KR20220124981A - Modular jack - Google Patents

Abstract

The present invention relates to a modular jack which has an optical module so as to enable location to be identified by remotely supplying test power, and can protect a circuit of the optical module even when a PoE patch cord is connected. The modular jack to which a plug of a patch cord is connected includes: a housing which has an insertion hole into which the plug of the patch cord is inserted; a circuit board which is fixed to the inside of the housing; a plurality of interface pins which are installed on the circuit board to be connected to a plurality of plug pins constituting the plug of the patch cord; and one or more optical modules.

Description

Modular Jack {MODULAR JACK}

The present invention relates to a modular jack. More particularly, the present invention relates to a modular jack that includes an optical module to enable location identification by remotely supplying test power, and capable of protecting the circuit of the optical module even when a PoE patch cord is connected.

Ethernet power supply technology (Power over Ethernet; abbreviation PoE) is a technology that transmits power and data together through an Ethernet cable for Ethernet communication, a plug of RJ-45 standard, and a modular jack. Since power can be supplied through Ethernet, a separate power cable is not required, simplifying system configuration and reducing costs.

In general, network equipment such as switches, routers, and gateways in communication rooms, patch panels, and modular jacks of communication equipment can be connected through an Ethernet cable (UTP, FTP, or STP cable, etc.) or its Ethernet patch cord.

In the process of installing, maintaining, or repairing such a communication system, it is necessary to check the connection state between network equipment such as switches, routers, and gateways, patch panels, and communication tools, or whether there is an abnormality in the communication lines connecting them.

In particular, as a premise for communication line maintenance or repair work inside the communication room, the connection location of the communication patch cord connecting the network equipment in the communication room and the patch panel, etc. must first be confirmed or specified. However, depending on the size of the communication room, a large amount of Ethernet cables or Ethernet patch cords are installed in a complicated manner to connect between network devices, between patch panels, or between network devices and patch panels, respectively. Therefore, it is very difficult for the operator to specify the connection position of the connector of each communication patch cord in the communication room internal environment.

To this end, an optical module is provided on the modular jack connected on the communication line, and a tester is installed on one of the connected modular jacks to supply test power. have.

In order to provide such a location identification function, it is designed on the premise that a low-power test power required to turn on an LED or a circuit including an LED provided in the modular jack is applied to the optical module. When the plug of the patch cord for PoE is installed and power is supplied, the optical module may be exposed to overvoltage or overcurrent and damage may occur.

In particular, when abnormal voltage and current are applied by static electricity, inrush current, etc., the possibility of damage to the optical module may further increase. And since the PoE standard tends to increase the size of the power supply, the possibility of failure of the optical module of the modular jack is increasing.

Damage to the optical module does not affect the communication function, but a failure of the optical identification function may occur, which may cause problems in communication system quality, product repair, and cost increase.

An object of the present invention is to provide a modular jack that includes an optical module so that a location can be identified by remotely supplying test power, and capable of protecting the circuit of the optical module even when a PoE patch cord is connected.

In order to solve the above problems, the present invention provides a modular jack for connecting a plug of a patch cord, comprising: a housing having an insertion hole for inserting the plug of the patch cord; a circuit board fixed in the housing; a plurality of interface pins installed on the circuit board to be connected to a plurality of plug pins constituting the plug of the patch cord; One or more lights installed in the housing, each connected to at least one pair of interface pins among a plurality of interface pins in a state in which the plug of the patch cord is separated from the modular jack, and emitting light when power is supplied through the at least one pair of interface pins It is possible to provide a modular jack including a module, and an extension in which the width of at least one of the pair of interface pins connected to the optical module is extended.

In addition, in the process in which the plug of the patch cord is mounted on the modular jack, the timing of releasing the contact with the one or more pairs of the optical module terminals of the one or more pairs of the interface pins and the one or more optical modules respectively connected may not be the same.

