JP6462282B2 - Additional equipment - Google Patents

Description

  The embodiment relates to an additional device for a thermal relay.

  The thermal relay includes a plurality of heat sources, a plurality of bimetals, and a contact mechanism. Each of the plurality of heat sources generates heat when a current from the electric motor flows, and each of the plurality of bimetals is heated by the heat source. The contact mechanism is connected to multiple bimetals. When multiple bimetals are bent by heating, the contact mechanism operates by transmitting the bimetal curve to the contact mechanism. By doing so, it is detected that the temperature of the electric motor has risen due to overcurrent.

JP 2007-234494 A JP 2002-203465 A Japanese Patent Laid-Open No. 6-196076

  In the case of conventional thermal relays, the current setting range is set according to the number of turns of the conducting wire (heat source) to the bimetal, the thickness of the conducting wire, the length of the bimetal, etc., and the rating is divided for each current setting range. Yes. Therefore, when the rated current of the electric motor is changed outside the current setting range of the thermal relay, it is necessary to replace the thermal relay with another having a different rating.

Additional equipment examples are additional devices to be used in the thermal relay comprising a plurality of heat sources which generate heat when current flows therethrough, a plurality of bimetal which is heated by the heat source is provided for each of the heat source, each of the heat source And a plurality of variable resistors connected in parallel to the heat source, and an adapter for connecting each of the plurality of variable resistors to the heat source of the thermal relay.

The figure which shows Example 1 (The figure which shows the external appearance of a thermal relay, an adapter, and a diversion unit) Diagram showing the electrical connection between the thermal relay, adapter and shunt unit Diagram showing the appearance of the adapter FIG. 1 equivalent diagram showing Example 2. 2 equivalent diagram FIG. 1 equivalent diagram showing Example 3. 2 equivalent diagram

As shown in FIG. 1, a diversion unit 3 is attached to the thermal relay 1 via an adapter 2. The thermal relay 1 deforms the bimetal with heat generated when the main current of the electric motor abnormally increases, and switches the contact mechanism according to the deformation of the bimetal. The adapter 2 electrically and mechanically connects the flow dividing unit 3 to the thermal relay 1 and is used for sharing the flow dividing unit 3 among a plurality of thermal relays 1 having different sizes. The diversion unit 3 changes the current settling range of the thermal relay 1, and the detailed configuration of the thermal relay 1, the adapter 2, and the diversion unit 3 is as follows.
1. About Thermal Relay 1 In the thermal case 11, a plurality of bimetals 12 are accommodated as shown in FIG. Each of the plurality of bimetals 12 is formed by joining a pair of metal plates having different coefficients of thermal expansion, and one end of each of the plurality of bimetals 12 is fixed to a stationary member in the thermal case 11. . Each of the plurality of bimetals 12 has a straight shape in a normal state, and a shifter is connected to the other end of the plurality of bimetals 12. The shifter is housed in the thermal case 11 so as to be displaceable between the first position and the second position, and is stationary at the first position in the normal state of the plurality of bimetals 12.

  A coil 13 corresponding to a heat source is wound around each of the plurality of bimetals 12 as shown in FIG. Each of the plurality of coils 13 flows the main current of the electric motor, and when an overload occurs in the electric motor, the bimetal 12 is heated in response to the coil 13 generating heat. Each of the plurality of bimetals 12 changes from the normal state to the curved state in response to being heated, and the shifter changes from the first position to the second state in response to the bimetal 12 from the normal state to the curved state. Displace to position.

A normally open contact and a normally closed contact are accommodated in the thermal case 11, and each of the normally open contact and the normally closed contact is connected to a shifter via a contact switching mechanism. This contact switching mechanism is housed in the thermal case 11 and closes the normally closed contact at the first position of the shifter, opens the normally open contact, and opens the normally closed contact at the second position of the shifter. And close the normally open contact.
2. Adapter 2 The terminal block 21 of FIG. 3 is attached to the thermal case 11. A plurality of conductive plates 22 and a plurality of female connectors 23 are fixed to the terminal block 21, and each of the plurality of female connectors 23 is wired 24 to the conductive plate 22 inside the terminal block 21 (see FIG. 2). Connected through. The plurality of conductive plates 22 are arranged in a line along one end of the terminal block 21, and the plurality of female connectors 23 are arranged along the plurality of conductive plates 22. Each of the plurality of conductive plates 22 is connected to a terminal 26 (see FIG. 2) via a screw 25, and each of the plurality of terminals 26 is connected to the coil 13 via a wiring 27 as shown in FIG. Is connected to one end of the.

