KR970004403Y1 - Resistor housing - Google Patents

Abstract

None.

Description

Housing for large capacity resistor enclosure

1 is an exploded perspective view of an essential part showing an embodiment of the present invention

2 is a side cross-sectional view showing the assembled state of FIG.

3 is an exploded perspective view of an essential part showing another embodiment of the present invention

4 is a combined state diagram of the FIG. 3 embodiment.

5 is an essential part assembly state showing another embodiment of the present invention

6 is an exploded perspective view illustrating an encapsulation structure related to a conventional large capacity resistor.

* Explanation of symbols for main parts of the drawings

2: material 4: space

6 spacer portion 8 flat portion

10: end 12: 휜

14: heat sink 22: stopper

24: notch 26: spacing area

The present invention relates to a housing for housing and sealing a resistor therein, and more particularly, to a sealing housing suitable for a large capacity resistor.

The resistor is usually a structure in which a material having a property of suppressing the passage of an electric current is enclosed therein. As a small resistor commonly used, a carbon film type may be mentioned.

Carbon film type has the advantage of being easy to manufacture, but it is not used in places such as high voltage current transmission because it cannot be mass-capable.

Unlike general resistors, large-capacity resistors use nichrome wire as a resistor, and its resistance is inversely proportional to the cross-sectional area of the nichrome wire and proportional to its length.

In the large-capacity resistor described above, the nichrome wire is enclosed in a suitable container, case, housing, or the like.

Conventionally, since a nichrome wire is put into a bottomed container and filled with an insulating material, it is manufactured in such a way that the structure of the resistor cannot be thinned.

Figure 6 depicts an example of an improved slim large capacity resistor in response to the recently required slimming.

This resistor accommodates a resistor (B) wound with nichrome wire inside a thin housing (A) having a bottom, and interposing a mica plate (C) as an insulating material on the upper and lower sides thereof, and housing the housing ( It has a structure which covered the open part of A) with the thin cover D, and was sealed by the screw E. FIG.

In the resistor having such a structure, the lead wire F is led to the outside through the groove G formed around the housing A. FIG.

The resistor of the above-described structure tends to be preferred because of its large capacity and its minimum size. However, in this structure, the housing A must be manufactured by the die casting method because the periphery of the housing A has a projection for accommodating the resistor B and the mica plate C integrally.

Although the die casting method can produce a large amount of one specification, there is a problem in producing the same structure by the specification.

That is, in order to manufacture the housing (A) of various standards by the die casting method, it is necessary to prepare a dedicated mold for each standard, the preparation of such a mold will act as a cause causing a rise in product cost.

The purpose of the present invention is to provide a space for accommodating resistors by symmetrically combining pairs of simple structures that can be manufactured by inexpensive extrusion methods so as to solve the problems of the conventional slim type large capacity resistors described above. It is to provide a housing for a large capacity resistor encapsulation improved to be formed.

In accordance with the above object, the present invention is a spacer portion having a relatively thick portion at one side in the longitudinal direction, the flat portion is formed to extend a thin thickness from the spacer to assemble the pair of materials holding the end in a mutually symmetrical length A housing is proposed which allows a space opened in a direction to be formed therein.

The pair of materials may each have a stopper on the outer edge of the spacer portion. In this case, the flat portion extending in a thin thickness should be set so that its width direction is shorter by the width of the stopper.

The pair of materials disposed symmetrically with each other may have a flat portion on the entire opposite surface thereof. In this case, notches are provided at both edges of the flat surface in the longitudinal direction, and stoppers in both directions held by the gap holder are engaged with the notches to form an inner body space.

The housing according to the present invention may further attach a heat sink having a plurality of fins formed on two flat surfaces or one flat surface having a large surface area at the outside thereof. In addition, the fin having substantially a heat dissipation effect may be integrally formed on two flat surfaces or one flat surface.

The inner space formed by a pair of mutually symmetrical combinations is sealed with a heat resistant insulating material after the usual resistor is housed, and the lead wire of the resistor must be drawn out beforehand.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is an exploded perspective view of an essential part showing an embodiment of the present invention, showing that the housing is made of a pair of mutually symmetrical material (2).

When the pair of materials 2 are combined, they form a space 4 in which the opening is opened in the longitudinal direction therein, and the space 4 is an exquisite harmony of the component parts held by each material 2. It occurs as

In order to form the space 4 described above, each material 2 has a relatively thick spacer portion 6 at a predetermined portion on one side.

