KR102350307B1 - Trip Device of DC Circuit Breaker - Google Patents

Abstract

The present invention relates to a trip device for a DC circuit breaker, and more particularly, to a trip device for a DC circuit breaker capable of adjusting a gap between contacts.
A trip device for a DC circuit breaker according to an embodiment of the present invention includes a trip stator; a mover rod installed through the trip stator to move up and down; a mover block contacting or separated from a fixed contact portion of the trip stator while sliding along the mover rod; a gap adjusting member coupled to the lower end of the mover rod to move the mover block while vertically moving along the mover rod; and a fixing pin connecting the mover block and the gap adjusting member to move the mover block and the gap adjusting member together.

Description

Trip Device of DC Circuit Breaker

The present invention relates to a trip device for a DC circuit breaker, and more particularly, to a trip device for a DC circuit breaker capable of adjusting a gap between contacts.

In general, a DC circuit breaker is a device used to quickly and efficiently cut off the system in order to protect the equipment and system in case of maintenance, replacement, or fault current in the high-voltage direct current (HVDC) transmission line or distribution line. to be.

DC transmission has the advantage of low power loss and high stability compared to AC transmission. However, DC transmission has a characteristic that it is difficult to step-up and step-down and it is not easy to cut off the voltage compared to AC transmission.

However, in recent years, the development of DC circuit breakers is increasing in order to actively utilize the advantages of DC power transmission. Accordingly, the current capacity increases and the rated voltage of the circuit breaker is also increased and diversified.

A DC circuit breaker, like an AC circuit breaker, is tripped when an overcurrent or instantaneous current occurs. The circuit breaker and the line are protected by blocking the power provided to the load side by the blocking operation.

An example of a trip device of a DC circuit breaker according to the prior art is shown in FIGS. 1 to 2 . 1 is a front view and FIG. 2 is a side view.

A conventional DC circuit breaker has a substantially hexahedral stator (1), a mover cylinder (4) installed through the stator (1), and a mover rod (3) inserted to be movable up and down in the mover cylinder (4). ), the mover block 2 coupled to the lower end of the mover rod 3 and separated or contacted with the stator 1, and a latch pressing member having one end coupled to the mover block 2 and the other end extending downward ( 7) is included.

A hollow part is formed in the center of the stator 1, and a triangular cutout is formed in a portion where the mover block 2 is disposed. The mover block 2 is formed as a hexahedron having a trapezoidal cross section corresponding to this cutout. The stator 1 and the mover block 2 are made of a core (iron core) in which a plurality of iron plates are overlapped so that magnetic induction is good.

When an overcurrent occurs in the circuit, the mover block 2 is attracted to the stator 1 by the electromagnetic force generated between the stator 1 and the mover block 2, and the latch provided in the mover block 2 is pressed. When member 7 depresses a latch (not shown) to release the restraint, the trip device is actuated to trip the circuit.

On the other hand, a gap adjusting nut 5 is provided at the lower end of the mover block 2 to adjust the gap between the stator 1 and the mover block 2, and the mover block 2 and the latch pressing member ( 7) is provided with a gap maintaining spring (8) between them.

However, in such a gap control method using a nut and a spring, a chattering phenomenon may occur in which the mover block 2 shakes along the flow of the gap maintaining spring 8 during trip operation. As a result, the trip operation may become unstable.

In addition, the gap is visually adjusted through a scale, etc., which may cause a deviation of the gap depending on the user.

In addition, in the case of repeated tripping, the gap adjusting nut 5 is loosened as the latch pressing member 7 or the mover block 2 moves up and down due to spring elasticity due to the impact, so that the trip operation is performed as desired. may not support

Regarding the trip device of the DC circuit breaker, Korean Patent Application No. 10-2019-0040649 “DC Circuit Breaker with Improved Trip Device” and Korean Patent Application No. 10-2019-0038004 “Circuit Breaker” filed by the present applicant can refer to

The present invention has been devised to solve the above problems, and an object of the present invention is to provide a trip device for a DC circuit breaker capable of maintaining a constant gap between a mover and a stator even during repeated trip operations.

