JPH0628763Y2 - Thermal overcurrent relay - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial application] The present invention relates to a structure of a contact operation mechanism portion of a thermal dynamic overcurrent relay for protecting a motor or the like from a burnout accident due to overload.

[Prior Art] FIGS. 11 to 17 show a conventional thermal type overcurrent relay. FIG. 11 is a front view when a cover (2) is removed, and FIG. 13 is a sectional view taken along the line A-A of FIG. 11, FIG. 13 is a sectional view taken along the line BB of FIG. 11 taken along the line BB, and FIG. 15 is a movable contactor, FIG. 16 is an operating lever, and FIG. 17 is a perspective view of a main part of a reversing mechanism, taken along the line C-C when cut along a cutting line C-C.

In the figure, (1) is a case and (2) is a cover.
(3) is a bimetal provided for each phase, around which a heater (4) that generates heat when a main circuit current flows is wound and is heated by the heater (4), and is indicated by a broken line in FIG. It will be deformed like a curve. The load side main circuit terminal (5) has the upper end of the bimetal (3) joined and fixed to the tongue portion (5a) thereof. Further, the load side main circuit terminal (5) is fixed to the case (1) by a tightening screw (6), and one end (5b) thereof has a terminal screw (7) for connecting the load side main circuit (external circuit). ) Is screwed on. The lower end (4b) of the heater (4) is electrically connected to the lower end of the bimetal (3) by means such as welding.

The main circuit terminal (40) on the power source side is, as shown in FIG.
The heater (4) has an upper end (4a) at one end (40a) thereof.
Are electrically connected by means such as welding. Also,
The left end portion (40b) of the power supply side main circuit terminal (40) is screwed to a terminal of a power supply circuit such as an electromagnetic contactor (not shown). The interlocking plate (8) contacts the tip of the bimetal (3) of each pole and transmits the deformation operation of the bimetal (3). The left end of the interlocking plate (8) shown in FIG. 11 is arranged so as to press the lower end of the temperature compensating bimetal (9). Actuator (10) is temperature-compensated bimetal (9)
The upper end portion of is fixed and is rotatably arranged around the shaft (11).

The shaft (11) is supported by lever supporting members (12) at both ends thereof, as shown in FIG. The lever support member (12) abuts the edge portion (1a) of the case (1) at its L-shaped bent inner corner (12a), and is supported as a fulcrum there, and the first tongue portion (12b) adjusts the adjustment screw. (1
It is pressed against 3). Also, the second tongue (12
In c), a leaf spring (14) receives a biasing force in the leftward direction shown in FIG.

Therefore, by rotating the adjusting knob (15) provided above the adjusting screw (13), the lever supporting member (12) rotates about the edge portion (1a). The shaft (11) attached to the lever support member (12) changes its position in the substantially left-right direction in FIG. 11, and operates in response to the amount of bending of the bimetal (3) that is bent by the current of the heater (4). Adjust the current.

The movable contactor (16) is made of a thin metal plate having elasticity and conductivity, and as shown in FIG. 15, the inner beam portion (16a).
And the outer beam portion (16b), and a U-shaped leaf spring (17) presses and urges between the tip of the inner beam portion (16a) and the outer beam portion (16b). Have been combined. Further, the contact portion (16c) of the movable contactor (16) is
The normally-closed contacts are arranged so as to be in contact with the fixed contact (18) for the normally-closed contacts to form normally-closed contacts. The lower end (16e) of the movable contactor (16) shown in FIG.
6g), the normally closed movable side terminal (19) shown in FIG.
It is fixed by caulking. The normally closed movable side terminal (19) is the first
As shown in FIG. 3, it is fixed to the case (1) by a tightening screw (20).

The inner beam portion (16a) of the movable contactor (16) is inserted through a substantially T-shaped hole (10a) provided at the tip of the actuating lever (10) shown in FIG. Movable contact (1
6) the extended upper end (16) of the outer beam (16b)
f) is a groove (21) provided at the left end of the crossbar (21).
a) is engaged. The crossbar (21) is guided by the case (1) so as to be movable in the left-right direction in FIG.

The normally open fixed contact (24) and the normally open movable contact (25) are made of a metal conductive plate having elasticity and conductivity. The normally open fixed side terminal (22) and the normally open movable side terminal (22) shown in FIG. 23)
Each of them is fixed by crimping. Normally open movable contact (25)
The rear surface (25a) of the upper tip in the change of (1) is arranged in contact with the protruding piece (21g) of the crossbar (21). The reset bar (26) is slidably held by the case (1) and is movable in the vertical direction in FIG. Normally, the reset bar (26) is urged by the return spring (27) at the edge portion (26c) by the elastic force in the upward direction and is stopped at the upper limit stop point. At this time, the lower vertical surface (26d) of the reset bar (26) is in contact with the curved portion (24a) provided on the back surface of the normally open fixed contactor (24). Then, the slope portion (26a) has a reset bar (2
6) The curved portion (24a) is slid and pressed by the downward movement, and the normally open fixed contact (24) is moved rightward in FIG.

