KR830001772Y1 - Solid state starter with socket terminal - Google Patents

Abstract

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Description

Solid state starter with socket terminal

1 is a top cross-sectional view of a contactless starting device with a conventional socket terminal.

2 is an electric circuit diagram of a split-phase starting type electric compressor using a static temperature-sensitive resistance element.

Figure 3 is a cross-sectional top view of a contactless starting device with a socket terminal showing an embodiment of the present invention.

4 is a perspective view of the protective cover of FIG.

5 is an exploded perspective view of a contactless starting device with a socket terminal showing an application of the present invention.

The present invention relates to an improvement of a contactless starting device with a socket terminal for use directly connected to an input terminal installed on the outer shell of an electric compressor used in a refrigerator or the like.

1 to 2, the conventional structure is described, where 1 is an electric compressor, 2 is an input terminal provided on the outer shell 3 of the electric compressor 1, and 4 is a protective frame fixed to the outer shell 3. to be.

5 is a predetermined temperature 8 surrounded by a case 6 and a base 7 made of an insulating material having heat resistance, such as a barium titanate-based semiconductor and the like. The thermostatic resistance element 9 whose resistance changes rapidly in the And a wire connection terminal provided at both ends of the positive electrode 11 and 12 of the positive temperature sensitive resistance element 9 so as to protrude from the case 6 at the same time. (13) and the socket terminals in which electrical conduction is made by electrically contacting the conductive metal electrodes 16 and 17 with the socket terminals 15 having the other ends mounted in the opening holes 14 of the base 7. Attached contactless starting device.

The contactless starting device 5 with the socket terminal is attached by inserting and fitting the socket terminal 15 into the pressure terminal 2 of the electric compressor 1. 18 is a protective cover installed for the purpose of insulation and waterproofing on the solid-state starting device 5 with the socket terminal attached thereto.

The protective cover 18 is provided with the above-mentioned protection frame to preserve the almost closed state except for the opening 19 on the outer side 3 side of the electric compressor 1 and the through hole 20 of the connecting wire (not shown). It is fixed by the pressure spring 21 clamped in 4).

When power is applied using the contactless starting device 5 with the socket terminal of the above structure as the splitter moving type electric compressor 22 of the electric circuit as shown in FIG. 2, the main winding ( Along with the main line 24, a current flows through the static winding resistance element 9 to the starting winding 25, and the shape-driven electric compressor 22 is started.

At this time, the temperature-sensitive resistance element 9 rises due to the current flowing in the starting winding 25. When this temperature exceeds the Curie point, the resistance increases rapidly.

As a result, the current of the starting winding 25 is extremely small, so that the circuit of the starting winding 25 is practically cut off. In this state, the resistive thermosensitive resistance element 9 is extremely turned on and self-heats by a small current flowing through the constant thermosensitive resistance element 9 to maintain a high resistance state.

Next, when the power supply is turned off, the energization of the main winding 24, the starting winding 25, and the static temperature-sensitive reservoir 9 is interrupted, and the rotation of the separator-driven electric compressor 22 is stopped.

It is well known that when the static temperature-sensitive resistive element 9 starts to cool down from this moment and falls below the Curie point, the resistance decreases rapidly.

When the door is opened and closed like a refrigerator, and the start-up and stop of the phase-operated electric compressor 22 are automatically sensed and controlled by a temperature controller or the like, the separator-driven electric compressor 22 stops. Immediately afterwards, the thermostat operates and there is a chance to restart automatically.

At this time, if the double wall structure of the outer shell of the static temperature-sensitive reservoir 9 is used, that is, the protective cover 18 is covered outside the case 6, the heat dissipation of the static temperature-sensitive storage element 9 is well achieved. In other words, it takes a long time to cool below the Curie point, which slows down the resistance. As a result, the restart probability in the high resistance state which does not reach below the Curie point increases, and a large current required for starting is not supplied to the starting winding 25, and a starting failure frequently occurs due to lack of oak.

In addition, when the frost attached to the evaporator of the refrigerator is defrosted by heating by a heater or the like and forcibly defrosting, the temperature of the refrigerant in the evaporator becomes high, and the internal pressure is about 5 kg / cm ² G. High pressure

As a result, there is a problem that the work load of the splitter moving type electric compressor 22 increases, that is, the load increases, and that the starting failure of lighting that causes a decrease in the resistance value of the static temperature-sensitive storage element 9 increases.

In addition, once the start is poor, a current flows in the overload protection device 23 to operate the overload protection device 23. Next, the overload protection device 23 returns after a period of time elapses, but if the heat dissipation of the static temperature-sensitive storage element 9 is poor, the resistance of the static temperature-sensitive storage element 9 sufficiently decreases within this recovery time. If not, the semi-permanent starting failure occurs in which the overload protection device 23 does not repeatedly operate and return.

Therefore, it was necessary to develop a special one carefully selected by matching the recovery time of the overload protection device 23 to the cooling characteristics of the static temperature-sensitive storage element 9.