In this spacer portion 6 a relatively thin flat portion 8 is elongated in the opposite direction and as a result an end 10 is formed at their boundary.

The end 10 acts as an element defining both side walls of the space 4 when both materials 2 are combined.

On the outer side of the material 2 to be combined with each other, a heat sink 14 that integrally holds a plurality of fins 12 on both sides or on either side may be additionally mounted. In this embodiment the heat sink 14 is mounted depending on the usual rivets or screws 16.

To this end, holes 18 are drilled at regular intervals on the heat sink 14 as well as on the edges of both materials 2. In use, both openings along the longitudinal direction of the space 4 are heat-resistant after the usual storage body 20 surrounded by an insulating material is inserted and received in the internal space 4 formed by the combination of the materials 2. Sealed with insulating material.

FIG. 2 is a view showing a state in which both materials 2 are combined, showing that the overall thickness H of the housing is determined according to the thickness settings of the spacer portion 6 and the flat portion 8.

3 is a perspective view of an essential part showing another embodiment of the present invention.

In this embodiment, each material 2 depicts an example in which the stopper 22 is integrally formed to protrude from the upper surface of the spacer portion 6 to the outer end.

As the stopper 22 is added to each material 2 in this way, the width of the flat portion 8 should be set as short as the width of the stopper 22. This embodiment is depicted in FIG. 4 in which the stopper 22 supports the side edges of the flat portion 8 in the combined state of the two workpieces 2 so that at least both workpieces 2 are in the width direction. No slipping is caused by slipping.

This effect is very important in keeping both materials 2 in a combined state by using a specific jig.

5 shows another embodiment related to the present invention.

In this embodiment, both materials 2 have flat surfaces 8 on opposite sides, and only the notches 24 are formed at both edges of the flat portion 8 in the width direction. The material 2 differs in that it is combined via the space | interval holding part 26 between them.

Since the space holder 26 is interposed with the stoppers 22 extending in both directions engaging the notches 24 of both materials 2, the space 4 formed between the materials 2 is maintained. It is defined by the thickness of the sphere 26.

In this embodiment, both materials 2 and the spacing 26 interposed therebetween are integrally combined depending on the rivets or screws 18.

Although the detailed description has been omitted, in the above-described embodiment, the heat sink 14 is added to the outer flat surface of the two materials 2 or the fin 14 is substantially integrally cooled to both materials 2. Additive forming embodiments can likewise be applied.

Reference numerals 28 in FIGS. 1 and 3 denote threaded holes for mounting the resistor of the present invention to a conventional heat sink.

In the housing of the present invention as described above, a pair of materials constituting the main part may be manufactured by compression molding, and both the materials thus formed may be arranged in a symmetrical manner so that the combination may be formed to form a space inside. It becomes simple.

In addition, since the production of resistors is possible only by selecting the length of the material, it has the advantage of providing extremely low-cost resistors of various specifications compared to the conventional large-capacity resistors illustrated in FIG.

Claims (4)

In a housing for a large-capacity resistor encapsulation housing a space for enclosing a resistor surrounded by an insulating material therein, consisting of a pair of materials (2) arranged symmetrically, each of which is a longitudinal direction A space (4) defined by the end portion (10) having a thick spacer portion (6) at one edge on a side edge and extending from the spacer portion (6) in a thin flat portion (8) in the opposite direction. A housing for encapsulating a large capacity resistor, characterized in that to form a. The high capacity resistor encapsulation according to claim 1, characterized in that both materials (2) each have a stopper (22) engaged with the edge of the flat portion (8) corresponding to the outer edge of the upper surface of the spacer portion (6). Housing. A housing for a large-capacity resistor encapsulation housing a space for enclosing a resistor surrounded by an insulating material therein, comprising a pair of materials (2) arranged in a symmetrical manner and a space holder (26) interposed therebetween. In addition, the material 2 has a notch 24 inside both edges in the width direction, and the stopper 22 extending in both directions from the gap holding hole 26 is engaged with the notch 24. A housing for encapsulating a large capacity resistor, characterized in that. The heat radiation fins 12 are integrally formed on the outer surface of the flat portion 8 held by the pair of raw materials 2, respectively, or on either side in one piece. Housing for encapsulating a large capacity resistor, characterized in that.