Another object of the present invention is to provide a trip device for a DC circuit breaker that minimizes a gap deviation according to a user.

A trip device for a DC circuit breaker according to an embodiment of the present invention includes a trip stator; a mover rod installed through the trip stator to move up and down; a mover block contacting or separated from a fixed contact portion of the trip stator while sliding along the mover rod; a gap adjusting member coupled to the lower end of the mover rod to move the mover block while vertically moving along the mover rod; and a fixing pin connecting the mover block and the gap adjusting member to move the mover block and the gap adjusting member together.

Here, the gap adjusting member may be screwed to the mover rod.

In addition, the mover block may have longitudinal through-holes formed in the vertical direction, and the gap adjusting member may be partially inserted into the longitudinal axis through-holes.

In addition, a first fixing hole is formed in the mover block in the front-rear direction and into which the fixing pin is inserted, and a second fixing hole is formed in the lower part of the first fixing hole by passing in the front-rear direction and into which the adjustment pin is inserted. can

In addition, the first fixing hole and the second fixing hole may be provided as a pair symmetrical with respect to the longitudinal axis through hole.

In addition, an interval between the pair of first fixing holes may be narrower than a spacing between the pair of second fixing holes.

In addition, an operation groove is formed in the mover rod to have a predetermined length along the longitudinal direction, and the control pin can slide along the operation groove.

In addition, the operation groove may be provided as a pair provided on both sides of the mover rod, respectively.

In addition, the interval between the pair of first fixing holes may correspond to the interval between the pair of operating grooves.

In addition, a circumferential circumferential groove may be formed at an upper portion of the gap adjusting member, and the circumferential circumferential groove may communicate with the second fixing hole.

In addition, one side of the fixing pin may be in contact with the circumferential groove.

In addition, the lower portion of the gap adjusting member may be formed with a corner for applying the rotary tool.

According to the trip device for a DC circuit breaker according to an embodiment of the present invention, since the mover block is fixed to the mover rod by a pin and moves integrally, the chattering phenomenon of the mover block does not occur.

In addition, an operation groove is formed in the cylinder and a first fixing hole is formed in the mover block, and the adjustment pin fixed to the first fixing hole slides along the operation groove to adjust the gap, so that the position of the mover block is set to the upper or lower limit. Since it can be set at a certain point, there is no dispersion for each worker and a unified product is provided. Accordingly, the gap between the contacts is kept constant.

In addition, since the gap between the contacts can be adjusted within the operating groove range, the rated current capacity can be set within a certain range. That is, it can be applied to products with different rated capacities within a certain range.

1 and 2 are a front view and a side view of a trip device of a DC circuit breaker according to the prior art.
3 is an internal structural diagram of a DC circuit breaker according to an embodiment of the present invention.
4 to 6 are a perspective view, a front cross-sectional view, and a side cross-sectional view of a trip device for a DC circuit breaker according to an embodiment of the present invention.
7 and 8 are exploded perspective views of a trip device for a DC circuit breaker according to an embodiment of the present invention.
9 is a trip operation diagram of a trip device for a DC circuit breaker according to an embodiment of the present invention.
10 is a diagram illustrating a gap control operation of a trip device for a DC circuit breaker according to an embodiment of the present invention.

Hereinafter, a preferred embodiment of the present invention will be described with reference to the accompanying drawings, which is intended to be described in detail enough to enable a person of ordinary skill in the art to easily practice the invention, thereby It does not mean that the technical spirit and scope of the invention are limited.

A trip device for a DC circuit breaker according to each embodiment of the present invention will be described in detail with reference to the drawings.

3 is an internal structural diagram of a DC circuit breaker according to an embodiment of the present invention, and FIGS. 4 to 6 are a perspective view, a front cross-sectional view, and a side cross-sectional view of a trip device for a DC circuit breaker according to an embodiment of the present invention. Here, FIGS. 5 and 6 are cross-sectional views taken along lines A-A and B-B in FIG. 4 .