When this thermal overcurrent relay is used in the automatic recovery system, the reset bar (26) is pushed downward and the switching plate (30) is moved leftward in FIG.
0) is inserted into the locking hole (26b) provided in the reset bar (26), and the fitting protrusion (1) of the case (1) is inserted.
b) and the fitting recess on the bottom surface of the switching plate (30) are set in a fitted state so as to restrain the reset bar (26) from returning upward.

The conventional thermal overcurrent relay thus configured operates as follows.

In FIG. 14, the main circuit current is the main circuit terminal (4
0) passes through the heater (4), the bimetal (3), and is energized to the load side main circuit terminal (5). An electric wire (not shown) is connected to the terminal screw (7) screwed to one end (5b) of the load-side main circuit terminal (5), and the tip of the screw (7) is connected to a load such as an electric motor (not shown). It is connected to the. Therefore, the main circuit current is the same as the load current. And
The Joule heat generated by the heater (4) and the bimetal (3) causes the main circuit current to heat the bimetal (3) and bend it as shown by a broken line in FIG.

When the above-mentioned load is in an overcurrent state, the main circuit current increases, and the curvature of the bimetal (3) shown by the broken line diagram in FIG. 11 becomes even larger. Therefore, the interlocking plate (8) is pressed by the tip of the bimetal (3) and moves leftward in FIG. When the interlocking plate (8) moves to the left, it is pressed by the left end of the interlocking plate (8) and has a substantially T-shaped hole (10a) provided at the tip of the temperature compensating bimetal (9) and the operating lever (10).
The movable contactor (16) is rotated clockwise about the shaft (11) and abuts around a substantially T-shaped hole (10a) provided at the tip of the operating lever (10).
The inner beam portion (16a) is also bent to the right in FIG.

Then, until the dead point determined by the relationship between the direction of the urging force of the U-shaped leaf spring (17) and the spring force of the outer beam portion (16b) of the movable contactor (16) trying to return to the inner side, When the beam (16a) is bent and moved,
The movable contactor (16) makes a sudden turn, and in FIG. 11, the outer beam portion (16b) jumps to the left and the inner beam portion (16a) jumps to the right.

Therefore, the contact between the contact portion (16c) and the fixed contact (18) for the normally closed contact opens the normally closed contact that has been kept in electrical conduction, and is in the cutoff state.

Further, the crossbar (21) is pulled by the upper end portion (16f) of the outer beam portion (16b) and moves to the left side in FIG. 11, and the protruding piece (21g) moves the normally open movable contact (25). Displace to the left. Therefore, the normally-open movable contact (25) comes into contact with the normally-open fixed contact (24) and becomes electrically conductive.

Therefore, by connecting the normally-closed contact in series to the operation coil circuit of the electromagnetic contactor (not shown) that opens and closes the main circuit current, when a load (not shown) such as an electric motor is overloaded. The main circuit can be cut off and protected. An alarm signal of overload can be output by connecting a circuit such as an alarm lamp in series with the normally open contact.

After the main circuit current is cut off and the bimetal (3) returns to its original state, the reset bar (26) shown in FIG. Perform by pushing down. Reset bar (2
6) Manually return spring (27) to the downward direction in FIG.
When pushed down while resisting the elastic force of the slope (26a)
Presses the curved portion (24a) on the back surface of the normally open fixed contact (24) to the right, and the normally open fixed contact (24) is bent to the right in FIG. The normally-open movable contact (25) that is in contact with the normally-open fixed contact (24) is also moved to the right, and the protruding piece (21g) of the crossbar (21) is moved to the normally-open movable contact (25). It is pressed by the back surface (25a) and moves to the right in the figure.

[Problems to be Solved by the Invention] In the conventional thermal overcurrent relay configured and operated as described above, as shown in FIG. 11, the crossbar (21) is movable in the left and right directions. There is. Therefore, when impact or vibration is applied in both directions of arrow P in FIG. 11, the crossbar (21) is moved in the left and right directions of FIG. 11 by the kinetic energy due to the magnitude of the mass and the force received. Therefore, there has been a problem that the contact mechanism that constitutes the normally open contact and the normally closed contact is likely to malfunction.

