KR20240059150A - Thermal relay - Google Patents

Abstract

The thermal overload relay according to the present invention consists of a base part 10 on which the main bimetal is installed, and a trip part 30 installed on the upper part of the base part, and the trip part 30 includes a trip assembly 300 and , Consisting of a front cover (F-CV) and a rear cover (R-CV) coupled at the front and rear of the trip assembly,
The trip assembly 300 includes a temperature compensation bimetal 310, a pressure lever 320 coupled to the temperature compensation bimetal, a reversal mechanism 330 that elastically deforms according to the pressure of the pressure lever, and a deformation of the reversal mechanism. It includes an interlocking lever 340 that follows and an adjustment shaft 350 installed on the lower side of the inversion mechanism,
The inversion mechanism 330 consists of left and right plates 331, a center plate 332 provided between the left and right plates, and a spring 333 coupled to the center plate,
The adjustment shaft 350 includes a central portion 351, an eccentric portion 352 installed on the left and right sides of the central portion, an adjustment protrusion 353 protruding from the left eccentric portion, and an adjustment protrusion formed on the outer peripheral surface of the adjustment protrusion. It consists of an uneven part 354, a stopper 355 formed on the outer peripheral surface of the adjustment protrusion and installed on both ends of the uneven part, and a fixing table 356 protruding from the right eccentric part, and the left and right eccentric parts of the adjustment shaft ( 352) is configured to support the left and right plates 331 of the inversion mechanism, respectively.
In addition, the rear cover (R-CV) is provided with a coupling groove (RH), the front cover (F-CV) is provided with a through hole (FH), and the fixture 356 of the adjustment shaft is connected to the rear cover (R). -CV) is inserted into the coupling groove (RH), and the adjustment protrusion 353 of the adjustment shaft is inserted into the through hole (FH) of the front cover (F-CV).

Description

Thermal overload relay{THERMAL RELAY}

The present invention relates to a thermal overload relay, and more specifically, to a thermal overload relay that can prevent malfunction due to a trip load of a lever applied to a reversing mechanism.

If overcurrent occurs in an electrical device, the power must be turned off quickly to protect the electrical device. An overload relay can prevent damage to electrical devices by cutting off power in the event of overcurrent.

Thermal relay, one of the overload relays, uses thermal deformation of bimetal to cut off power. The thermal relay has a structure in which the bimetal is bent during overcurrent, and the thermally deformed bimetal operates a reversal mechanism to block the circuit.

Bimetals that operate by heat can be affected by temperature changes in the external environment. For example, in hot summer, it may trip within the allowable current range, and in cold winter, it may not trip in overcurrent condition. To prevent such malfunctions, the operating timing is supplemented by combining a bimetal with a temperature compensation bimetal.

Another cause of malfunction may be the tripping load of the reversing mechanism. The reversing mechanism is made of elastic material, but a tripping error may occur due to a defect in the trip load due to the gap between the reversing mechanism and the lever being exceeded.

Publication of Patent No. 10-2013-0096080, Trip device assembly having an adjustment axis Registered Patent Publication No. 10-1276923, thermal overload relay Publication of Patent No. 10-2009-0045790, thermal overload relay Registered Patent Publication No. 10-0937234, thermal overload relay Registered Utility Model Publication No. 20-0411527, thermal overload relay

The purpose of the present invention is to provide a thermal relay that can prevent malfunction by correcting the thermal deformation length of the bimetal due to external temperature changes.

In addition, the purpose of the present invention is to provide a thermal relay that can prevent trip errors by adjusting the elastic force of the reversing mechanism.

The problems to be solved by the present invention are not limited to the problems mentioned. Other technical problems not mentioned will be clearly understood by those skilled in the art from the following description.