And, for elastic connection with the plug pin of the patch cord plug, a plurality of the interface pins are bent or bent upwardly between the outer end and the inner end, and the contact portion is bent or bent again horizontally or downwardly from the contact portion. It further includes a connecting portion configured to be made, and the extension portion may be provided on the contact portion.

Here, in the process in which the plug of the patch cord is mounted, the interface pin with the extension part is first pushed by the plug, so that the connection with the optical module may be released.

The plug housing may propel the extension of the interface pin.

In this case, in a state in which the plug of the patch cord is connected to the modular jack, the state in which the connection state of the interface pin with the extension part and the optical module terminal is released is maintained, and the interface pin with the extension part and the The plug pins may be electrically connected.

In addition, the plug is mounted so that a plurality of plugs are spaced apart and not exposed to the outside, and a plurality of partition walls are provided for forming a plurality of slots in the plug housing so that an interface pin is inserted and connected, and the plug is the modular jack The extension of the interface pin may be propelled by the partition wall during the mounting process.

In addition, when the plug passes through the expansion part in a state in which the plug is mounted on the modular jack, the interface pin connection part may be inserted into a slot between the partition walls to be connected to the plug pin.

In addition, the width of the extension portion of the interface pin may be greater than the width of the plug housing slot, but may be of a size that does not contact the adjacent interface pin.

Here, the housing includes a front housing in which the insertion hole is formed, a rear housing in which the circuit board is mounted to face the insertion hole of the front housing and mounted behind the front housing, and in the rear housing to connect the front housing and the rear housing. It may include a middle housing which is mounted, the interface pin is disposed on the upper portion, and the optical module is mounted in front.

In this case, it is embedded in the front of the middle housing so that one surface of the optical module is exposed, and the outer end of the interface pin is provided with a displaceable tip to the lower side, and at least one pair of the interface pins are the plugs of the patch cord. Depending on whether or not the connection is made, the contact or release of the contact with the terminal of the optical module exposed under the front end of the middle housing may be made.

And, the optical module may include an LED or a circuit including the LED.

In addition, in order to solve the above problems, the present invention is a modular jack for connecting the plug of the patch cord, the housing having an insertion hole for inserting the plug of the patch cord; a circuit board fixed in the housing; a plurality of interface pins installed on the circuit board to be connected to a plurality of plug pins constituting the plug of the patch cord; and at least one pair of the pairs to which the plurality of interface pins are contacted may have different contact timings from the other pairs.

1 is a perspective view of a plug of a modular jack and a patch cord according to an embodiment of the present invention.
2 is an exploded view of the modular jack according to the present invention shown in FIG.
3 is a plan view in a state in which the front housing of the modular jack according to the present invention shown in FIG. 1 is removed.
Figure 4 is a side view of the plug of the patch cord for communication that can be mounted on the modular jack according to the present invention.
5 and 6 are side cross-sectional views showing a state in which the plug of the patch cord is inserted into the insertion hole of the modular jack according to the present invention shown in FIG. 1 .
7 and 8 are side cross-sectional views illustrating a process of disconnecting the electrical connection between the optical module terminal of the modular jack and a pair of interface pins while the plug of the patch cord is inserted and connected to the insertion hole of the modular jack.
9 and 10 show a side cross-sectional view of a state in which the plug of the patch cord is mounted on the modular jack according to the present invention shown in FIG. 1 .

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments described herein and may be embodied in other forms. Rather, the embodiments introduced herein are provided so that the disclosed subject matter may be thorough and complete, and the spirit of the invention may be sufficiently conveyed to those skilled in the art. Like reference numbers refer to like elements throughout.

1 is a perspective view of a modular jack 100 and a plug 300 of a patch cord according to an embodiment of the present invention, and FIG. 2 is an exploded view of the modular jack 100 according to the present invention shown in FIG. 3 is a plan view showing a state in which the front housing 110 of the modular jack 100 according to the present invention shown in FIG. 1 is removed, and FIG. 4 can be mounted on the modular jack 100 according to the present invention. It is one side view of the plug 300 of the patch cord for communication.