On the other hand, in Japanese Utility Model Publication No. 3-7480, movements of a plurality of bimetals are transmitted to a reversing mechanism section composed of a toggle mechanism, and a normally-closed contact and a normally-open contact are interlocked by interlocking means composed of a lever which rotates about an axis. Techniques for operating thermal overcurrent relays are disclosed. However, in the technology disclosed in this type of publication, the normally-closed contact is transmitted by an interlocking device that transmits the movements of a plurality of bimetals to a reversing mechanism section that is a toggle mechanism and that rotates about an axis and that is an L-shaped lever. Although the normally open contact is operated in an interlocking manner, nothing is disclosed about the structure of the rotating portion which is rich in impact resistance and vibration resistance.

Therefore, the present invention has been made to solve the above-mentioned problems, and an object thereof is to provide a thermal dynamic overcurrent relay having excellent shock resistance or vibration resistance.

[Means for Solving the Problems] The thermal overcurrent relay according to the present invention transmits the movement of the bimetal, which bends in response to the main circuit current, to the reversing mechanism section including the toggle mechanism so that the position of the center of gravity rotates. In a thermal dynamic overcurrent relay in which a normally-closed contact and a normally-open contact are interlocked by interlocking means composed of a lever that rotates around a shaft that is substantially at the same position as the center of motion, the lever that rotates around the shaft is ,
The center of rotation is approximately the center of gravity, and the arm extends in three directions from the center of rotation. The arm is engaged with the normally-closed movable contact of the normally-closed contact of the first arm, and the normally-open contact of the second arm. This is for engaging with the normally open movable contactor and displaying the tip of the third arm as an operation display.

[Operation] In this invention, the interlocking means for interlocking the normally-closed contact and the normally-open contact is a lever, and the lever is rotated about the axis whose center of gravity is substantially the same as the center of rotation. Since the mass of the lever is balanced against shock or vibration, shock resistance and vibration resistance can be improved. In particular, the lever has a center of rotation as a center of gravity,
It consists of arms extending in three directions from the center of rotation, with the first arm engaging the normally closed movable contact of the normally closed contact and the second arm engaging the normally open movable contact of the normally open contact. Since the tip of the third arm is operated and displayed, the tip of the third arm has an operation display and a manual trip mechanism. However, since the arms extending in three directions are balanced, impact resistance is provided. And vibration resistance can be improved.

[Embodiment] FIGS. 1 to 10 show a thermal dynamic overcurrent relay according to an embodiment of the present invention. FIG. 1 is a front view when a cover (2) is removed, and FIG. 1 is a sectional view taken along the line U-U of FIG. 1, and FIG. 3 is the same as the cutting line V of FIG.
5 is a sectional view taken along the line V-V when cut at -V, FIG. 4 is a sectional view taken along the line W-W of FIG. 1, and a sectional view taken along the line W-W of FIG. 1, and FIG. XX sectional view taken along the line XX, FIG. 6 is a plan view, front view, and left and right side views of the heating element portion, and FIG. 7 is an exploded perspective view of components of the normally-open contact and reset device portion. , FIG. 8 is an exploded perspective view of the components of the normally closed contact and the reversing mechanism part, FIG. 9 is an exploded perspective view of the components showing a perspective view of the first lever and the second lever, and FIG. It is a rear view (the arrow view of the Y direction of FIG. 5) which shows the thermal overcurrent relay of an Example. In the drawings, the same reference numerals and symbols as those in FIGS. 11 to 17 indicate the same or corresponding parts as the constituent parts of the conventional thermal overcurrent relay.

In the figure, the bimetal (3) provided for each phase is
The main circuit current flows and is heated by the heater (4) which generates heat, and is bent and deformed as shown by the broken line in FIG.

The load-side main circuit terminal (5) has an L-shape, and one end (5b) of the L-shape has a load-side main circuit (external circuit).
A terminal screw (7) for connection is screwed, and the other end (5
c) is electrically and mechanically connected to the bimetal support member (5) by means such as welding. The bimetal supporting member (50) is electrically and mechanically joined and fixed to the tongue (50a) of the bimetal (3) by means such as welding.

As shown in FIGS. 5 and 6, the power source side main circuit terminal (40) is electrically connected to one end (40a) of the upper end portion (4a) of the heater (4) by means such as welding. There is. In addition, the left end portion (40) of the power supply side main circuit terminal (40)
b) is screwed to a terminal of a power supply circuit such as an electromagnetic contactor (not shown).

