the plug is inserted deeply into the socket so that sufficient contact between the contacts of the plug with the electrical contacts is achieved and the on-state of the breaker The type in which switching to the furnace is to take place is preferred. An electrical contact length of at least 2 mm, preferably at least 5 mm, is preferred in the direction of plug connection. This form generates voltage on the electrical contacts of the socket only when a plug is inserted into the socket according to the invention, when sufficient electrical contact occurs between the contacts of the plug and the electrical contacts of the socket. This prevents arc-over from occurring when the electrical contacts are separated from each other before electrical contact occurs. Horak damages the socket and plug on a regular basis and can endanger the health of the person inserting the plug into the socket. If the voltage on the contacts of the socket can be interrupted by the breaker, depending on how the electrical contact is designed, when the contacts come in contact with 2 mm or more in the plug connection direction, preferably 5 mm or more in the plug connection direction, especially for safety reasons When the length comes into contact, sufficient electrical contact can occur.

This embodiment can be realized by designing a short actuating pin so that electrical contact occurs only when the contact between the face of the plug for pushing the actuating pin in the plug connecting direction and the electrical contact overlaps by the intended length. . In addition, the breaker can be designed so that the actuating pin must pass through the plug until the actuating pins overlap each other by the intended length between the contact and the electrical contact. In this case, the actuating pins and the electrical contacts may overlap each other in the opposite direction to the plug connection direction, and the front surfaces of the electrical contacts of the plug may be arranged in line with the surfaces for operating the actuating pins formed in the plug. According to the implementation form of the plug, the surface for operating the actuating pin is adjusted, and the mechanical connection of the actuating pin and the circuit breaker auxiliary element is adjusted according to the position of the folding contact of the plug and the socket to achieve the invention-based embodiment. can do. The shape of the plug and socket shall comply with the regulations in which the shape and position of the contacts and the length in the direction of the plug connection are recorded, which criteria can be directly introduced by the expert in determining the shape of the embodiment.

It is also preferred that the socket according to the invention be realized as a spring element which energizes the coupling element and turns the coupling element on-state. Basically, the breaker switches on-state and has a resilient return enough to switch off the mechanical coupling element and the actuating pin realized on or connected to this element. However, a more preferred and functionally more advantageous form is that this return effect of the container socket according to the present invention has a separate spring element. A separate spring element accurately disconnects the electrical connection to the socket and removes the voltage in the socket when the socket is unplugged. Basically, for the safe use of the socket in accordance with the present invention, the voltage on the electrical contacts of the socket must be removed before the electrical connection between the plug and the socket is disconnected. In particular, it is preferred that there is no voltage on the electrical contacts of the socket until the electrical contacts of the plug and socket achieve an overlap of at least 2 mm, or preferably at least 5 mm, in the plug connection direction. To achieve this, the mechanical components involved in the process of transferring the operation movement from the socket to the breaker are preloaded by the spring elements, causing the components to be off-state, ie separated actuators. It is preferred that the setting pin is preloaded in the opposite direction of the plug connection direction. Such a spring element can be realized, for example, in the form of a coil spring generating a compressive force. In addition, other spring elements of spiral spring or similar form may also be introduced.

In another preferred embodiment, the coupling element comprises the actuator (s) and the connecting unit integrally for direct connection with the actuator of the breaker. This coupling element realized integrally with the actuating pins or the actuating pins and the connecting unit allows simple assembly with fewer components and at the same time a more robust realization of the container socket according to the invention, i.e. malfunctions and generally It enables a more durable realization of loads due to energy appearing during use. Integral means that the coupling element consists of two components assembled into one unit, consisting of one component or joined together with an adhesive.

In another preferred embodiment the electrical contact of the socket is realized as a contact case so that the electrical contact pin of the plug can be received internally and the actuating pin (s) can be measured and connected to the actuator of the breaker. The transition from the off-state to the on-state only occurs when the electrical contact of the plug is inserted into the electrical contact of the socket by at least 2 mm, preferably at least 5 mm in length.