The Ethernet cable 200 for communication having a plurality of twisted pairs is equipped with RJ45 standard plugs 300 at both ends to configure a patch cord for communication.

The plug 300 of the patch cord may be mounted on a modular jack 100 such as communication equipment to supply communication data and power in Ethernet power supply technology (PoE).

Accordingly, in the PoE system, the modular jack 100 functions as, for example, an Ethernet power supply socket of an electronic device (not shown), and the plug 300 of the patch cord may also function as, for example, an Ethernet power supply plug. .

However, the modular jack as the Ethernet power supply socket and the plug of the patch cord as the Ethernet power supply plug can also function as a general Ethernet socket and Ethernet plug in which the power supply function is omitted.

In the following description, it is described that one optical module is provided, but the number of optical modules may be plural, the optical module terminal may be more than one pair, and the interface pin connected to the optical module terminal may be one or more pair. However, for convenience of explanation, it will be described that one optical module is provided with a pair of optical module terminals, and that there is a pair of interface pins connected to the optical module terminal.

The modular jack 100 according to the present invention shown in FIGS. 1 to 3 includes a housing having an insertion hole 111 for inserting and installing a plug 300 of a patch cord; a circuit board 160 fixed in the housing; a plurality of interface pins 150 installed on the circuit board 160 to be connected to a plurality of plug pins 350 constituting the plug 300 of the patch cord; It is installed in the housing and is connected to a pair of interface pins 150a and 150b (refer to FIG. 3 ) among the plurality of interface pins 150 in a state in which the plug 300 of the patch cord is separated from the modular jack 100 . An optical module 140 that emits light when power is supplied; an extension in which the width of one of the interface pins 150a among the pair of interface pins 150a and 150b connected to the optical module 140 is extended. (152a) is characterized in that it is provided.

In addition, by the extension 152a provided on one of the interface pins 150a of the pair of interface pins 150a and 150b in contact with the optical module 140 terminal of the modular jack 100 according to the present invention. When the plug 300 of the patch cord is mounted, the terminals 141a and 141b of the optical module 140 exposed under the front end of the middle housing 120 and the interface pins 150a and 150b are in contact or released. The point of view is different. The extension portion 152a refers to a portion in which a width is extended in a partial region of the interface pin. A detailed explanation of this is deferred.

The housings 110 , 120 , and 130 may be provided to configure the outer shape of the modular jack 100 to protect the internal configuration, and to provide a space for inserting the plug 300 of the patch cord.

The housing includes a front housing 110 in which the insertion hole 111 is formed, the circuit board 160 is mounted to face the insertion hole 111 of the front housing 110 , and a rear mounted rear of the front housing 110 . The housing 130 and the front housing 110 are mounted on the rear housing 130 to connect the rear housing 130, the interface pin 150 is disposed on the upper part, and the optical module 140 is mounted on the front. It may be configured to include a middle housing 120 that is.

A circuit board 160 is mounted on the front surface of the rear housing 130 so that a plurality of interface pins 150 are connected to the front, and a plurality of connecting pins 170 can be connected via the circuit board 160 . have.

Specifically, the connecting pin 170 is mounted in the rear housing 130 , and the conductor wire 210 constituting a pair of the Ethernet cable 200 from the rear in the slot 135 provided in the rear housing 130 , FIG. 5 . See below) may be inserted and supported to be connected to the connecting pin 170 .

The interface pin 150 has an inner end 155 connected to the circuit board 160, and an outer end 151 is disposed in the direction of the front housing 110 constituting the housing.

In addition, for elastic connection with the plug pin 350 of the patch cord plug 300, a plurality of the interface pins 150 are bent or bent upward between the inner end and the outer end, so that the plug is attached to the modular jack. When mounted, the plug pin of the plug is in contact with the moving contact part 152 and the contact part is bent or bent again horizontally or downward from the contact part. It may be configured to include a connection part 153 .

