KR830001070Y1 - Terminal block - Google Patents

Abstract

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Description

Terminal block

1 is a view showing a part of the compressor of the terminal block of the present invention.

2 is an enlarged cross-sectional view of the terminal block of the present invention.

3 is a cross-sectional view of an annular groove showing an adjacent portion of the body.

4 is a cross-sectional view of the annular sealing ring and the adjacent portion of the fixed sleeve.

FIG. 5 is a cross-sectional view showing a portion in which an adhesive coating is coated between the surface forming the annular groove and the annular sealing ring in the terminal block shown in FIG.

The present invention relates to a terminal block for transferring power from an external power source to an electrical conductor located in the fuselage of an electrically operated device. Terminal blocks consisting of at least one conductive terminal wrapped in such a non-conductive body are used in many ways. As an example, such terminal blocks are used in compressors sealed by welding or quasi welding. Such compressors are used in mechanical air conditioners or refrigerators. It is important that the terminal block does not have any couplings or gaps in order to prevent leakage of compressed refrigerant gas from the compressor to the outside.

It is also desirable to manufacture terminal blocks from inexpensive materials and the terminal blocks can be made inexpensively by transfer molding or injection molding in the form in which the electrically conductive terminals are inserted into the thermosetting resin. Typically, the terminal block includes an annular groove having a plurality of holes extending in the axial direction at equal intervals on the circumference and attached to and inserted through a axial hole in a fixing device such as a bolt or the like. It is fixed to the fuselage.

Although the terminal blocks are made relatively inexpensively with a single molded body or housing, such terminal blocks may crack or otherwise deform when attached to the body. For example, if one of the fixtures is tightened more tightly than the other, the terminal block is locally compressed at the end under the over tightened bolts and twists against the surface of the device. In addition, when the fastening device is tightened firmly, bending moments occur at locally compressed ends, and in extreme cases, deformations or cracks occur at the ends. This crack causes the high pressure refrigerant to leak into the compartment. Therefore, the leakage loss of the refrigerant or other high pressure hydraulic oil through the terminal block is very large. According to the present invention, the drawback is that the terminal block for supplying electric power from an external power source to an electric conductor installed in the fuselage of the electric operation device composed of an axially extending body formed of a non-conductive material is connected to the electric conductor and the external power source. Consists of an electrically conductive terminal extending through the connecting body, and a fixed sleeve surrounding the body in an annular shape connecting the terminal block to the fuselage of the electric actuator, and overcomes by constructing the sleeve and the body in the axial direction. In addition, the terminal block includes an annular groove formed on the surface of the terminal block and includes an opening connected to a gap formed by the body and the sleeve, an inner compartment connected to the hole and having an axial length longer than the depth of the hole, and located in the inner compartment. And an annular hermetic seal which includes a head and extends radially through a gap consisting of a fixed sleeve and a body, the head surface being behind a hole in contact with a surface forming an annular groove that impedes fluid flow therebetween. Extend in the axial direction.

Referring to the present invention with reference to the drawings as follows. The present invention relates to a terminal block which is suitably used for various devices in which power is transferred from an external power source to a conductive lead provided in a housing or body of an electrical actuation mechanism via a block.

In the conventional apparatus, a terminal block having a hermetic or semi-hermetic refrigeration compressor by an electric motor was used. 1 shows a terminal block of the present invention in which the electrically operated refrigeration compressor 12 is installed. The block 10 is designed to supply electric power from an external power source (not shown) to an electrical input line (not shown) installed in the fuselage of the compressor 12. In particular, the plurality of electrically conductive terminals 16 extend through the terminal block 10 and the first end 18 of the terminal 16 is in contact with the boot electrical input line with an external power source and the second end 20 of the terminal 20. ) Is in contact with the electrical input line of the compressor motor (not shown).

Referring to FIG. 2, the terminal block 10 is composed of a normal terminal 16, a central portion or a body 22, and a fixed portion or a fixed sleeve 24. Body 22 is formed of a non-conductive material, such as a thermosetting resin, and the body is approximately inserted into electrically conductive terminal 16. The fixed sleeve 24 confines the cylindrical hole through the body 22, which usually has a rectangular perimeter and extends axially. In addition, the fixed sleeve 24 surrounds the body 22 in an annular shape. The fixed sleeve 24 has a constant spaced axially extending hole 26 and a compressor 12 for attaching a hole or terminal block 10 hung through the hole 26 to the electrical actuator. Fasteners, such as bolts 28, that extend to the holes 30 installed in the body 14 of the < RTI ID = 0.0 > A closure device, such as a gasket 31, is installed between the sleeve and the body to block or delay the flow of fluid between the fixed sleeve 24 and the body 14. Until now, the fixing part of the terminal block 10 was also formed of a thermosetting resin. Using such a material, when the terminal block is fixed to the electric actuating device, either of the fixing mechanisms is excessively clamped on one side of the block and is twisted and locally compressed. The thermosetting resins used to make terminal blocks cannot accommodate excessive concentrated stress, so the terminal blocks cause breakage or deformation. In order to solve the above problem, the fixed sleeve 4 is formed of a material capable of withstanding greater concentrated stress than in the thermosetting resin used to manufacture the body 22 of the block 10. For example, the fixed sleeve 24 is formed of aluminum or other suitable material. When the terminal block is attached to the electric actuating device as a fixed device, the only fixed sleeve is installed under the compressive load, so in this case the terminal block can withstand greater concentrated stress without being damaged.