The structure of this embodiment allows for a very safe electrical contact between the socket and the plug, while at the same time suitable guidance in the direction of the plug connection via the electrical contact which facilitates accurate and lateral free operation of the coupling element. The overlap between the electrical contacts achieved through this embodiment is effective, among other things, to prevent arc-over, which can occur when inserting and removing the plug, making the configuration of the unit in a very efficient manner. do. The functional mode of this embodiment is such that the actuating pin and / or coupling element only moves in the plug connection direction after the intended overlap of the electrical contacts has been sufficiently achieved or when the overlap of the intended length has been exceeded. . That is, this can be achieved, for example, by making the actuating pins appropriately short relative to the contact surface of the plug which moves the actuating pins in the plug connection direction. In the same principle, the actuating pin starts to move as soon as it begins to insert the plug, but this movement can only be applied after a suitable interval leading to the operation of the breaker.

The present invention can achieve improved container sockets with improved and at the same time higher or higher mechanical rigidity than previously known sockets in terms of assembly and production costs.

Preferred embodiments of the invention are illustrated by the accompanying drawings.
1A shows an exploded view of one embodiment of a container socket in accordance with the present invention.
FIG. 1B shows a plan view of a portion of an embodiment when the embodiment of FIG. 1 is in an off-state.
1C shows a perspective view when the embodiment of FIG. 1 is assembled and in an off-state.
1D shows a perspective view when the embodiment of FIG. 1 is on-state.
2A shows a perspective view when the second embodiment is in the off-state.
FIG. 2B shows a perspective view when the embodiment of FIG. 2A is on-state.
3A shows a perspective view when the third embodiment is in the off-state.
3B shows a perspective view when the embodiment of FIG. 3A is on-state.
4A shows a perspective view when the fourth embodiment is in the off-state.
4B shows a perspective view when the embodiment of FIG. 4A is on-state.
5A shows a perspective view when the fifth embodiment is in the off-state.
5B shows a perspective view when the embodiment of FIG. 5A is on-state.
6A shows a perspective view when the sixth embodiment is in the off-state.
FIG. 6B shows a perspective view when the embodiment of FIG. 6A is on-state.

1A shows an exploded view of one embodiment of a container socket with a breaker in the form of a rotary switch in accordance with the present invention. This container socket consists of four main parts: the first housing element 10 which covers the socket 11, the fixing flange 12 and the rear housing part 13; A second housing element 20 integrally coupled with the first housing element 10 by bite locking elements 21a and 22b at the ends of the two housing bars 21 and 22; Breaker 30; And a coupling element 40 for circuit breaker control.

The first housing element 10 has a socket 11 with a total of four electrical contacts 11a-d installed in total four independent of each other. The four electrical contacts 11a-d are realized in the form of a core section and the rear part can contact the face facing the socket 1 of the fixing flange 12 of the housing. Three of these lines serve as a line for three-phase exchange and are electrically connected to the blocking surface of the breaker 30. The opposite side of the breaker is connected to three corresponding three-phase AC energy sources, which are generally connected to the user of the container, such as the vessel's power grid and cooling unit. The fourth line is for the ground wire for safety measures, and is connected to the part of the vessel that is in contact with the ground for electric transport, that is, the part of the container or the user that should be in contact with the ground.

The socket 11 is generally cylindrical in shape and wraps the electrical contacts so that the electrical contacts are accessible from the front. The electrical contacts are once again enclosed in individually cylindrical cylindrical covers, once again within the cylindrical rim, as shown in detail in FIG. 1B. The plug can be inserted and secured to the socket 11 via a covering realized as a bayonet catch when the front portion has an undercut shape with a curved portion projecting forward.

The socket 11 is integral and realized in a rectangular shape and at each corner has a fixing flange 12 with an opening for screwing the container socket in the housing or in the container itself or in other parts.

On the rear side of the fixing flange 12 there is a rear housing portion consisting of two vertical wall reinforcements and one bottom plate. This part contributes to strengthening the overall structure of the container socket according to the present invention and to realizing the socket as one compact unit.