The thermal overload relay according to the present invention consists of a base part 10 on which the main bimetal is installed, and a trip part 30 installed on the upper part of the base part, and the trip part 30 includes a trip assembly 300 and , Consisting of a front cover (F-CV) and a rear cover (R-CV) coupled at the front and rear of the trip assembly,

The trip assembly 300 includes a temperature compensation bimetal 310, a pressure lever 320 coupled to the temperature compensation bimetal, a reversal mechanism 330 that elastically deforms according to the pressure of the pressure lever, and a deformation of the reversal mechanism. It includes an interlocking lever 340 that follows and an adjustment shaft 350 installed on the lower side of the reversal mechanism,

The inversion mechanism 330 consists of left and right plates 331, a center plate 332 provided between the left and right plates, and a spring 333 coupled to the center plate,

The adjustment shaft 350 includes a central portion 351, an eccentric portion 352 installed on the left and right sides of the central portion, an adjustment protrusion 353 protruding from the left eccentric portion, and an adjustment protrusion formed on the outer peripheral surface of the adjustment protrusion. It consists of an uneven portion 354, a stopper 355 formed on the outer peripheral surface of the adjustment protrusion and installed on both ends of the uneven portion, and a fixing table 356 protruding from the right eccentric portion, and the left and right eccentric portions of the adjustment shaft ( 352) is configured to support the left and right plates 331 of the inversion mechanism, respectively.

In addition, the rear cover (R-CV) is provided with a coupling groove (RH), the front cover (F-CV) is provided with a through hole (FH), and the fixture 356 of the adjustment shaft is connected to the rear cover (R). -CV) is inserted into the coupling groove (RH), and the adjustment protrusion 353 of the adjustment shaft is inserted into the through hole (FH) of the front cover (F-CV).

In addition, a straight groove or a cross groove is formed on the end surface of the adjustment protrusion 353, and the end surface of the adjustment protrusion 353 of the adjustment shaft is exposed through the through hole (FH) of the front cover (F-CV). And, the operator adjusts the trip load by rotating the straight groove or cross groove using a driver tool.

In addition, the central portion 351 of the adjusting shaft 350 has a smaller outer diameter than the eccentric portion 352, so that when the pressing lever 320 presses the central plate 332 of the reversing mechanism 330, the adjusting shaft ( It is configured so as not to interfere with the central portion 351 of 350).

According to the present invention, the fixture 356 of the adjustment shaft is inserted into the coupling groove (RH) of the rear cover (R-CV), and the adjustment protrusion 353 of the adjustment shaft is inserted into the through hole (FH) of the front cover (F-CV). is installed in Support is provided on both sides of the adjustment shaft to prevent movement of the adjustment shaft and enable fine adjustment.

1 is a perspective view of a thermal overload relay according to the present invention.
Figure 2 is a front view of a thermal overload relay according to the present invention.
Figure 3 is an exploded perspective view of the trip unit according to the present invention.
Figure 4 shows the main components of the trip unit according to the present invention.
Figure 5 shows a reversal mechanism and an adjustment axis according to the present invention.
Figure 6 shows the change in support of the inversion mechanism according to the rotation of the adjustment shaft.
Figures 7 and 8 are views showing the coupling position of the adjustment shaft in the cover according to the present invention.
Figure 9 shows the front cover of the thermal overload relay according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the attached drawings. For convenience of explanation, components shown in the drawings may be exaggerated, omitted, or schematically represented.

Figure 1 is a perspective view of a thermal overload relay according to the present invention, and Figure 2 is a front view of the thermal overload relay according to the present invention.

The thermal relay according to the present invention consists of a base unit 10 on which the main bimetal is installed, and a trip unit 30 that performs a trip according to thermal deformation of the main bimetal. Referring to the drawing, the trip portion is coupled to the upper part of the base portion.

The base portion 10 includes a main bimetal 11 and a horizontal bar 12 that moves according to thermal deformation of the bimetal. When the main bimetal is thermally deformed and moves the horizontal bar, the horizontal bar contacts the end of the temperature compensation bimetal 310 of the trip unit 30.

Figure 3 is an exploded perspective view of the trip unit according to the present invention.

The trip unit 30 according to the present invention consists of a trip assembly 300, and a front cover (F-CV) and a rear cover (R-CV) that are coupled to the front and rear of the trip assembly.

Figure 4 shows the main components of the trip unit according to the present invention. Figure 4a) shows the overall configuration of the trip unit, and Figure 4(b) shows some components of the trip unit.