The rear housing 130 is mounted such that the circuit board 160 faces the insertion hole 111 of the front housing 110 , and a middle housing 120 is disposed between the front housing 110 and the rear housing 130 . ) may be provided.

The interface pin 150 may be disposed on the middle housing 120 , and the outer end 151 of the interface pin 150 may be displaceably disposed below the front end of the middle housing 120 .

As shown in FIGS. 2 and 3 , mutual contact of the respective interface pins 150 is prevented inside the front end of the middle housing 120 , and the outer end 151 of the interface pin 150 is disposed to be displaceable. A plurality of slots 123 are provided so as to be possible, and the optical module 140 may be exposed to the upper surface of the front end to be mounted, and a pair of optical module terminals 141a and 141b for supplying power to the optical module 140 . may be provided to contact or release contact depending on whether a plug is mounted with the outer ends 151a and 151b of the pair of interface pins 150a and 150b that are exposed downwardly and are inserted and disposed in each slot 123 .

The optical module 140 turns on the modular jack 100 that requires position identification among a pair of modular jacks 100 connected on the communication line to perform a function of identifying the position among the plurality of modular jacks 100 . have.

That is, a pair of modular jacks 100 on one communication line may also be connected with an Ethernet cable 200, and a tester is connected to one of the modular jacks 100 to apply test power to the other modular jacks ( 100) can be identified.

Specifically, the optical module 140 mounted on the middle housing 120 of the modular jack 100 is in contact with a pair of interface pins among the plurality of interface pins 150 in a state in which the plug 300 is not mounted. It is configured to emit light when test power is supplied from a tester, etc. through a communication line connected to a pair of interface pins, so that the position of the modular jack 100 requiring position identification can be identified.

The front end of the middle housing 120 provided with the optical module 140 may be installed in close contact with the rear surface of the front housing 110 so as to be connected to the lower surface of the insertion hole 111 of the front housing 110 .

In addition, when the patch cord supplies PoE power directly to the interface pin or indirectly via the circuit board 160 , a circuit damage problem of the optical module 140 may occur.

Accordingly, when the plug 300 of the patch cord is mounted on the pair of interface terminals electrically connected to the optical module 140 , the pair of interface pins 150 connected to the optical module terminal 141 is connected to the plug 300 . A technology for protecting the optical module 140 by having a structure separated from the pair of plug pins 350 and the pair of optical module terminals 141 in the connection process is applied. That is, when the modular jack and the plug are combined, before the interface pin that can be in switchable contact with the optical module terminal constituting the modular jack is electrically connected to the plug pin of the plug, the electrical connection with the optical module terminal is disconnected to release the plug. It is to protect the optical module from damage by physically blocking the situation in which overvoltage or overcurrent is applied to the optical module from the pin.

However, before the pair of interface pins 150 and the pair of optical module terminals 141a and 141b are completely separated while the plug 300 is mounted on the modular jack 100, the pair of interface pins 150a , 150b) and a pair of corresponding plug pins 350 are in contact and when PoE power is supplied through the patch cord, a part of the power is directly transmitted to the optical module 140 or indirectly through the circuit board 160. Therefore, there is still a risk of damage to the optical module 140 .

Therefore, in the present invention, the plug 300 of the patch cord is connected so as to be in switchable contact with the pair of optical module terminals 141 in the process of being mounted on the modular jack 100 having the optical module 140 . By adopting a structure that blocks the connection of the pair of interface pins with the optical module 140 before the electrical connection of the pair of interface pins 150 and the corresponding pair of plug pins 350, the optical module from the plug pins The optical module is protected from damage by physically blocking the situation in which overvoltage or overcurrent is applied to the device.

Specifically, in the modular jack 100 according to the present invention, one of the interface pins 150a and 150b of the pair of interface pins 150a and the corresponding plug pin come into contact before the corresponding interface pin 150a and the optical module terminal come into contact. It is possible to provide a method of blocking the supply of PoE power to the optical module 140 through a pair of interface pins 150 by releasing the connection state of the 141a. A detailed method will be described later.