A trip device for a DC circuit breaker according to an embodiment of the present invention includes a trip stator 110; a mover rod 121 that is installed through the trip stator 110 and moves up and down; a mover block 130 contacting or separated from the fixed contact portion 115 of the trip stator 110 while sliding along the mover rod 121; a gap adjusting member 180 coupled to the lower end of the mover rod 121 to move the mover block 130 while vertically moving along the mover rod 121; and a fixing pin 175 for connecting the mover block 130 and the gap adjusting member 180 to move the mover block 130 and the gap adjusting member 180 integrally.

The enclosure 10 may be formed in a box shape. The enclosure 10 may be formed of an insulating material. Components are accommodated and mounted inside the enclosure 10 . These components include trip devices, switching devices, and extinguishing devices.

The opening/closing device is a mechanism for operating the fixed contact 30 and the movable contact 41 . The opening/closing device is driven to operate between a closed position in which the movable contact 41 contacts the fixed contact 30 and an open position in which the movable contact 41 is separated from the fixed contact 30 . The opening/closing device may include a fixing mechanism 15 , an input mechanism 50 , a movable part 40 , and fixing parts 30 and 32 , and the like.

A trip device is a mechanism that detects when a pre-current such as an overcurrent or a short-circuit current flows in the circuit, and drives the switchgear to operate the circuit in the open position.

The arc extinguishing mechanism (not shown) is configured by stacking a plurality of grids on top of the movable contact 42 and the fixed contact 32 , and is operated during operation to the open position while energized (eg trip operation or manual off operation) It is a mechanism that quickly extinguishes the arc generated between the contact and the fixed contact. Arc runners 34 and 44 are provided in the contact part to guide the arc to the arc extinguishing part.

In a normal operating state, the movable contactor 41 is contacted or separated from the fixed contactor 30 by the opening/closing device, and when an accident current occurs, the movable contactor 41 is separated from the fixed contactor 30 by the trip device.

The configuration of the present invention will be described in more detail.

3, the DC circuit breaker according to an embodiment of the present invention includes an upper terminal 20 and a lower terminal 25, a fixed contactor 30 electrically connected to the upper terminal 20, and a lower A movable contact 41 electrically connected to the terminal 25 and contacted or separated from the fixed contact 30 by rotational movement, and an input mechanism 50 for operating the movable contact 41 are provided. On the other hand, a trip device 100 for an automatic trip when an overcurrent occurs between the movable part 40 and the lower terminal 20 is provided.

The fixed contact 30 is provided with a fixed contact 32 , and the movable contact 41 is provided with a movable contact 42 . A latch pin 43 is provided on the movable contactor 41 , and the latch member 45 of the input mechanism 50 is caught by the latch pin 43 to fix the movable contactor 41 . That is, the movable contact 41 maintains a state in which the movable contact 42 is in contact with the fixed contact 32 in a fixed state. When the fixing force of the input mechanism 50 is removed, the movable contact 41 is rotated by the opening/closing spring 49 to separate the movable contact 42 from the fixed contact 32 .

3 to 8, the trip device 100 according to an embodiment of the present invention includes a trip stator 110 fixed to a DC circuit breaker, and a trip mover coupled to the trip stator 110 ( 120) and a latch release block 160 that moves up and down by the trip mover 120.

The trip device 100 presses one end of the locking member 47 installed under the latch member 45 during the trip operation, so that the other end of the locking member 47 pushes the latch member 45 of the input mechanism 50 . Lift it up so that it is released from the latch pin (43). Accordingly, the movable contact 41 is released from the restraint of the latch member 45 and is separated from the fixed contact 30 while rotating and the circuit is cut off.

The trip stator 110 has a 'ㅁ' shape, and a substantially rectangular hollow 112 is formed in the center. In addition, the trip stator 110 may have a predetermined thickness and may be provided by stacking a plurality of iron plates. That is, it is made of a magnetic material and is formed in the form of a magnetic core (iron core) to be advantageous in forming a magnetic path. The mover rod 121 is inserted through the upper portion of the trip stator 110 .

