KR20160002735U - Over load device - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an overload protection device for a compressor motor, and more particularly, An input terminal and an output terminal which are formed of a predetermined conductive electric terminal and extend in and out of the housing to be connected to an external electrical device; And an overload protection means disposed in the housing and provided between the input terminal and the output terminal for opening and closing an electrical connection between the input terminal and the output terminal, And a cover for covering the base, wherein the overload protecting means comprises: a resistance heating body having a predetermined electrical resistance; A variable lead portion made of a material having conductivity and elastic restoring force and disposed on the resistance heating element and extending a predetermined length in the longitudinal direction; And a bimetal disposed between the resistance heating element and the variable lead portion and having a variable shape by heat; Wherein the resistance heating element is configured such that one end is electrically connected to the input terminal and the other end is electrically connected to the variable lead portion and is configured to radiate heat in accordance with the application of electric power, And a movable contact which is electrically connected to the other end of the resistance heating element and whose other end in the longitudinal direction is in contact with the output terminal to electrically connect the input terminal and the output terminal, To an overload protection device of a compressor motor configured to open and close an electrical connection between the movable contact and the output terminal.

Description

[0001] OVER LOAD DEVICE [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an overload protection device for a compressor motor, and more particularly, An input terminal and an output terminal which are formed of a predetermined conductive electric terminal and extend in and out of the housing to be connected to an external electrical device; And an overload protection means disposed in the housing and provided between the input terminal and the output terminal for opening and closing an electrical connection between the input terminal and the output terminal, And a cover for covering the base, wherein the overload protecting means comprises: a resistance heating body having a predetermined electrical resistance; A variable lead portion made of a material having conductivity and elastic restoring force and disposed on the resistance heating element and extending a predetermined length in the longitudinal direction; And a bimetal disposed between the resistance heating element and the variable lead portion and having a variable shape by heat; Wherein the resistance heating element is configured such that one end is electrically connected to the input terminal and the other end is electrically connected to the variable lead portion and is configured to radiate heat in accordance with the application of electric power, And a movable contact which is electrically connected to the other end of the resistance heating element and whose other end in the longitudinal direction is in contact with the output terminal to electrically connect the input terminal and the output terminal, To an overload protection device of a compressor motor configured to open and close an electrical connection between the movable contact and the output terminal.

BACKGROUND ART A conventional motor protection device used in a compressor such as a refrigerator or a refrigerator has a structure in which a current input from the outside of a device is transmitted to the inside through a terminal connected to the outside and is connected to a fixed contact electrically connected to the inside of the device through a movable contact And is conveyed directly to a fixed predetermined horizontal. The electric current delivered directly to the fixed side of one side is transmitted to the resistance heating element. The load current flowing into the compressor motor generates heat in the resistance heating element, and the bimetal is deformed when the temperature reaches a preset bimetal temperature. As a result of this operation, when the horizontal bar fixed to one side rises to the cover side, the movable contact which is electrically connected to the fixed contact is dropped and the electric supply is interrupted.

The configuration of the energizing path of a general refrigerator or refrigerator compressor motor protection device is as follows.

In order for the current outside the device to be introduced for the protection function inside the device, it is welded to the current input terminal and the plate for mounting the fixed contact. This fixed contact mounting steel plate is fitted in a hole formed in the base of the apparatus, and a fixed contact is welded to the upper face of the steel plate. The fixed contact is electrically connected to the movable contact welded to the movable side of the fixed horizontal bar. In order to fix the horizontal bar fixed on one side to the base, the horizontal bar fixing steel plate connected to one side of the resistance heating element is inserted into the hole formed on the base, and one side of the horizontal bar is fixed on the upper surface thereof. One of the resistance heating elements is connected to the resistance heating element connection part connected to the horizontal bar fixing steel plate and the other is connected to the external connection terminal inserted into the hole formed in the base.

When an excessive current flows through the energizing path, the resistance heating element on the energizing path generates heat. When this heat reaches the preset operating temperature of the bimetal, the bimetal is deformed and the fixed horizontal bar is moved So that the refrigerator compressor motor is protected.

In order to constitute the energizing path of the general compressor motor protection device, a contact plate, a horizontal bar fixing plate and an external terminal fixing plate are required at the base of the apparatus, and a predetermined hole is required for fixing each plate . Not only the arc generated during the operation of the apparatus can be discharged to the outside through the gap of the hole but also the contact plate and the terminals fitted to the hole can easily be bent easily due to shock, vibration, overheating, The deformed structure may cause unstable current flow, which may make it impossible to protect the overcurrent and overload of the compressor motor.