As shown in FIG. 2 , for elastic connection with the plug pin 350 of the patch cord plug 300 , a plurality of the interface pins 150 are bent upwards in the middle housing 120 between both ends or One of a pair of interface pins (150a, 150b) in contact with the optical module is provided with a contact part 152 configured by bending and a connection part 153 configured by bending or bending again horizontally or downward from the contact part. The interface pin 150a may include an extension portion 152a at a position of a contact portion of the other interface pins.

Since the inner end 155 of the interface pin 150 is mounted on the circuit board 160 and the outer end 151 is displaceably disposed in the slot 123 of the middle housing 120 , the plug 300 is When mounted, the bottom surface of the plug pin 350 (refer to FIG. 1 ) and the connection part 153 of the interface pin 150 may be in elastic contact. More specifically, in the process of the plug 300 being mounted on the modular jack, the first contact point such as the front edge of the plug pin 350 first contacts the contact portion 152 or the extension portion 152a of the interface pin 150, As the plug continues to enter the modular jack, the contact point with the plug pin moves from the contact part 152 or the extension part 152a to the connection part 153 , and the connection with the connection part 153 is maintained.

The modular jack 100 shown in FIGS. 2 and 3 may be provided with eight interface pins 150 , and the shape of the interface pin 150 or the connection part 153 is the same, but the present invention is an optical module 140 . One of the interface pins 150a of the pair of interface pins 150a and 150b electrically connected to the polarizer has an extension portion 152a in at least a partial region of the contact portion.

The modular jack 100 according to the present invention shown in FIG. 2 is an interface pin in which the 3rd and 6th interface pins 150a and 150b of the 8 interface pins 150 are connected to the optical module 140, and one of them The shape of the interface pin 150b is configured the same as that of the remaining six interface pins 150, and the third interface pin 150a of can be configured.

That is, even if the height and position of the highest point of the connection part 153 are the same, when the plug 300 is mounted on the modular jack 100 according to the presence or absence of an extension part in front of the connection part, the optical module terminals 141a and 141b and a pair of interfaces The contact release timing of the pins 150a and 150b may vary, and the modular jack 100 according to the present invention uses such a characteristic as a pair of interface pins connected to the pair of optical module terminals 141a and 141b ( 150a, 150b) and the corresponding pair of plug pins (350a, 350b) before the electrical connection of the pair of interface pins (150a, 150b) to the optical module terminal (141a, 141b) is cut off structure was hired. A description related thereto will be given later.

As shown in FIG. 4 , the patch cord may be configured by mounting a connector-type plug 300 at the end of the Ethernet communication cable 200 , and the plug 300 includes a plug housing 310 , and a plurality of The plug pins 350 may be respectively connected to insulating-coated conducting wires (not shown) constituting the communication cable 200 . A boot member 330 for preventing the Ethernet communication cable 200 from being bent may be mounted on the rear of the plug housing 310 .

The plug pin 350 may be mounted between the plurality of rib-shaped parallel partition walls 360 formed on the front bottom surface of the plug housing 310 so as not to protrude or be exposed to the outside.

Therefore, when the plug 300 is mounted on the modular jack 100 , the interface pin 150 is inserted between the partition wall 360 on the lower surface of the plug housing 310 of the plug 300 to form a structure connected to the plug pin 350 . have

As described above, the extended portion of the interface pin 150a may have a size that cannot enter between the pair of barrier ribs of the plug shown in FIG. 4 as an area in which the width of the interface pin is enlarged.

In addition, the interface pin 150a, which is in contact with the optical module terminal 141a and has an extension, has an enlarged width, but an insulating state between the adjacent interface pins and the phase must be maintained, and has a size that cannot enter between the partition walls 360. When configured, as described with reference to FIG. 5 or less, the pair of plug pins 350a and 350b and the pair of interface pins 150a and 150b are connected before the optical module terminals 141a and 141b and a pair of the interface pins 150a and 150b may be released from contact. Accordingly, the width of the extension 152a may be greater than the width of the slot formed between the pair of barrier ribs, but the limit may be a size capable of maintaining the interphase insulation between the interface pins. A detailed description of the process of releasing the contact between the optical module and the interface pin through the extension 152a will be postponed.