A fixed contact part 115 cut in an inverted triangle shape is formed at a lower portion of the trip stator 110 . A step is formed in the fixed contact portion 115 to form a stator stepped portion 117 in which movement of the mover block 130 is restricted.

The trip mover 120 may also be referred to as a mover assembly. The trip mover 120 includes a mover rod 121 for power transmission, a mover block 130 coupled to the mover rod 121 to contact or separate the trip stator 110 while moving together, and a latch member. Includes a latch release block 160 for releasing the constraint of (45).

The mover rod 121 is inserted into the cylinder 151 and coupled to the mover block 130 to serve as a shaft during lifting. The mover rod 121 is installed to pass through the trip stator 110 . The mover rod 121 is inserted and installed in the cylinder 151 , and the flange portion 123 of the mover rod 121 moves up and down in the cylinder 151 . The mover block 130 is coupled to the lower end of the mover rod 121 .

The upper rod 122 of the mover rod 121 is disposed through the upper block of the trip stator 110 . The upper rod 122 of the mover rod 121 is disposed in the cylinder 150 . A fastening member 148 is coupled to the upper end of the upper rod 122 to support the cylinder cap 143 .

The intermediate rod 125 of the mover rod 121 is formed to be thicker (with a larger diameter in cross section) than the other portions (the upper rod and the lower rod). Some of the intermediate rods 125 of the mover rod 121 are disposed inside the cylinder 150 , and some are exposed outside the cylinder 150 .

At the upper end of the intermediate rod 125 of the mover rod 121 (the portion where the intermediate rod meets the upper rod), a flange portion 123 that can come into contact with the return spring 140 is formed to protrude in a ring shape. The flange portion 123 is disposed in the cylinder 150 . The flange portion 123 prevents the mover rod 121 from leaving the cylinder 150 when descending.

A latch release block 160 is coupled to the intermediate rod 125 of the mover rod 121 . The latch release block 160 may be coupled to the intermediate rod 125 in a pin coupling manner.

The intermediate rod 125 of the mover rod 121 is provided with an operating groove 127, which is a space in which the adjusting pin 170 is mounted and slidably movable, in a predetermined length along the longitudinal direction. The operation groove 127 is formed on the outer surface (both sides) of the intermediate rod 125 .

Although not separately shown, a thread may be formed on some of the lower rods 128 of the mover rod 121 . The gap adjusting member 180 is movable in the vertical direction while rotating along the screw thread.

A cylinder 150 is provided. The cylinder 150 provides a space for the mover rod 121 to move away from the trip stator 110 . The cylinder 150 provides a space in which the return spring 140 can be accommodated and operated.

The cylinder 150 is provided with a flange 151 at its upper end, and is installed and fixed in such a way that it rests on the upper portion of the trip stator 110 .

A locking groove 153 in contact with the fixing member 114 to be fixed to the trip stator 110 is formed in the middle portion of the cylinder 150 . The locking grooves 153 may be provided as a symmetrical pair. That is, the locking grooves 153 may be respectively formed on both sides of the cylinder 150 .

The cylinder 150 is provided with an accommodating part 155 formed as an accommodating groove along the axial direction therein.

In the cylinder 150, an insertion groove 157 extending to the top is formed on the side surface.

Two steps are formed inside the cylinder 151 . Between the upper end of the cylinder 151 and the upper first step (unsigned) is a space in which the cylinder cap 143 operates. A second step (unsigned) of the lower portion of the cylinder 151 supports the lower end of the return spring 140 . That is, the return spring 140 is installed while resting on the second step inside the cylinder 151 .

A cylinder cap 143 is provided. The cylinder cap 143 supports the upper end of the return spring 140 . The cylinder cap 143 has a through hole 144 in its upper end into which the upper rod 122 of the mover rod 121 can be inserted, and the lower end 145 is opened.

An insertion protrusion 146 inserted into the insertion groove 157 of the cylinder 150 is protruded from the side surface of the cylinder cap 143 .