Therefore, the adjustment and sorting required a long time, significantly lowered the productivity and at the same time caused the price increase due to the bad effect of the ratio of the product to the cost.

In the worst case, the overload protection device 23 of the required specification could not be manufactured.

As a countermeasure against this, when the protective cover 18 is removed, the motor-driven compressor 1 is generally attached to the top of the refrigerator so as to radiate heat. 5) It is also exposed to the outside.

As a result, when cleaning the upper surface of the electric refrigerator by spraying water, water adheres to the exposed charging part, which causes a short circuit between the charging parts and an insulation resistance between the charging part and the non-charged metal part, which causes a short circuit accident. .

The present invention is made to remedy this drawback. That is, the insulating case contains a positive temperature sensitive resistance element and a conductive tool in contact with the positive electrode of the positive temperature sensitive element, and installs a wire connecting terminal at one end of one or both ends of the conductive tool and at the other end of the electric compressor. In a contactless starting device with a socket terminal provided with a socket terminal for connecting directly to an input terminal, a protective cover is placed on the wire connecting terminal, and the angle of the thermosensitive storage element accommodating part of the insulating case is projected on the outside of the protective cover. It is intended to solve the above defects by providing good heat dissipation.

Hereinafter, the details of the present invention will be described with reference to one embodiment of FIGS. 3 to 4.

Like reference numerals in the drawings denote like parts.

The difference from the prior art is the case 26 and the protective cover 27 made of an insulating material having heat resistance.

That is, the positive electrode 11 of the static temperature-sensitive storage element 9 together with the static temperature-sensitive reservoir 9 in a substantially box-shaped space 29 having one side of the case 26 as the opening 28. 12, the conductive metal fittings 16 and 17 which are in contact with each other are accommodated, and a flange portion 30 is provided at the bottom of the opening 28, and the wire connecting terminal 13 is protruded and installed at the flange portion 30. At the same time, a U-shaped insulating wall 32 is continuously provided in the middle portion of the flange face 30a on which the outer shell 31 of the box-shaped space 29 and the wire connecting terminal 13 protrude. A protective cover 27 formed by connecting two box-shaped covers 34 each having an opening 33 as an opening 33 between the curved insulating wall 32 and the outer shell 31 by a wall 35 facing each other. Is in contact with the end face 37 of the opening 33 side of the wall 36 that intersects the connection wall 35 at right angles.

In the contactless starting value 38 to which the socket terminal of this structure is attached, the outer shell 31 of the case 26 protrudes from the part of the connection wall 35 to the outside of the protective cover 27.

Therefore, the static temperature-sensitive storage element 9 is covered only with the outer shell 31 of the case 26 and the heat dissipation is improved. As a result, in addition to the direct cooling action of the outside air, the time to cool below the Curie point of the static temperature storage reservoir 9 is shortened, the resistance decreases quickly, and the starting winding 25 has a large current required for starting. Is easily supplied so that starting failure due to torque shortage does not occur.

Also, even if water is sprayed, there is no nozzle filling as shown in FIG. 3, and the sprayed water is transferred to the outer shell 31 of the case 26, the flange portion 30a and the wall 36 of the protective cover 27. The enclosed space flows from the near side to the opposite side of the road. In addition, even if water penetrates from the contact portion of the flange portion 30a of the case 26 and the end face 37 of the protective cover 27, it is blocked by the insulated insulating wall 32 of the upper surface of the case 26. Since it does not penetrate inside, it does not cause short circuit or insulation failure.

In Table 1, the contactless starter 38 with the socket terminal of the present invention and the contactless starter 5 with the conventional socket terminal are assembled in the same refrigerator, so that the functional characteristics, namely restartable cutting time and minimum start-up, are assembled. The result of comparing the voltage is shown.

TABLE 1

(Startup characteristics comparison result)

As can be seen from Table 1, the restartable shortest time is less than or equal to the conventional structure, so that the overload protection device 23 generally has a return time that is generally used. As a result, the productivity of the overload protection device 23 is not lowered and may be used at low cost.

The present invention has various effects as described above, and the practical effect is very large because it can be provided at low cost by employing a contactless starting device with a highly reliable socket terminal.

FIG. 5 shows an application example of the contactless starting device 41 with the socket terminal having the overload protection device 23 and the terminal 39 having the same effect fixed to the mounting table 40 and integrated. will be.

Claims (1)

In the insulating case 6, the conductive thermosensitive resistor 9 and the conductive brackets 16, 17 in contact with the positive electrodes 11, 12 of the static thermosensitive resistor 9 are housed. A wire connecting terminal 13 is provided at one end of the brackets 16 and 17, and a socket terminal 15 for directly connecting the input terminal 3 of the electric compressor 1 to the other end is provided. In the solid-state starting device (5) with one socket terminal, a protective cover (27) is placed on the wire connecting terminal (13), and the outer portion of the static characteristic thermosensitive resistance element (9) of the flexible case (26) 31) A contactless starting device with a socket terminal, characterized in that protruding outside the protective cover (27).