Each of the plug pins 350 is configured in the form of a blade, and in the process of inserting the plug 300 into the modular jack, it can be connected in a stacked form while riding over the interface pin 150 in the form of a spring or wire.

The interface pin 150 is configured in the form of a wire but has a connection part 153 and is fixed to the circuit board 160 only once, so when the connection of the plug 300 to the modular jack 100 is completed, the interface pin 150 ) may maintain an elastic contact state with the plug pin 350 .

In addition, when the plug housing 310 enters the insertion hole 111 of the modular jack 100 , the interface pin 150 without an extension part is inserted into the slot between the partition walls 360 of the plug housing 310 as will be described later. The interface pin 150 connected to the optical module 140 may keep in contact with the optical module terminals 141a and 141b until it enters the interior and comes into contact with the plug pin 350, but the extension 152a The provided interface pin 150a may be disconnected from the optical module terminal 141a. Described specifically.

5 and 6 are side cross-sectional views of a state in which the plug 300 of the patch cord is inserted into the insertion hole 111 of the modular jack 100 according to the present invention shown in FIG. 1 .

Specifically, the interface pin 150 connected to the optical module 140 is the 3rd and 6th interface pins 150a and 150b out of 8, and FIG. 5 shows the modular jack at the front of the 3rd interface pin 150a. It shows a cross-sectional view of 100, and FIG. 6 shows a cross-sectional view of the modular jack 100 from the front of the sixth interface pin 150b.

As described above, the 6th interface pin 150b is configured in the same shape as the other 6 interface pins so that the front of the connection part 153b has the same width and is composed of a simple curved contact part 152b, and the 3rd interface pin ( 150a) may be formed with an extended part 152a having an extended width in front of the connection part 153a.

In addition, as shown in FIGS. 5 and 6 , the outer ends 151a and 151b of the 3rd and 6th interface pins 150a and 150b are connected to the modular jack 100 in the process of the plug 300 entering the process. It maintains a state in contact with the optical module terminals 141a and 141b.

7 and 8 show the optical module terminals 141a and 141b of the modular jack 100 and a pair of the plug 300 of the patch cord enter and connect to the insertion hole 111 of the modular jack 100. A side cross-sectional view of the contact release process of the interface pins 150a and 150b is shown.

Specifically, in the state shown in FIGS. 5 and 6 , in a state in which the plug 300 is additionally entered into the modular jack 100, FIG. 7 is a cross-sectional view of the modular jack 100 from the front of the third interface pin 150a. FIG. 8 shows a cross-sectional view of the modular jack 100 from the front of the sixth interface pin 150b.

As described above, in the plug 300 of a typical patch cord, the plug pin 350 is disposed between the plurality of rib-shaped partition walls 360 and is not exposed to the outside, and the plug 300 is connected to the modular jack 100 . It has a standardized structure in which the interface pin 150 is inserted between the partition wall 360 on the bottom of the plug housing 310 to be connected to the plug pin 350 .

The third interface pin 150a shown in FIG. 7 is provided with an extended part 152a with an extended width in front of the highest point of the connecting part 153a, and the sixth interface pin 150b shown in FIG. 8 is the connecting part 153b. is configured in a curved shape as a whole, so that the contact portion 153b has the same width in front of the highest point of the contact portion 152b.

Therefore, when the plug housing 310 enters the insertion hole 111 of the modular jack 100 , as shown in FIG. 8 , the 6th interface pin 150b without an extension part is a partition wall of the plug housing 310 . The 6th interface pin 150b maintains contact with the optical module terminals 141a and 141b until it enters between 360 and comes into contact with the plug pin 350b.