When the mover assembly is lowered, the cylinder cap 143 is lowered while compressing the return spring 140 .

The return spring 140 is installed inside the cylinder 151 . The return spring 140 has a lower end supported on the second step inside the cylinder 151 , and an upper end supported on the cylinder cap 143 . As the lower end of the return spring 140 is compressed by the cylinder cap 143 in a state where the lower end is supported by the second step of the cylinder 151 and fixed, the restoring force is stored.

When the magnetic force acting on the mover block 130 to contact the trip stator 110 is released, the return spring 140 returns the mover assembly, mainly the mover rod 121 and the mover block 130 to their original positions. Provides resilience to return.

The mover block 130 is positioned in a cutout (fixed contact part) formed in the lower block of the trip stator 110 . When the mover block 130 comes into contact with the fixed contact portion 115 of the trip stator 110 , it is integrated with the trip stator 110 to form a magnetic path. From another point of view, it may be seen that a cut portion corresponding to the shape of the mover block 130 is formed in the lower block of the trip stator 110 .

The mover block 130 may be formed as a hexahedron having a trapezoidal cross-section. The mover block 130 is disposed on the fixed contact portion 115 of the trip stator 110 to contact or separate the trip stator 110 .

Both sides of the mover block 130 have inclined portions 131 , respectively. A mover stepped portion 133 is formed in the middle of the inclined portion 131 to be in close contact with the stator stepped portion 117 of the trip stator 110 . When the mover stepped portion 133 of the mover block 130 comes into contact with the stator stepped portion 117 of the trip stator 110 , the movement is restricted.

The mover block 130 has longitudinal axis through-holes 135 formed in the vertical direction. The lower rod 128 and the gap adjusting member 180 of the mover rod 121 are inserted into the longitudinal axis through-hole 135 .

A first fixing hole 137 and a second fixing hole 139 are formed in the mover block 130 in the front-rear direction. Based on the vertical direction, the first fixing hole 137 is formed above the second fixing hole 139 . The first fixing hole 137 and the second fixing hole 139 may be configured as a pair symmetrical with respect to the longitudinal axis. In this case, the interval between the pair of first fixing holes 137 may be narrower than the interval between the pair of second fixing holes 139 . A spacing between the pair of first fixing holes 137 may correspond to a spacing between the pair of operating grooves 127 . The adjustment pin 170 is inserted into the first fixing hole 137 , and the fixing pin 175 is inserted into the second fixing hole 139 .

The latch release block 160 is coupled to the intermediate rod 125 of the mover rod 121 and is located below the cylinder 150 .

An insertion hole 161 into which the intermediate rod 125 of the mover rod 121 can be inserted is formed in the latch release block 160 .

The latch release block 160 has a bar shape having a predetermined thickness. The latch release block 160 is bent in a 'L' shape. A downwardly bent portion of the latch release block 160 is defined as a pressing part 163 . The pressing unit 163 may be configured as a separate part from the latch release block 160 .

The pressing part 163 presses the engaging member 47 when the mover rod 121 descends. When the locking member 47 descends, the restraint on the latch member 45 is released.

A gap adjusting member 180 is provided. The gap adjusting member 180 has a rod through hole 181 formed along the longitudinal axis. The lower rod 128 of the mover rod 121 is inserted into the rod through hole 181 . The gap adjusting member 180 may slide along the lower rod 128 of the mover rod 121 . As an example, the gap adjusting member 180 is screwed to the lower rod 128 and can be raised and lowered while rotating.

A circumferential circumferential groove 183 is formed in the upper portion of the gap adjusting member 180 . The circumferential circumferential groove 183 communicates with the second fixing hole 139 . That is, the interval between the pair of second fixing holes 139 corresponds to the diameter of the circumferential groove 183 .