There are two longitudinal lanes in the bottom plate 13a of this housing structure, in which the protruding bars 21 and 22 of the second housing element 20 can be inserted. At the ends of the bars 21, 22 facing the socket 11 there are two bleed locking elements 21a, 22b, which can engage the opening or undercut of the bottom plate of the first housing element. This allows the second housing element to be integrally coupled to the first housing element 10.

The breaker is integrally coupled between the first and second housing elements 10 and 20 and also fixed laterally by the side walls 13b and c of the rear housing structure of the first housing element, as can be seen in all the illustrations below. It is installed in the form.

The bite locking elements 21a, 22a are installed along the rear housing structure side walls 13b, c of the first housing element and can be fixedly engaged with the windows 14a, b of the housing wall.

Through the transverse bars 23 installed on the second housing element 20 and the two corner reinforcing elements 15a, b arranged above the rear housing structure side walls 13b, c of the first housing element, the breaker It is fixedly installed in the transverse direction.

The breaker 30 includes a rotary switch 31 having an operating portion 32 eccentrically above the breaker housing.

The eccentric operation part 32 is provided in the slider 41 arrange | positioned at the sliding plate 42 of the coupling element 40. As shown in FIG. The slider 41 has a sliding lane extending diagonally in the plug connection direction 1.

The sliding plate 42 is fixed to a transverse bar 43 arranged laterally with respect to the plug connection direction 1, and protrudes from the transverse bar 4 in the plug connection direction 1 to the second housing. It is located between two coil guide pins 44a and b facing in the direction of the element 20. Coil guide pins 44a and b are arranged in two coil guide covers 24a and b on second housing element 20. The two coil springs 45a and b are wound around the coil guide pins 44a and b and are supported between the coil guide covers 24a and b and the transverse bars 43.

Two actuating pins 46a and b protrude from the transverse bar 43 in the opposite direction to the plug connection direction 1, which are two openings on the fixing flange 12 with the plug in. It is inserted into the internal space of the socket 11 via 16a, b. The actuating pins 46a, b are arranged side by side in the socket 11 and eccentrically with respect to the plug connection direction 1 towards the longitudinal center axis and the wall of the housing in the form of a cylinder of the socket 11. The actuating pin is operated through the ring-shaped wall portion of the plug. This is because the actuating pin is pushed against the spring force of the coil springs 45a and b when the plug is inserted in the socket in the plug connection direction.

Through this insertion of the plug into the socket 11, the coupling element 40 is moved from the off-state to the on-state as shown in FIG. 1D as shown in FIG. 1D, with the breaker 30 Actuating pin 32 is moved from the off-state position of the rotary switch to the on-state position. As a result, the electrical contacts 11a-c are changed from the non-voltage contact state to the voltage contact state. As can be seen in FIG. 1B, the actuating pins 46a and b are such that the contact between the plug and the contact pin can be made only when the electrical contact pin of the plug is inserted into the contact case of the socket by a length X equal to 5 mm. Will have a length. Only after the electrical contact pin of the plug is inserted to the predetermined length, the breaker is operated by the coupling element 40 through the insertion movement of the plug into the socket, and the current flows through the electrical contacts 11a-c. .

When the plug 50 is pulled out again, the sliding plate is pressed through the compression spring elements 45a and b in the opposite direction to the plug connection direction, that is, the housing flange 12 so that the breaker is moved back off and the electrical contact portion ( Current is cut off at 11a-c). This still occurs when the pins are x = 5 mm long with the case between the plug and socket electrical contacts and there is an electrical connection. The plug can then be unplugged, eliminating the possibility of being a threat to the user during the unplugging process.

2A and 2B show a second embodiment of a container socket according to the present invention, which is basically the same in construction as the first embodiment and differs only in the following details:

In the second embodiment the breaker has a toggle switch realized as an actuator. At this time, the toggle shaft of the toggle switch is located inside the breaker and disposed transverse to the plug connection direction 101.

The toggle switch 132 passes through a rectangular opening 141 in the plate 142 realized on the coupling element 140 and extends upwardly through the opening. The coupling plate 142 is arranged in a position and arrangement to match the rocker arm plate 42 of the first embodiment.