The heater support pair (51) made of a heat resistant resin is
The power source side main circuit terminal (40) is fixed by being held by the first groove portion (51a). Further, the tongue portion (5) of the bimetal support member (50) is formed in the second groove portion (51b).
0a) and the upper end of the bimetal (3) are clamped and fixed together. The heater support pair (51) has a cylindrical pin (51c) formed at the right end thereof inserted through a hole (50c) formed at the upper end of the bimetal support member (50). As shown in FIG. 6, the heater support pair (51) includes main circuit terminals such as a power source side main circuit terminal (40), a bimetal support member (50), a bimetal (3), a heater (4), and heating element peripheral parts. It has the function of connecting and integrating. The heating element portion (52) thus integrated and assembled as shown in FIG. 6 is housed in the case (1). At this time, the pin (51c) of the heater support pair (51)
The tip of the pin (5) is inserted into the hole (1x) of the case (1) shown in FIG. 10 which is a view in the Y direction of FIG.
1c) as a center, the tip of the bimetal (3) is adjusted so as to have the same mutual position in each phase in a freely rotatable state, and then the bimetal support member (50) is tightened with the tightening screw (6) shown in FIG. The lower end (50b) of the is fixed to the case (1). Furthermore, the hole (1y) of the case (1) shown in FIG.
Is filled with an adhesive resin (53) to form between the corner (50d) and the hole (1y) of the bimetal supporting member (50),
Adhesive resin (53) in the space shown by hatching in FIG.
By hardening, the position of the bimetal (3) in the rotation direction in FIG. 1 is completely fixed.

The interlocking plate (8) that transmits the heating bending motion of the bimetal (3) abuts on the tip of the bimetal (3) of each pole, and the temperature compensating bimetal (5) is attached to the left end of the interlocking plate (8) of FIG.
It is arranged so as to press the lower end portion (54c) of 4). The lever support member (55) has a pair of first fulcrums (55a) at its lower part and a pair of second fulcrums (5a) at its upper part.
5b) has been formed. And the normally closed movable contact (5
6) is made of a conductive thin metal plate.

1 formed in the approximate center of the temperature compensating bimetal (54)
The pair of edge portions (54a) is formed on the first fulcrum portion (55a) of the lever supporting member (55), and the pair of edge portions (56a) formed on the lower portion of the normally closed movable contact (56) is formed on the lever supporting member. Holes (54b) abutted on the second fulcrums (55b) of (55) and drilled in the upper portion of the temperature compensating bimetal (54)
A tension coil spring (57) is stretched between the hole (56b) formed in the normally closed movable contact (56).

The lever support member (55) has an L-shaped bent inner corner (5
5c) abuts on the edge portion (1a) of the case (1) and is supported by a fulcrum there, and the first tongue portion (55) thereof is also supported.
The second tongue portion (55e) is configured to receive a biasing force in the left direction in FIG. 1 by the leaf spring (14) by being pressed against and brought into contact with the adjusting screw (13) in (d).

Therefore, by rotating the adjusting knob (15) encapsulated on the adjusting screw (13), the lever supporting member (55) is moved to the edge portion (1) of the case (1) in FIG.
Since the lower end portion (54c) of the temperature compensating bimetal (54) can be moved in the substantially left-right direction in FIG. 1 by performing a pivotal movement around a), the temperature compensating bimetal (54) responds to the bending amount of the bimetal (3). The operating current to be applied can be changed and adjusted.

The normally closed fixed contact (59) made of a thin metal plate having elasticity and conductivity is electrically and mechanically connected and fixed to the normally closed fixed side terminal (58) by means such as caulking at its lower part (59a). There is. In addition, the contact (59
b) is arranged to face the contact (56c) provided on the upper part of the normally-closed movable contactor (56), and the normally-closed contact is constituted by contact and opening of these contacts.

The normally closed fixed side terminal (58) is press-fitted and fixed to the case (1). The normally closed movable side terminal (60) is the case (1)
The tongue portion (60a) of the contact spring (61) attached to the first tongue portion (55d) of the lever supporting member (55) contacts the first spring portion (61a) of the contact spring (61). ing. The contact spring (61) is made of a thin metal plate having elasticity and conductivity, and is a normally closed movable side terminal (60) → contact spring (61) → lever support member (55) → normally closed movable contact (56). Power is being supplied to the movable side of the normally-closed contact via the path.

In FIGS. 1 and 2, the normally open fixed side terminal (22) and the normally open movable side terminal (23) are press-fitted and fixed to the case (1). The normally open fixed and movable contacts of the normally open fixed contactor (24) and the normally open movable contactor (25) are both made of a thin metal plate having elasticity and conductivity, and the normally open fixed side terminal (22). Also, the right end of each of the normally open movable terminals (23) is electrically and mechanically connected and fixed by means such as caulking.

Further, the normally open fixed contact (24) and the normally open movable contact (25) are respectively provided with a contact (24a) and a contact (25a) so as to face each other at substantially left ends thereof. ) And the contact (25a) are contacted and separated to form a normally-open contact. The normally open movable contactor (25) is operated by the first lever (62) which constitutes an interlocking means for interlocking the normally closed contact and the normally open contact.