One side of the fixing pin 175 is in contact with the circumferential groove 183 . That is, the fixing pin 175 is fixed in contact with the circumferential circumferential groove 183 while being inserted into the second fixing hole 139 . Accordingly, when the gap adjusting member 180 moves in the vertical direction, the mover block 130 is moved together. That is, the fixing pin 175 is a medium that allows the gap adjusting member 180 and the mover block 130 to move up and down integrally. Accordingly, by moving the gap adjusting member 180 in the vertical direction, the mover block 130 can be moved in the vertical direction.

A corner portion (eg, a hexagonal portion) 185 for applying a rotary tool is formed at a lower portion of the gap adjusting member 180 .

Since the gap adjusting member 180 is screw-coupled to the lower rod 128 of the mover rod 121 , when the gap adjusting member 180 is rotated, it moves up and down along the mover rod 121 .

A space of a predetermined distance is formed between the upper end of the gap adjusting member 180 and the intermediate rod 125 of the mover rod 121 . Therefore, the gap adjusting member 180 is not limited by the intermediate rod 125 when moving. In other words, an operating space (a black portion between the gap adjusting member and the intermediate rod in FIG. 5 ) is provided so that the gap adjusting member 180 does not collide with the intermediate rod 125 while moving up and down.

The operation of the trip device of the DC circuit breaker according to an embodiment of the present invention will be described as follows.

When an overcurrent occurs in the circuit in the trip device open state (the circuit is energized) as shown in FIG. 5 , the current is supplied to the trip stator 110 by the external power of the trip stator 110 . The trip stator 110 is magnetized to attract the mover block 130 made of a magnetic material. That is, the trip stator 110 serves as an electromagnet. When the latch release block 160 coupled to the mover block 130 descends while the pressing part 163 presses one end of the locking member 47 and the locking member 47 rotates, the latch member 45 becomes the locking member ( 47) and rises with the power of the other end. The latch member 45 is released from the latch pin 43 , and the movable contact 41 is released from restraint and separated from the fixed contact 30 , thereby opening the circuit. That is, the circuit becomes open while the trip device is in a closed state. As the trip device is closed, a restoring force is stored in the return spring 140 . The trip device is in a state as shown in FIG. 9 .

When the fault current processing is completed and the external power supply to the trip device is cut off, the magnetic force of the trip stator 110 disappears and the force that attracts the mover block 130 is removed. The mover block 130 and the mover rod 121 rise to their original positions by the restoring force of the return spring 140 . That is, the trip device is in the open state of FIG. 5 .

The operation of adjusting the gap of the trip device of the DC circuit breaker according to an embodiment of the present invention will be described as follows. Reference may be made mainly to FIGS. 5 and 10 .

5 is a state in which the adjustment pin 170 is positioned at the lower limit of the operation groove 127 . In this case, in the open state of the trip device, the mover block 130 and the fixed contact part 115 are the closest.

The user rotates each part 185 of the gap adjusting member 180 using a tool so that the gap adjusting member 180 rises along the thread of the lower rod 128 . Since the mover block 130 moves together with the gap adjusting member 180 by the fixing pin 175 , it rises together with the rise of the gap adjusting member 180 . Here, when the gap adjusting member 180 rotates, the fixing pin 175 slides along the circumferential circumferential groove 183 . That is, the force in the rotational direction of the gap adjusting member 180 is lost by sliding between the fixing pin 175 and the circumferential groove 183, and only the vertical force of the gap adjusting member 180 is the mover block 130. is transmitted to

As the mover block 130 rises, the adjusting pin 170 coupled to the first fixing hole 137 of the mover block 130 also slides along the operating groove 127 and rises. When the adjustment pin 170 contacts the upper limit of the operation groove 127 , the rise of the mover block 130 is limited. In this case, in the open state of the trip device, the mover block 130 and the fixed contact part 115 are at the furthest distance. The user can easily set the position of the mover block 130 by the upper limit point and the lower limit point without looking at it with the naked eye. In FIG. 10 , the movement distance 'd' of the upper end of the mover block 130 corresponds to the distance between the upper limit point and the lower limit point in the operation groove 127 .

Of course, the mover block 130 may be arranged at any position between the upper and lower limits of the operation groove 127 .