When inserting the plug, the coupling element 140 is guided back along the plug connection direction, ie in the opposite direction of the tension of the spring, and in the process flips the toggle switch 132 back to turn the breaker on. Unplugging again causes the opening 141 on the coupling element 140 to move forward through the springs 145a and b in the opposite direction to the plug connection direction, so that the breaker returns to the off-state as shown in FIG. 2A. do.

3A, B show an embodiment which is basically the same as the embodiment shown in FIGS. 2A, B and differs only in the following features:

In the embodiment of Figs. 3A and B, the breaker has a toggle switch as an actuator. At this time, the toggle shaft of the toggle switch is disposed inside the circuit breaker and exists in parallel with the plug connection direction 201. The toggle switch 232 is guided in the rocker arm guide 241, which has a rocker arm section that exists diagonally with respect to the plug connection direction and is realized in the rocker arm plate 242. The rocker arm plate 242 is arranged similarly to the rocker arm plate 42 in the first embodiment.

When plug 250 is inserted into a socket having the same shape as in the third embodiment, after sufficient electrical contact has occurred between the socket and the contact of the plug, coupling element 240 is shown in FIG. 2A by an actuating pin. In the plug connection direction, as shown in Fig. 3B. The toggle switch 232 is flipped from the state shown in FIG. 3A to the state shown in FIG. 3B and the breaker is thereby switched on. When unplugging, the rocker arm plate 242 on the coupling element 240 is pushed back in the opposite direction to the plug connection direction in an analog manner, thereby flipping the toggle switch back to that shown in FIG. 3A.

In the fourth embodiment shown in Figs. 4A and 4B, the breaker is distinguished from other embodiments in that the breaker is realized in the form of two control keys 432a and b. As shown in FIG. 4A, when the breaker is in the off-state, the control keys 432b are pressed down and the control keys 432 are raised upward. In the off-state, the breaker is turned on through the displacement of the coupling element 440, with the control keys 432a pressed down along the run-up slope 441a. At the same time, the control key 432b is raised upward in the pressed state. This is achieved by run-up tilt 441b, which moves in reverse. Run-up inclines 441a and b are arranged on the transverse bars 443 along the rocker arm plate 42 of the first embodiment and are provided on the fingers 442a and b extending in the plug connection direction parallel to the transverse bars.

When the plug is pulled out, the run-up inclination is pushed back to the opposite direction of the plug connection, so that the control key 432b is pushed down and the control key 432a rises upward. This movement is caused by the coil springs 445a and b.

5A, B and 6A, B show a circuit breaker having a rotational breaker as an actuator. 5A and 5B, the actuator interacts with a gear rack 541 which is realized as a gear 532 and protrudes from the transverse bar 543 in the plug connection direction. As the coupling element 540 is displaced in the plug connection direction or in the opposite direction by the spring force of the return springs 545a and b, the off-state of the breaker shown in Fig. 5A is turned on as shown in Fig. 5B. -To the state or vice versa.

In the sixth embodiment shown in Figs. 6A and 6B, the actuator of the breaker is realized as the rotary knob 632, which is wrapped 360 ° by one belt 641. As shown in Figs. The belt 641 is not an endless belt, but has one end fixed to a longitudinal bar 642 extending in a plug connection direction from a transverse bar like the gear rack 541. The other end of the belt is fixed to the transverse bar 643.

By inserting the plug into the socket, the coupling element 640 of the sixth embodiment is moved parallel to the power insertion direction, where this linear movement is converted to the rotational movement of the rotary knob 632 by the belt. In the process of removing the plug from the socket, a counter-rotational motion occurs by linear movement of the coupling element 640 by the return springs 645a and b.