As shown in FIG. 3, a plurality of conductive plates 28 and a plurality of female connectors 29 are fixed to the terminal block 21, and each of the plurality of female connectors 29 is connected to the conductive plate 28 inside the terminal block 21. They are connected via wiring 30 (see FIG. 2). The plurality of conductive plates 28 are arranged in a line along the other end of the terminal block 21, and the plurality of female connectors 29 are arranged along the plurality of conductive plates 28. A terminal 32 (see FIG. 2) is connected to each of the plurality of conductive plates 28 via screws 31, and each of the plurality of terminals 32 is connected to the coil 13 via a wiring 33 as shown in FIG. Connected to the other end.
3. About the shunt unit 3 In the unit case 41, a plurality of variable resistors 42 are accommodated, as shown in FIG. As shown in FIG. 1, the plurality of variable resistors 42 have a rotatable dial 43, and the dial 43 protrudes out of the unit case 41 so as to be operable. Each of the plurality of variable resistors 42 has a resistance value that changes in accordance with the amount of rotation of the dial 43, and a male connector 44 is connected to one end of each of the plurality of variable resistors 42. Each of the plurality of male connectors 44 protrudes outside the unit case 41, and a male connector 45 is connected to the other end of each of the plurality of variable resistors 42. Each protrudes outside the unit case 41. Each of the plurality of variable resistors 42 corresponds to a variable resistor.

  As shown in FIG. 1, each of the plurality of male connectors 44 is detachably fitted to the female connector 23 of the adapter 2, and each of the plurality of male connectors 45 is a female side of the adapter 2. The connector 29 is detachably fitted. Each of the plurality of variable resistors 42 is fitted between the male connector 44 and the female connector 23, and the coil of the thermal switch 1 according to the fitting between the male connector 45 and the female connector 29. The main current from the motor is shunted to each of the plurality of variable resistors 42 when the shunt unit 3 is connected to the thermal relay 1 via the adapter 2. To do.

According to the said Example 1, there exists the following effect.
Since the variable resistor 42 of the shunt unit 3 is connected in parallel to each of the plurality of coils 13 of the thermal relay 1, the current from the electric motor is shunted to each of the plurality of variable resistors 42. Accordingly, since the current setting range of the thermal relay 1 can be adjusted by rotating the dials 43 of the plurality of variable resistors 42, the thermal relay 1 can be used even when the rated current of the motor is changed. Can be used without replacement.

  Each of the plurality of variable resistors 42 of the shunt unit 3 was connected to the coil 13 of the thermal relay 1 via the adapter 2. Although this thermal relay 1 has a different size of the thermal case 11 according to the current settling range, the shunt unit 3 is attached to the thermal case 11 via the adapter 2, so that a common shunt unit is used between the thermal relays 1 having different current settling ranges. 3 can be used.

In the first embodiment, the diversion unit 3 may be directly connected to the thermal switch 1.
In the first embodiment, each of the plurality of variable resistors 42 is directly connected to the coil 13 of the thermal relay 1 via a wiring without unitizing the plurality of variable resistors 42 via the unit case 41. May be.

  As shown in FIG. 4, an expansion branch unit 4 is interposed between the adapter 2 and the branch unit 3. As shown in FIG. 5, the shunt unit 4 has a plurality of variable resistors 42 accommodated in a unit case 41, and each dial 43 of the plurality of variable resistors 42 is operated outside the unit case 41. The male connector 44 is connected to one end of each of the plurality of variable resistors 42, and the male connector 45 is connected to the other end of each of the plurality of variable resistors 42. Each of the plurality of variable resistors 42 of the shunt unit 4 corresponds to an additional variable resistor.

  As shown in FIG. 4, a plurality of female connectors 46 are fixed in a row to the unit case 41 of the diversion unit 4. As shown in FIG. 5, each of the plurality of female connectors 46 is a unit case 41. Is connected to one end of the variable resistor 42 via a wiring 47. As shown in FIG. 4, a plurality of female connectors 48 are fixed to the unit case 41 in a row. As shown in FIG. 5, each of the plurality of female connectors 48 is provided inside the unit case 41. The other end of the variable resistor 42 is connected via a wiring 49.