According to the trip device for a DC circuit breaker according to an embodiment of the present invention, since the mover block is fixed to the mover rod by a pin and moves integrally, the chattering phenomenon of the mover block does not occur.

In addition, an operation groove is formed in the cylinder and a first fixing hole is formed in the mover block, so that the adjustment pin fixed to the first fixing hole slides along the operation groove to adjust the gap, so that the position of the mover block is set to the upper or lower limit. Since it can be set at a certain point, there is no dispersion for each worker and a unified product is provided. Accordingly, the gap between the contacts is kept constant.

In addition, since the gap between the contacts can be adjusted within the operating groove range, the rated current capacity can be set within a certain range. That is, it can be applied to products with different rated capacities within a certain range.

The embodiments described above are embodiments for implementing the present invention, and various modifications and variations may be made by those of ordinary skill in the art to which the present invention pertains without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments. That is, the protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent range should be interpreted as being included in the scope of the present invention.

10 Enclosure 20 Upper Terminal
25 lower terminal 30 fixed contact
32 fixed contact 34,44 arc runner
40 movable part 41 movable contactor
42 Movable contact 43 Latch pin
45 Latch member 47 Lock member
49 Opening/closing spring 50 Closing mechanism
100 trip device 110 stator
112 hollow 114 fixing member
115 Fixed contact part 117 Stator stepped part
120 trip mover 121 mover load
122 Upper rod 123 Flange part
125 Intermediate rod 127 Operating groove
128 lower rod 130 mover block
131 Inclined part 133 Mover stepped part
135 Longitudinal shaft through hole 137 First fixing hole
139 Second fixing hole 140 Return spring
143 Cylinder Cap 144 Through Hole
145 Lower part 146 Insertion protrusion
148 Fastening member 150 Cylinder
151 Flange 153 Locking Groove
155 Receptacle 157 Insertion Groove
160 Latch release block 161 Insertion hole
163 Pressing unit 170 Adjustment pin
175 Fixing pin 180 Gap adjusting member
181 Rod through hole 183 Circumferential groove

Claims (12)

trip stator;
a mover rod installed through the trip stator to move up and down;
a mover block contacting or separated from a fixed contact portion of the trip stator while sliding along the mover rod;
a gap adjusting member coupled to the lower end of the mover rod to move the mover block while vertically moving along the mover rod; and
and a fixing pin connecting the mover block and the gap adjusting member to move the mover block and the gap adjusting member together. The trip device of claim 1, wherein the gap adjusting member is screw-coupled to the mover rod. The trip device of claim 1, wherein the mover block has vertical through-holes formed in the vertical direction, and the gap adjusting member is partially inserted into the vertical axis through-holes. [4] The second fixing hole of claim 3, wherein a first fixing hole is formed in the mover block in the front-rear direction and into which the fixing pin is inserted. A trip device for a DC circuit breaker in which a hole is formed. 5. The trip device of claim 4, wherein the first fixing hole and the second fixing hole are provided as a pair symmetrical with respect to the vertical axis through hole. The trip device of claim 5, wherein a distance between the pair of first fixing holes is narrower than an interval between the pair of second fixing holes. [Claim 6] The trip device of claim 5, wherein an operation groove is formed in the mover rod to have a predetermined length along the longitudinal direction, and the control pin slides along the operation groove. [8] The trip device of claim 7, wherein the operation grooves are provided as a pair provided on both sides of the mover rod, respectively. The trip device of claim 8, wherein a distance between the pair of first fixing holes corresponds to a distance between the pair of operating grooves. [Claim 5] The trip device of claim 4, wherein a circumferential circumferential groove is formed at an upper portion of the gap adjusting member, and the circumferential circumferential groove communicates with the second fixing hole. The tripping device of claim 10, wherein one side of the fixing pin is in contact with the circumferential groove. [Claim 2] The tripping device of a DC circuit breaker according to claim 1, wherein each part for applying a rotary tool is formed under the gap adjusting member.

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