The first lever (62) is substantially Y-shaped as shown in the perspective view of FIG.
It is shaped like a letter, and is inserted into the protruding shaft (1z) provided in the case (1) by the cylindrical portion (62a) at the center thereof, and is rotatably held. The first lever (62) has a first arm (6) extending in three directions around the cylindrical portion (62a).
2b), a second arm (62c) and a third arm (62d), and the first arm (62b) has its tip divided into two protruding pieces (62e) and protruding pieces (62f). The projecting piece (62e) and the projecting piece (62f) hold the tip portion (56d) of the normally-closed movable contact (56). Also,
The tip of the second arm (62c) is divided into two pieces, a protruding piece (62g) and a protruding piece (62h).
normally open movable contact (25) between g) and the protruding piece (62h)
The tip of is arranged. Also, the tip of the third arm (62d) is bent as shown in FIG.
2j), and this display piece (62j) projects to a position corresponding to the window (1w) of the case (1).

Like the first lever (62), the second lever (63) has a semi-notched cylindrical portion (63a) at its substantially central portion so as to be rotatably held with respect to the protruding shaft (1z) of the case (1). Then
The first arm (63b) extending in two directions around this
And a second arm (63c).

The tip of the first arm (63b) is divided into a protruding piece (63d) and a protruding piece (63e), and the tip (59c) of the normally-closed fixed contactor (59) is sandwiched and arranged in the gap. There is. In addition, the tip (63
f) is arranged to be pressed by a reset bar (64) described later. In addition, the second spring portion (61b) provided on the contact spring (61) is the second lever (6).
The configuration is such that the substantially central portion of the first arm (63b) of 3) is pushed to the left in FIG. The second lever (63) receives a counterclockwise urging force about the protruding shaft (1z),
The stopper portion (1s) of the case (1) abuts on the case (1) and stops.

The reset binder (64) and the switching lever (65) are assembled to the reset bar case (66) and then attached to the case (1). The reset bar (64) has guides (66) on both sides of the reset bar case (66).
a) and a guide (66b) are slidably supported and are vertically movable in FIG.
A return spring (67) is assembled by compressing and urging between a) and a spring receiving portion (66c) provided in the reset bar case (66), and the reset bar (64) is attached to the return spring (67).
Is urged upward by.

Also, the first protrusion (64) at the bottom of the reset bar (64)
b) is arranged to press the upper surface of the normally open fixed contactor (24), and the second protrusion (64c) is to press the tip (63f) of the second arm (63c) of the second lever (63). It is arranged. The switching lever (65) switches the return method after the contact operation of the device from the manual return to the automatic return. Therefore, in the shaft hole (66d) of the reset bar case (66), the front split shaft ( 65a) is fitted and assembled, and the switching lever (65) is centered around this shaft hole.
Rotates. Guide hole (66e) is switch lever (65)
Is a substantially darma hole for fixing the two positions of the manual return position and the automatic return position. And this guide hole (6
The pair of protrusions (65b) of the switching lever (65) is configured to fit into 6e). Note that FIG. 1 shows a state of manual restoration. Further, in the case of automatic return, the switching lever (65) is rotated counterclockwise, and its tip (65c) is configured to push down the upper surface of the normally open fixed contact (59).

Next, the operation of the thermal overcurrent relay according to the embodiment of the present invention will be described.

In FIG. 5, the main circuit current is the main circuit terminal (4
0) passes through the heater (4), the bimetal (3), the bimetal support member (50), and then the load side main circuit terminal (5). An electric wire (not shown) is tightened and connected by a terminal screw (7) screwed to an L-shaped end (5b) of the load side main circuit terminal (5), and the other end is a load of an electric motor (Fig. Connected (not shown). Therefore,
The main circuit current is the same as the current flowing through the load.

The Joule heat generated by the main circuit current flowing through the heater (4) and the bimetal (3) heats the bimetal (3) and bends it as shown by the broken line in FIG. is there.

When the load is overloaded, the main circuit current increases, so that the curve of the bimetal (3) becomes even larger as indicated by the broken line in FIG. ) And is moved to the left in FIG.