Claims (14)

A switched socket used as a container socket for ships,
A housing which encloses a space inside the housing and has a housing opening,
Electrical sockets having a plurality of electrical contacts arranged independent of each other in the housing opening and all arranged in the plug connection direction,
A circuit breaker having a mechanical actuator disposed in the interior space of the housing and connected to at least one electrical contact pair,
In the OFF-state of the actuator, disconnect this pair of electrical contacts so that the electrical connection between the at least one power lead and the electrical socket of the electrical socket is disconnected.
A breaker having an actuator in the ON-state of the actuator, the actuator electrically contacting this pair of electrical contacts so that an electrical connection is made between at least one power connection and an electrical contact of the electrical socket;
A mechanical coupling element which connects the actuator of the breaker with the electrical socket and allows the breaker to be controlled by a plug inserted into the socket,
The coupling element extends in parallel with the plug connection direction at one end and has an actuating pin guided for the switching movement in the plug connection direction, the other end of the coupling element being connected to the actuator Socket The method according to claim 1,
An electrical contact between the socket and the actuating pin is enclosed by the outer wall of the socket, which extends parallel to the front of the plug in the direction of plug connection and guides for switching movement in the direction of the plug connection. Characterized in that it has a socket. The method according to claim 1 or 2,
A socket, characterized in that the coupling element has two actuating pins on one side, the actuating pins preferably extending in parallel and more preferably integrally formed on the coupling element. The method according to any one of claims 1 to 3,
A socket, characterized in that the actuator is a push switch or toggle switch which is directly connected with the mechanical coupling element and which is operated in parallel with the plug connection direction by the linear movement of the coupling element. The method according to any one of claims 1 to 4,
The actuator is a toggle switch, and the toggle axis of this toggle switch
Actuated by a run-up slope disposed approximately parallel to the plug connection direction and connected to the actuating pin, preferably by a run-up slope arranged at regular intervals from one another in the plug connection direction;
A socket, characterized in that it is arranged approximately perpendicular to the plug connection direction and is received in an opening in the coupling element. The method according to any one of claims 1 to 5,
The actuator is a push switch, which is composed of an on-button and an off-button, and the actuating pin is connected to the first run-up slope, which is the on-button when the actuating pin moves. A socket which is moved in one direction and connected with a second run up slope, the second run up slope moving the off-button in the opposite direction when the actuating pin is moved. The method according to any one of claims 1 to 6,
The actuator is a rotary switch, the rotary switch being connected to the actuating pin via a mechanical transfer unit, the mechanical transfer unit converting the linear movement of the actuating pin into the rotary movement of the rotary switch , socket. The method according to any one of claims 1 to 7,
And the actuator is a rotary switch, the rotary switch being connected with the actuating pin via the rocker arm and operated eccentrically with respect to the axis of rotation of the rotary switch. The method according to any one of claims 1 to 8,
The actuator is a rotary switch, the rotary switch being connected to the actuating pin via a part or gear of the circular gear, the actuating pin being actuated by a gear rack connected to the actuating pin, socket. The method according to any one of claims 1 to 9,
And the actuator is a rotary switch, wherein the rotary switch is actuated by a belt which partially surrounds the coupling element connected with the rotary switch and is connected with the actuating pin. The method according to any one of claims 1 to 10,
The size of the actuating pin and the connection of the actuating pin with the actuator of the breaker are preferably at least 2 mm in the plug connection direction after the plug is sufficiently inserted into the socket to achieve electrical contact between the electrical contacts. A socket, characterized in that the breaker is only able to switch from off-state to on-state only when at least 5 mm is contacted. The method according to any one of claims 1 to 11,
A socket, characterized by applying a force to the coupling element that the spring element moves off-state. The method according to any one of claims 1 to 12,
A socket, characterized in that the coupling element integrally comprises the actuating pin (s) and the connecting unit for direct connection of the breaker to the actuator. The method according to any one of claims 1 to 13,
The electrical contacts of the socket are embodied as a contact case for receiving the electrical contacts of the plug therein, the size of the actuating pin (s) and the connection of the breaker to the actuator of the plug being such that the electrical contact of the plug is at least 2 mm, preferably 5 mm. And the switch of the breaker is adapted to switch from the off-state to the on-state only after being inserted into the electrical contact of the socket.

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