The trip assembly 300 includes a temperature compensation bimetal 310, a pressure lever 320 coupled to the temperature compensation bimetal, a reversal mechanism 330 that elastically deforms according to the pressure of the pressure lever, and follows the deformation of the reversal mechanism. It includes an interlocking lever 340 and an adjustment shaft 350 installed on the lower side of the inversion mechanism.

The lower end of the temperature compensation bimetal 310 is in contact with and interlocked with the movement of the horizontal bar 12 of the base portion 10 described above.

The temperature compensation bimetal 310 compensates for the curvature of the main bimetal due to changes in external temperature. For example, in hot summer, the main bimetal may be curved due to external temperature, and may trip depending on the curvature of the main bimetal. To prevent this, the temperature compensation bimetal compensates for the curvature caused by the abnormal temperature of the main bimetal.

The pressure lever 320 is connected to the temperature compensation bimetal and is inflected in conjunction with the movement of the temperature compensation bimetal. When the pressing lever is inverted, the end of the pressing lever presses the inversion mechanism.

Figure 5 shows a reversal mechanism and an adjustment axis according to the present invention.

The inversion mechanism 330 according to the present invention includes left and right plates 331, a center plate 332 provided between the left and right plates, and a spring 333 coupled to the center plate. The other side of the inversion mechanism is fixed, and the other side of the inversion mechanism is connected to the interlocking lever 340.

The left and right plates 331 are supported by the adjustment shaft 350, and the center plate 332 receives a pressing force from the end of the pressing lever described above. When the end of the pressing lever presses the center plate 332, the left and right plates rise due to the elastic force of the spring, and accordingly, one end of the inversion mechanism rises elastically. Accordingly, the interlocking lever 340 connected to one end of the inversion mechanism rises.

Referring to FIG. 5(a), an adjustment shaft 350 is installed on the lower side of the inversion mechanism, and the lower portions of the left and right plates 331 of the inversion mechanism are in contact with the adjustment shaft 350.

Figure 5(b) is a perspective view of the adjustment shaft according to the present invention, and Figure 5(c) is a front view of the adjustment shaft according to the present invention.

The adjustment shaft 350 according to the present invention includes a central portion 351, an eccentric portion 352 installed on the left and right sides of the central portion, an adjustment protrusion 353 protruding from the left eccentric portion, and an outer peripheral surface of the adjustment protrusion. It includes a concave-convex portion 354 formed on the outer peripheral surface of the control protrusion, a stopper 355 installed on both ends of the concave-convex portion, and a fixing bar 356 protruding from the right eccentric portion.

The eccentric portion 352 is in surface contact with the left and right plates 331 of the inversion mechanism. The supported height of the left and right plates 331 of the inversion mechanism may vary depending on the rotation of the eccentric portion 352.

Meanwhile, referring to Figure 5(c), a straight groove is formed on the end surface of the adjusting protrusion 353. The straight groove can be rotated using a driver tool.

Figure 6 shows the change in support of the inversion mechanism according to the rotation of the adjustment shaft.

The eccentric portion of the adjustment shaft according to the present invention supports the left and right plates 331 of the inversion mechanism. Figure 6(a) shows that the long semi-radius part of the eccentric part supports the left and right plates, and Figure 6(b) shows the short radius part of the eccentric part supports the left and right plates.

As shown in the drawing, the supporting height of the left and right plates of the long semi-diameter portion is higher than that of the short semi-diameter portion of the eccentric portion. By adjusting the height using the adjustment shaft, the end of the pressure lever 320 changes the position of the pressure height of the center plate 332 of the inversion mechanism, thereby correcting errors due to the trip load.

Figures 7 and 8 are views showing the coupling position of the adjustment shaft in the cover according to the present invention.

As shown in Figure 7, the fixing bar 356 of the adjustment shaft is inserted into the coupling groove (RH) of the rear cover (R-CV), and the adjustment protrusion 353 of the adjustment shaft is inserted into the through hole of the front cover (F-CV). It is inserted into (FH).

Figure 8 shows the inner surface of the front cover, where a through hole (FH) is formed, and the through hole is provided with a restraining protrusion (FH-h). The restraining protrusion restrains the rotation of the uneven portion 354 of the adjustment shaft. Accordingly, the adjustment shaft does not easily rotate due to weak external force. Additionally, the restraining protrusion prevents the stopper 355 of the adjustment shaft from rotating. When the adjustment shaft is rotated, the eccentric portion rotates alternately between the long and short diameter portions. The restraining protrusions are installed at both ends to limit the free rotation of the eccentric part. The eccentric part can rotate in an angle range of 180 degrees by the restraining protrusion.