However, the third interface pin 150a is provided with an extended part 152a in front of the highest point of the connection part 153a, so that the extended part 152a cannot be inserted into the slot between the partition walls of the plug while the plug is mounted on the modular jack. .

Accordingly, as shown in FIG. 8 , the extension 152a of the interface pin no. 3 150a is propelled by the barrier rib of the plug housing so that the outer end 151a of the interface pin no. 3 150a and the optical module terminal are connected. It can be disconnected and electrically disconnected.

In this way, in the process in which the modular jack 100 is mounted, the pair of plug pins 350 and the pair of interface pins 150a and 150b connected to the optical module 140 are electrically connected to the optical module 140 before the electrical connection. ) and a pair of interface pins 150a and 150b are released to reduce the risk of damage to the optical module 140 of the modular jack 100 even when the patch cord is a PoE patch cord for power.

9 and 10 show a side cross-sectional view of a state in which the plug 300 of the patch cord is mounted on the modular jack 100 according to the present invention shown in FIG. 1 .

Specifically, in the state shown in FIGS. 7 and 8 , the plug 300 is additionally inserted into the modular jack 100 to complete the connection, and FIG. 9 shows the modular jack 100 in front of the third interface pin 150a. ), and FIG. 10 shows a cross-sectional view of the modular jack 100 from the front of the sixth interface pin 150b.

In FIG. 7 , the third interface pin 150a and the third plug pin 350a are in a non-contact state, but the extension 152a of the third interface pin 150a is propelled by the plug housing or its bulkhead to promote the third interface pin. (150a) and the optical module terminals 141a and 141b are disconnected. In FIG. 8, the 6th interface pin 150b starts to enter the slot between the partition walls of the plug housing, but the 6th interface pin 150a ) and the 6th plug pin 350b are in a state before contact, so the 6th interface pin 150b and the optical module terminals 141a and 141b are maintained in a connected state.

In this state, when the plug 300 further enters the inside of the modular jack 100, as shown in FIG. 9 , the area near the highest point of the connection part 153a of the interface pin 150a no. 3 is not an extended part but has a normal width. It enters the slot between the partition walls of the plug housing and is connected to the No. 3 plug pin 350a to complete the connection, and the No. 6 interface pin 150b enters the slot between the partition walls and the contact portion 152b is The 6th plug pin 350b is connected to the 6th plug pin 350b, and the 6th plug pin 350b moves to the uppermost point of the connection part 153b of the 6th interface pin 150b while maintaining the contact state as the plug enters additionally. This is done.

In this way, in the process in which the plug of the patch cord is mounted on the modular jack, at least one pair of pairs (interface pins and plug pins) to which the plurality of plug pins and the corresponding plurality of interface pins are in contact is the other pair. Timing of contact with them may be different.

That is, as shown in FIGS. 9 and 10 , PoE power is supplied in a state in which the 3rd and 6th interface pins 150a and 150b and the 3rd and 6th plug pins 350a and 350b corresponding thereto are connected. Even in this case, the electrical connection connecting the 3rd and 6th interface pins 150a and 150b and the optical module 140 is already released, so that the optical module 140 can be protected.

Here, before the plug 300 of the patch cord is mounted on the modular jack 100, a pair of optical module terminals 141a and 141b of the optical module 140 of the modular jack 100 and a pair of interface pins ( In a state in which 150a and 150b are connected, the circuit to which test power is supplied through the pair of interface pins 150a and 150b after being electrically connected from a test power supply (not shown) such as a tester is in a closed circuit state. Optical module 140 blinking control is possible, but when the plug 300 of the patch cord is mounted on the modular jack 100, a pair of optical module terminals (141a, 141b) and a pair of interface pins (150a, 150b) ) is disconnected and the circuit to which test power is supplied becomes an open circuit state, so that it is impossible to control the blinking of the optical module 140 , but the optical module 140 can be protected from overcurrent or overvoltage.