Therefore, the temperature compensating bimetal (54) whose lower end (54c) is pressed to the left by the left end of the interlocking plate (8) moves around the first fulcrum (55a) of the lever support member (55). Rotate in the direction. This movement causes the hole (54b) of the temperature compensating bimetal (54) to move to the right side in FIG.
A straight line connecting the hole (54b) of the temperature compensating bimetal and the hole (56b) of the movable contact, that is, in FIG. 1, the axis of the tension coil spring (57) corresponds to the hole (56b) of the normally closed movable contact (56). When the temperature-compensating bimetal (54) rotates to a state (dead point) that exceeds the straight line connecting the second fulcrum portion (55b) of the lever support member (55) to the right, the tensile force of the tension coil spring (57) Changes the direction of the force that urges the normally closed movable contact (56), and the normally closed movable contact (56) moves to the second fulcrum (5) of the lever support member (55).
5b) as a center of rapid clockwise rotation. At this time, the tension coil spring (5
The pulling force of 7) acts as an urging force in the counterclockwise direction about the second fulcrum portion (55b) of the normally closed movable contactor (56), so that the contact point (59b) and the contact point (56c) come into contact with each other. The normally closed stationary contact (59) is pressed to the left in FIG. 1 by the tensile force of the tension coil spring (57), and comes into contact with the protruding piece (63e) of the second lever (63). Stop. That is, the normally closed movable contactor (56) constitutes a toggle mechanism by the tensile force of the tension coil spring (57). When the normally closed movable contactor (56) rapidly rotates clockwise beyond the dead point as described above, the normally closed stationary contactor (59) has its tip (59c) at the second lever (63).
Of the normally-closed movable contact (56) up to the position where the normally-closed movable contactor (56) contacts the protruding piece (63d), and is constrained at the position where the normally-closed movable contactor (56) contacts the protruding piece (63d). Because of the rotation, the contact (56c) is separated from the contact (59b) and the normally closed contact is opened.

Here, the normally closed fixed contact (59) is the second lever (63).
The protruding piece (63e) from the position where it abuts against the protruding piece (63e).
The dimension that follows the normally closed movable contactor (56) until it comes into contact with d) becomes the overtravel dimension of the normally closed contact, which has the effect of improving the contact reliability of the normally closed contact.

As described above, when the normally closed movable contactor (56) rapidly rotates clockwise, the tip (56d) of the normally closed movable contactor (56) causes the protruding piece (62f) to move to the right in FIG. The first lever (62) pressed in the direction rotates counterclockwise about the protruding shaft (1z). Therefore, the normally-open movable contact (25) is deformed by being pressed by the protruding piece (62g) of the first lever (62), and the contact (25b) becomes the contact (24a) of the normally-open fixed contact (24). Abut and close the normally open contact. Since the normally open fixed contact (24) is made of an elastic thin metal plate, it is pushed by the protruding piece (62g) of the first lever (62) even after the contact is closed, and the normally open movable contact is formed. The child (25) is further deformed upward. The normally open fixed contact (24) is the first protrusion (6) of the reset bar (64).
4b) is deformed until it contacts the normally open stationary contactor (24) and the first protrusion (64b) of the reset bar (64).
Deformation stops at the position where it abuts against. At this position, the rotating operation of the normally closed movable contactor (56) and the first lever (62) is also stopped, and the reversing operation (trip) is completed. Contact point (24a)
And the contact (25b) come into contact with each other, and the deformation amount of the normally open fixed contact (24) after the normally open contact is closed (that is, the normally open fixed contact (24) and the reset bar (64 in the initial state of FIG. 1). The gap between the first protrusions in) is the overtravel dimension of the normally open contact, and has the effect of improving the contact reliability of the normally open contact.

Further, the contact (24a) and the contact (25b) slide in the lateral direction in FIG. 1 due to the deformation operation of the normally open fixed contact (24) and the normally open movable contact (25) within this overtravel dimension. The combined operation is performed to remove dust, dust, oxides, etc. on the surface of each contact, and the contact reliability of the normally open contact is improved.

In addition, as described above, when the reversing operation (trip) is completed, the first lever (62) is fully rotated counterclockwise, and therefore the third arm (62d) is also rotated to the left. The display piece (62j) at the tip is visible from the outside through the window (1w) of the case (1) in the initial state of FIG. 1, but after completion of the reversing operation, the wall (1v) of the case (1) is visible. ) Hides and disappears. That is, the display piece (62
When j) is visible from the outside through the window (1w) of the case (1), it is in a non-inverted state (reset state), and when it is not visible, it indicates a reversing operation completed state (trip), and the display piece (62j). Has a function of operation display.

Further, this display piece (62j) also has a function of a test trip operation part in addition to the operation display function. That is, in general, during a test trip to check whether the normally closed and normally open contacts are connected to an external circuit to perform the required operation when an overcurrent relay of this type performs a reversal operation due to an overload, the main circuit Only the contacts can be operated without passing current.

Next, a test trip of the thermal overcurrent relay according to this embodiment will be described.