Figure 9 shows the front cover of the thermal overload relay according to the present invention.

Referring to the drawing, a through hole (FH) is formed in the front cover (F-CV), an adjustment protrusion 353 of the adjustment shaft is exposed in the through hole, and an end surface of the adjustment protrusion 353 has a straight line. A groove (or cross groove) is formed. The operator can adjust the trip load by rotating the straight groove using a driver tool.

According to the present invention, the fixture 356 of the adjustment shaft is inserted into the coupling groove (RH) of the rear cover (R-CV), and the adjustment protrusion 353 of the adjustment shaft is inserted into the through hole (FH) of the front cover (F-CV). is installed in Support is provided on both sides of the adjustment shaft to prevent movement of the adjustment shaft and enable fine adjustment.

Above, the present invention has been described in detail through specific embodiments, but the present invention is not limited to the above embodiments, and various modifications can be made by those skilled in the art within the scope of the technical idea of the present invention.

10: base part
11: main bimetal
12: horizontal bar
30: Trip unit
300: Trip assembly
310: Temperature compensation bimetal
320: Pressure lever
330: Inversion mechanism
331: Left and right plates
332: central plate
333: spring
340: Interlocking lever
350: Control axis
351: central part
352: Eccentric part
353: Control protrusion
354: uneven part
355: stopper
356: fixture
R-CV: Rear cover
F-CV: Front cover
RH: Combination groove
FH: Through hole

Claims (4)

In a thermal overload relay consisting of a base unit 10 on which the main bimetal is installed and a trip unit 30 installed on the top of the base unit,
The trip unit 30 consists of a trip assembly 300, a front cover (F-CV) and a rear cover (R-CV) that are coupled at the front and rear of the trip assembly,
The trip assembly 300 includes a temperature compensation bimetal 310, a pressure lever 320 coupled to the temperature compensation bimetal, a reversal mechanism 330 that elastically deforms according to the pressure of the pressure lever, and a deformation of the reversal mechanism. It includes a following interlocking lever 340 and an adjustment shaft 350 installed on the lower side of the reversal mechanism,
The inversion mechanism 330 consists of left and right plates 331, a center plate 332 provided between the left and right plates, and a spring 333 coupled to the center plate,
The adjustment shaft 350 includes a central portion 351, an eccentric portion 352 installed on the left and right sides of the central portion, an adjustment protrusion 353 protruding from the left eccentric portion, and an adjustment protrusion formed on the outer peripheral surface of the adjustment protrusion. It consists of an uneven portion 354, a stopper 355 formed on the outer peripheral surface of the adjustment protrusion and installed on both ends of the uneven portion, and a fixing bar 356 protruding from the right eccentric portion,
Thermal overcurrent relay, characterized in that the left and right eccentric portions (352) of the adjustment shaft support the left and right plates (331) of the inversion mechanism, respectively.
In claim 1,
The rear cover (R-CV) is provided with a coupling groove (RH), and the front cover (F-CV) is provided with a through hole (FH),
The fixture 356 of the adjustment shaft is inserted into the coupling groove (RH) of the rear cover (R-CV), and the adjustment protrusion 353 of the adjustment shaft is inserted into the through hole (FH) of the front cover (F-CV). Characterized by thermal overcurrent relay.
In claim 1,
A straight groove or a cross groove is formed on the end surface of the adjusting protrusion 353, and the end surface of the adjusting protrusion 353 of the adjusting shaft is exposed through the through hole (FH) of the front cover (F-CV), A thermal overcurrent relay characterized in that the operator controls the trip load by rotating the straight groove or cross groove using a driver tool.
In claim 1,
The central portion 351 of the adjustment shaft 350 has a smaller outer diameter than the eccentric portion 352, so that when the pressing lever 320 presses the central plate 332 of the inversion mechanism 330, the adjustment shaft 350 A thermal overcurrent relay characterized in that there is no interference with the central part (351) of.

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