The terminal block 10 is formed by positioning the fixed sleeve 24 in the mold, placing the terminal 16 in the mold, and spraying or injecting the heated thermosetting resin into the mold around the terminal. The resin is cured by forming the body 22 solid. When the resin is injected into the mold, the resin heats the fixed sleeve 24. After the resin is cured, the resin and the fixed sleeve 24 are cooled. The resin is cured and cooled and the fixed sleeve 24 cools down. The resin and sleeve shrink in both the radial and axial directions, and the resin shrinks more severely than the fixed sleeve. In FIG. It is enlarged. In order to prevent the refrigerant from leaking through the axial gap 32, the terminal block 10 includes an annular groove 24 and a sealing ring 36 that closes or seals the gap 32.

The annular groove 34 shown in detail in FIG. 2 is formed of the surface of the terminal block 10 and the surface of the body 22. The groove 34 includes a hole 40 connected to the gap 32, and an inner compartment 42 connected to the hole 40 and having an axial length longer than the hole depth. The annular sealing ring 36 extends radially through the gap 32 and is formed to be completely combined with the fixed sleeve 24. Referring to FIGS. 2 and 4, the sealing ring 36 is a compartment 42 The head surface 44 of the head 44 extends axially behind the hole 40 in contact with the surface 38 to prevent the flow of fluid therebetween. In this way, the annular groove 34 and the sealing ring 36 seal the leakage passage between the body 22 and the fixed sleeve 24 and close the gap 32 therebetween.

In the preferred embodiment shown in the figure, the annular groove 34 comprises a passage extending radially from the aperture 40 of the inner compartment 42 and having an axis length shorter than the axial length of the inner compartment 42. do. The annular closure ring 36 also includes a neck 50 extending radially along the passageway into the interior compartment. The inner compartment 42 extends symmetrically up and down the hole 40, the head 44 extends symmetrically up and down the neck 50 and the surface 46 of the head contacts the up and down hole 40. Doing. The annular groove 34 and the annular sealing ring 36 are tightly fitted or dovetailed.

The bond between the annular ring 36 and the groove 34 has been improved by shrinking in the axial radius direction as the resin used to form the body is cured and cooled. As described above, when the terminal block 10 is formed, the resin is cured and cooled, and the fixed sleeve 24 is cooled, the resin shrinks more severely than the fixed sleeve, while both the resin and the fixed sling radially. To contract. In particular, the surface 38 forming the groove 34 moves in the second figure to the right, radially inward with respect to the head 44 and between the surface 38 and the surface 46 of the head 44. Pressure is applied. This pressure serves to prevent the flow of the refrigerant along the leakage passage formed by the fixed sleeve 24 and the body 22. Therefore, the user can take advantage of the greatest disadvantage of the molded terminal block (reduction due to the curing and cooling of the thermosetting resin forming the block) as an advantage (used for sealing between the fixed sleeve 24 and the body 22). do.

As shown in FIG. 2, surfaces 38 and 46 are joined directly. However, as shown in FIG. 5, the surfaces 38 and 46 are directly bonded through the adhesive coating 52 disposed between the surfaces. The adhesive film 52 is suitable when the terminal block 10 uses a high pressure refrigerant. The annular sealing ring 36 is coated with a pressure sensitive adhesive coating on the formation of the body 22. As the thermosetting resin cures, cools and shrinks to form the body 22, the adhesive is forced to squeeze the fluid flow between the surfaces 38 and 46 while locally filling the space created by the shrinkage. In addition, the contraction action forces the adhesive into the gap or irregularities between the surfaces 38 and 46 to prevent the leakage path from extending through the gap or irregularities. Therefore, the adhesive should be thermosetable at a molding temperature of about 160 ° C and have sufficient strength not to be swept away when the resin is inserted into the mold during molding. It is known that adhesives called "hysol AS7-2094" have satisfactory properties. "Hyazole" is a Dexter Corporation registered trademark.

Although only the case where the terminal block 10 is applied to the refrigeration compressor is shown here, it may be usefully used in other devices in which the leak-proof block is used.

The present invention is designed to satisfy the above object, but may have various embodiments by those skilled in the art and the claims include all these embodiments according to the present invention.

Claims (1)

An axially extending body formed of a non-conductive material, a conductive sleeve extending through the body connecting the external power source and the electrical conductor, and a fixed sleeve surrounding the body connecting the terminal block to the body of the electric actuator. A terminal block having an axially extending gap formed by a sleeve and a body, and transferring electric power from an external power source to a conductor installed in a fuselage of a battery operated device, wherein the gap is formed of a body 22 and a fixed sleeve 24. An annular groove 34 including a hole 40 connected to the 32 and limited to the surface 38 of the terminal block 10, and an inner compartment 42 connected to the hole with an axial length longer than the depth of the hole; And an annular sealing ring 36 extending radially through a gap 32 which includes a head 44 located in the inner compartment 42 and is confined to the body 22 and the fixed sleeve 24. Composed A terminal block axially extending behind a hole (40) in contact with a surface (38) that restricts the annular groove (32) of the surface of the air head and retards fluid flow therebetween.