  As shown in FIG. 5, each of the plurality of male connectors 44 of the diversion unit 4 is detachably fitted into the female connector 23 of the adapter 2, and each of the plurality of male connectors 45 is a female connector of the adapter 2. The side connector 29 is detachably fitted. Each of the plurality of female connectors 46 of the flow dividing unit 4 is detachably fitted with the male connector 44 of the flow dividing unit 3, and each of the plurality of female connectors 48 is connected to the male connector 45 of the flow dividing unit 3. It is detachably fitted. That is, the shunt unit 4 is electrically and mechanically connected between the adapter 2 and the shunt unit 3, and each of the plurality of variable resistors 42 of the shunt unit 4 includes the coil 13 of the thermal switch 1 and the shunt unit 3. Are connected to the variable resistor 42 in parallel.

According to the said Example 2, there exist the following effects.
Since each of the plurality of variable resistors 42 of the additional shunt unit 4 is connected in parallel to the coil 13 of the thermal relay 1 and the variable resistor 42 of the shunt unit 3, the plurality of dials 43 and the shunt unit 4 of the shunt unit 3 are connected. By rotating each of the plurality of dials 43, the current settling range of the thermal relay 1 can be largely adjusted. Therefore, even if the rated current of the motor is greatly changed, the thermal relay 1 can be used as it is without being replaced.

As shown in FIG. 6, the diversion unit 4 is detachably connected to the adapter 2. In this diversion unit 4, each of the plurality of male connectors 44 is fitted into the female connector 23 of the adapter 2, and each of the plurality of male connectors 45 is fitted into the female connector 29 of the adapter 2. An ammeter unit 5 is detachably connected to the shunt unit 4 and is connected to the thermal relay 1 via an adapter 2. This ammeter unit 5 measures the magnitude of the current flowing through the coil 13 of the thermal switch 1 and the variable resistor 42 of the shunt unit 4, and is configured as follows.
1. About Ammeter Unit 5 A plurality of male connectors 52 and a plurality of male connectors 53 are fixed to the connector case 51 as shown in FIG. Each of the plurality of male connectors 52 is detachably fitted into the female connector 46 of the flow dividing unit 4, and is connected to a commercial AC power supply via a wiring 54. Each of the plurality of male connectors 53 is detachably fitted into the female connector 48 of the flow dividing unit 4, and is connected to a commercial AC power supply via a wiring 55.

  As shown in FIG. 6, a plurality of ammeters 62 are attached to the ammeter case 61. Each of the plurality of ammeters 62 has a scale plate 63 and a pointer 64, and a current transformer 66 is connected to each of the plurality of ammeters 62 via a wiring 65 as shown in FIG. ing. Each of the plurality of current transformers 66 is interposed in the wiring 54 inside the ammeter case 61, and the pointer 64 of each of the plurality of ammeters 62 is variable for the coil 13 of the thermal switch 1 and the shunt unit 4. The current value flowing through the resistor 42 is indicated. Each of the plurality of ammeters 62 corresponds to a current detector.

According to the said Example 3, there exist the following effects.
An ammeter 62 for detecting the current flowing through the coil 13 of the thermal relay 1 and the variable resistor 42 of the shunt unit 3 is provided. Therefore, when the operator operates the plurality of dials 43 of the shunt unit 4 while looking at the pointer 64 of the ammeter 62, currents having the same magnitude can be caused to flow through the coils 13 of the thermal relay 1 respectively. Therefore, it is possible to correct variation in resistance value among a plurality of phases.

  As mentioned above, although the Example of this invention was described, this Example is shown as an example and is not intending limiting the range of invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention and are also included in the invention described in the claims and the equivalent scope thereof.

  1 is a thermal relay, 2 is an adapter, 12 is a bimetal, 13 is a coil (heat source), 42 is a variable resistor (variable resistor), and 62 is an ammeter (current detector).

Claims (3)

In an additional device used for a thermal relay including a plurality of heat sources that generate heat when current flows, and a plurality of bimetals that are provided for each heat source and are heated by the heat sources,
A plurality of variable resistors provided for each heat source and connected in parallel to the heat source;
An adapter for connecting each of the plurality of variable resistors to the heat source of the thermal relay;
Additional equipment characterized by comprising The additional device according to claim 1 , further comprising a plurality of additional variable resistors provided for each of the variable resistors and connected in parallel to the variable resistor and the heat source. Wherein provided for each heat source, the addition device according to claim 1 or 2, characterized in that it comprises a plurality of current detectors for detecting current flowing through said heat source and said variable resistor.

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