Although the present specification has been described with reference to preferred embodiments of the present invention, those skilled in the art can variously modify and change the present invention without departing from the spirit and scope of the present invention as set forth in the claims described below. will be able to carry out Therefore, if the modified implementation basically includes the elements of the claims of the present invention, all of them should be considered to be included in the technical scope of the present invention.

Claims (13)

In the modular jack for connecting the plug of the patch cord,
a housing having an insertion hole for inserting the patch cord plug;
a circuit board fixed in the housing;
a plurality of interface pins installed on the circuit board to be connected to a plurality of plug pins constituting the plug of the patch cord;
One or more lights installed in the housing, each connected to at least one pair of interface pins among a plurality of interface pins in a state in which the plug of the patch cord is separated from the modular jack, and emitting light when power is supplied through the at least one pair of interface pins module; including;
The modular jack, characterized in that the extension portion is provided with an extension of at least one interface pin of the pair of interface pins connected to the optical module. According to claim 1,
In the process in which the plug of the patch cord is mounted on the modular jack, the timing of releasing the contact with the one or more pairs of the optical module terminals of the one or more pair of the interface pins and the one or more optical modules respectively connected to the modular jack is not the same. jack. According to claim 1,
For elastic connection with the plug pin of the patch cord plug, a plurality of the interface pins are formed by bending or bending upward between the outer end and the inner end, and horizontally or downwardly bending or bending from the contact portion. A modular jack, characterized in that the extension is provided on the contact portion. 4. The method of claim 3,
In the process of mounting the plug of the patch cord, the interface pin with the extension part is first pushed by the plug to release the connection from the optical module. 5. The method of claim 4,
The modular jack, characterized in that the plug housing pushes the extension of the interface pin. 4. The method of claim 3,
In a state in which the plug of the patch cord is connected to the modular jack, the state in which the connection state of the interface pin having the extension part and the optical module terminal is released is maintained, and the interface pin and the plug pin having the extension part are maintained at the same time. Modular jack, characterized in that electrically connected. 6. The method of claim 5,
The plug is mounted so that a plurality of plugs are spaced apart and not exposed to the outside, and a plurality of partition walls are provided for forming a plurality of slots in the plug housing to be connected by inserting an interface pin, and the plug is mounted on the modular jack. In the process of becoming a modular jack, the extension of the interface pin is propelled by the partition wall. 8. The method of claim 7,
When the plug passes through the expansion part in a state in which the plug is mounted on the modular jack, the connection part of the interface pin is inserted into a slot between the partition walls to be connected to the plug pin. According to claim 1,
The width of the extension part of the interface pin is larger than the width of the plug housing slot, but the size of the interface pin is not in contact with the adjacent interface pin. According to claim 1,
The housing includes a front housing in which the insertion hole is formed, a rear housing in which the circuit board is mounted to face the insertion hole of the front housing and mounted behind the front housing, and a rear housing connected to the front housing and the rear housing, Modular jack, characterized in that it comprises a middle housing on which the interface pin is disposed on the upper portion and the optical module is mounted on the front side. 11. The method of claim 10,
It is embedded in the front of the middle housing so that one surface of the optical module is exposed, and a front end portion is provided at which the outer end of the interface pin is displaceable downward;
The at least one pair of the interface pins are in contact with or released from contact with the terminal of the optical module exposed under the front end of the middle housing according to whether the patch cord is plugged in or not. According to claim 1,
The optical module is a modular jack, characterized in that it comprises an LED or a circuit including the LED. In the modular jack for connecting the plug of the patch cord,
a housing having an insertion hole for inserting the patch cord plug;
a circuit board fixed in the housing;
a plurality of interface pins installed on the circuit board to be connected to a plurality of plug pins constituting the plug of the patch cord; and
In the process in which the plug of the patch cord is mounted on the modular jack, at least one pair of the pairs in which the plurality of plug pins and the corresponding plurality of interface pins are in contact with each other has a different contact timing from the other pairs Features a modular jack.

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