In the initial state of FIG. 1, the display piece (62j) is artificially moved to the left in FIG. 1 from the outside through the window of the case. This operation causes the first lever (62) to rotate counterclockwise, and this rotation causes the first lever (6) to rotate.
The protruding piece (62e) of 2) presses the tip (56d) of the normally closed movable contactor (56) to the right in FIG. Then, the hole (56b) of the normally closed movable contactor (56) moves until it is located on the right side of the straight line connecting the first fulcrum portion (55a) and the second fulcrum portion (55b) of the lever support member (55). At this time, the force direction of the tension coil spring (57) suddenly changes to the opposite direction, and the normally-closed movable contactor (56) rapidly rotates clockwise. The normally closed movable contactor (56) and the first lever (62) are rotated in the same manner as the above-described reversal operation, and the normally closed movable contactor (56) is reversed (tripped).
To complete.

Then, when the reversing operation is completed, the reset bar (6
4) is manually pushed downward in FIG. 1 against the elastic force of the return spring (67). By this operation, the first protrusion (64b) of the reset bar (64) causes the protruding piece (62g) of the first lever (62) via the normally open fixed contact (24) and the normally open movable contact (25). Will be pushed downward in FIG. As a result, the first lever (62) rotates clockwise around the protrusion shaft (1z) and is pushed by the protrusion piece (62f) to move the normally-closed movable contactor (56) to the left. The normally closed movable contact (56) has a hole (56
b) is the first fulcrum portion (55) of the lever support member (55).
When moved to the left of the straight line connecting a) and the second fulcrum portion (55b), the biasing force of the normally closed movable contact (56) by the tension coil spring (57) changes rapidly from the clockwise direction to the counterclockwise direction. Then, the normally closed movable contactor (56) rapidly becomes the first
Rotate counterclockwise to return to the initial state in the figure. Therefore, the tip (56d) of the normally-closed movable contactor (56) pushes the protruding piece (62e) of the first lever (62), and the first lever (62) rapidly rotates clockwise, as shown in FIG. Returning to the initial state (reset state), the normally open contact is opened and the normally closed contact is closed.

Next, the operation of opening the normally closed contact will be described.

In the initial state of FIG. 1, this is done by pressing the reset bar (64) downward in FIG. When the reset bar (64) is pushed down against the return spring (67), the second protrusion (64c) of the reset bar (64)
Comes into contact with the tip (63f) of the second arm (63c) of the second lever (63) and is pushed down. The second lever (63) has a contact spring (6) centered on the protruding shaft (1z).
It rotates clockwise against the elastic force of the second spring portion (61b) of 1). As a result, the protruding piece (63d) of the second lever (63) causes the tip (59) of the normally closed fixed contactor (59).
Press c) to the left. Therefore, the normally closed fixed contact (5
9) transforms to the left. At this time, the normally closed movable contactor (56)
Also, a position where the first lever (62) can rotate clockwise,
That is, the protruding piece (62g) is the stop piece (1) of the case (1).
Although it follows the normally closed fixed contact (59) up to the position where it abuts t), the tip (56d) of the normally closed movable contact (56) is the protruding piece (1) of the first lever (62) thereafter. 62
The contact (56c) and the contact (59b) are opened without being followed by being abutted against and restrained by e). That is, the normally closed contact is opened. Then, by releasing the manual pressing force of the reset bar (64), the reset bar (6
4) returns to the state shown in FIG. Therefore, the second lever (63) is also released, and the second spring portion (61b) of the contact spring (61) returns to the original state of FIG. 1 by the urging force of the second spring portion (61b).
The normally closed contact is closed.

Like the conventional thermal overcurrent relay, the normally-closed contact is connected in series with the operation coil circuit of the electromagnetic contactor (not shown) that opens and closes the main circuit current, and the normally-open contact is the alarm lamp ( It is used to open and close (not shown).

As described above, the thermal overcurrent relay according to the present embodiment transmits the movement of the bimetal (3) that bends in response to the main circuit current to the reversing mechanism portion including the toggle mechanism, and the interlocking means causes the normally closed contact and In a thermal dynamic overcurrent relay in which a normally-open contact is interlocked, the operation of the reversing mechanism of the one contact, that is, the normally-closed movable contact (56) of the normally-closed contact is performed by the other contact,
That is, the first lever that rotates the interlocking device that transmits the normally open movable contact (25) of the normally open contact centering on the axis of the cylindrical portion (62a) whose center of gravity is substantially the same as the center of rotation. (6
The first lever (62) for transmitting the reversal force of the normally-closed contact to the normally-open contact is pivotally supported by the projecting shaft (1z) of the case (1), and the cylinder of the bearing portion. Division (62
It is composed of a first arm, a second arm, and a third arm extending in three directions centering on a), and the center of gravity thereof is substantially the same as the axial position.
Therefore, in FIG. 1, the first lever (62) does not rotate with respect to vibrations and shocks in all directions, so that vibration resistance and shock resistance are improved.

Further, in comparison with the conventional thermal-type overcurrent relay, in this embodiment, the first lever (62) which rotates about the axis of the cylindrical portion (62a) whose center of gravity position is substantially the same as the rotation center. ) And the frictional resistance during operation is extremely small, the toggle mechanism operates smoothly, the operation speed can be increased, and the reliability can be improved.

And a first lever (62) which rotates about the shaft
Is an arm extending in three directions around the axis of rotation, and is engaged with the normally closed movable contact (56) of the normally closed contact by the first arm (62b) and the second arm (62c). Is engaged with the normally open movable contact (25) of the normally open contact, and the tip of the third arm (62d) is displayed as an operation display. Therefore, the operation display is provided at the tip of the third arm (62d). And a manual trip function, and that part is the top surface of the thermal overcurrent relay (first
Since it appears on the upper side of the figure, there is an advantage that the display is easy to see and operate.

[Effects of the Invention] As described above, the thermal overcurrent relay of the present invention transmits the movement of the bimetal, which bends in response to the main circuit current, to the reversing mechanism section consisting of the toggle mechanism, and the normally closed contact and the normally closed contact. Since the interlocking means for interlocking the open contacts is composed of a lever that rotates about an axis whose center of gravity is substantially the same as the center of rotation, it is possible to prevent vibration and impact in all directions.
Since the lever does not rotate while maintaining a balanced state, vibration resistance and impact resistance can be improved.

Further, as compared with the conventional thermal overcurrent relay, in this embodiment, the center of gravity is composed of a lever that rotates about the axis of the cylindrical portion that is substantially the same as the rotation center, Since the frictional resistance during the operation is remarkably small, the toggle mechanism operates smoothly, the operation speed can be increased, and the reliability can be improved.

The lever that rotates about the axis includes an arm that extends in three directions around the axis that is the center of rotation, and the first arm engages the normally-closed movable contact of the normally-closed contact with the second arm. Since the arm engages the normally-open movable contact of the normally-open contact and the tip of the third arm is displayed as an operation, the tip of the third arm has an operation display and a manual trip function, The effect is that the display is easy to see and operate.

[Brief description of drawings]

1 is a cross-sectional view of the thermal overcurrent relay according to the embodiment of the present invention when the cover is removed, and FIG. 2 is a section line U of FIG.
U-U sectional view when cut by -U, FIG. 3 is a V-V sectional view when cut by cutting line V-V of FIG. 1, and FIG. 4 is cutting line W of FIG. FIG. 5 is a sectional view taken along line WW of FIG.
6 is a cross-sectional view taken along the line X--X of FIG. 6, FIG. 6 is a plan view, a front view, a right and left side view of a heating element portion used in the thermal overcurrent relay according to the embodiment of the present invention, and FIG. FIG. 8 is an exploded perspective view of the components of the normally open contact and the reset device used in the thermal overcurrent relay of the example, and FIG. 8 is a normally closed contact and a reversing mechanism used in the thermal overcurrent relay of the embodiment of the present invention. FIG. 9 is an exploded perspective view of parts of the parts, FIG. 9 is a perspective view of the first lever and the second lever used in the thermal overcurrent relay according to the embodiment of the present invention, and FIG. 10 is a thermal view of the embodiment of the present invention. Fig. 11 is a rear view showing the overcurrent relay, Fig. 11 is a front view when the cover of the conventional thermal overcurrent relay is removed, and Fig. 12 is A when cutting at the cutting line AA in Fig. 11. -A sectional view, 13th
The figure also shows B when cut along the cutting line BB in FIG.
14B is a sectional view taken along line B, and FIG. 14 is a sectional view taken along line CC of FIG.
15 is a perspective view of a movable contact used in a conventional thermal overcurrent relay, and FIG. 16 is a movable lever used in a conventional thermal overcurrent relay. FIG. 17 is a perspective view of the main part of the reversing mechanism used in the conventional thermal overcurrent relay. In the figure, 1 is a case, 1z is a protruding shaft, 3 is a bimetal, 25 is a normally open movable contact, 56 is a normally closed movable contact, 62 is a first lever, and 62a is a cylindrical portion. In the drawings, the same reference numerals and symbols indicate the same or corresponding parts.

Claims (1)

[Scope of utility model registration request] 1. A lever that transmits the movement of a bimetal that bends in response to a main circuit current to a reversing mechanism section that includes a toggle mechanism and that rotates about an axis whose center of gravity is substantially the same as the center of rotation. In the thermal-type overcurrent relay in which the normally-closed contact and the normally-open contact are interlocked by the interlocking means, the lever that rotates about the shaft has a rotation center at a substantially center of gravity, and three directions from the rotation center. It consists of an arm that extends to
The first arm engages the normally-closed movable contact of the normally-closed contact, the second arm engages the normally-open movable contact of the normally-open contact, and the tip of the third arm serves as an operation display. Thermal overcurrent relay characterized by.