 In addition, each of the steel plates is exposed to the inside of the device, and the exposed steel plate reflects the arc generated when the fixed contacts and the variable contacts are switched, thereby accelerating the thermal deformation of the device, The heat generated from the heating element through the exposed steel plate is radiated and transferred, thereby reducing the life of the product.

Also, the internal explosion can be transmitted to the external combustible gas or the steam through the space formed by the hole formed in the base and the terminals connected to the outside, and the external explosive gas can be introduced into the interior.

There has been a demand for development of a protective device in which the complexity of the energizing path of the compressor motor protecting device such as the refrigerator or the refrigerator is stabilized in a simple form and the inside of the device is sealed and the electric safety is ensured.

Public utility model 2000-0013446

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and an object of the present invention is to provide a semiconductor device, An input terminal and an output terminal which are formed of a predetermined conductive electric terminal and extend in and out of the housing to be connected to an external electrical device; And an overload protection means disposed in the housing and provided between the input terminal and the output terminal for opening and closing an electrical connection between the input terminal and the output terminal, And a cover for covering the base, wherein the overload protecting means comprises: a resistance heating body having a predetermined electrical resistance; A variable lead portion made of a material having conductivity and elastic restoring force and disposed on the resistance heating element and extending a predetermined length in the longitudinal direction; And a bimetal disposed between the resistance heating element and the variable lead portion and having a variable shape by heat; Wherein the resistance heating element is configured such that one end is electrically connected to the input terminal and the other end is electrically connected to the variable lead portion and is configured to radiate heat in accordance with the application of electric power, And a movable contact which is electrically connected to the other end of the resistance heating element and whose other end in the longitudinal direction is in contact with the output terminal to electrically connect the input terminal and the output terminal, So that the shape of the movable contact and the output terminal can be varied to open and close the electrical connection between the movable contact and the output terminal.

According to an aspect of the present invention, there is provided an overload protection device for a compressor motor, comprising: a housing made of an insulating material; An input terminal and an output terminal which are formed of a predetermined conductive electric terminal and extend in and out of the housing to be connected to an external electrical device; And an overload protection means disposed in the housing and provided between the input terminal and the output terminal for opening and closing an electrical connection between the input terminal and the output terminal,

The housing includes a base in which the input terminal and the output terminal are buried and in which the overload protection means is accommodated, and a cover that covers the base,

The overload protecting means includes: a resistance heating element having a predetermined electrical resistance; A variable lead portion made of a material having conductivity and elastic restoring force and disposed on the resistance heating element and extending a predetermined length in the longitudinal direction; And a bimetal disposed between the resistance heating element and the variable lead portion and having a variable shape by heat; / RTI >

Wherein the resistance heating body is configured such that one end is electrically connected to the input terminal and the other end is electrically connected to the variable lead portion,

Wherein the variable lead portion comprises a stationary contact whose one end in the longitudinal direction is electrically connected to the other end of the resistance heating element and whose other end in the longitudinal direction is in contact with the output terminal to electrically connect the input terminal and the output terminal , And the shape of the bimetal varies as the shape of the bimetal changes, thereby opening and closing the electrical connection between the movable contact and the output terminal.

Preferably, the resistance heating body is constituted by a heating coil wound with a predetermined length, the heating coil is wound so as to extend in a torus shape, and the variable lead portion is provided on the upper side of the resistance heating body in a radial direction And the base has a coil receiving recess formed in a torus shape so as to receive the resistance heating body.

Preferably, the stationary contact and the movable contact are disposed on both sides in the radial direction of the resistance heating element.

Preferably, the bimetal is deformed in shape by heat generated in the resistance heating body so that the movable lead is displaced upward by pushing up the variable lead portion disposed at the upper portion in accordance with thermal deformation, And the contact between the output terminals is released.

Preferably, the bimetal is formed in a disc shape having a predetermined area. The bimetal has a curved dish shape and has a concave surface. The bimetal is configured to deform the variable lead portion by reversing the depression direction in accordance with thermal deformation.

Preferably, the overload protection means includes: a first contact terminal disposed on the output terminal; And a second contact terminal disposed on the movable contact of the variable lead portion; Wherein the first contact terminal and the second contact terminal are in contact with each other to be electrically connected to each other, and the variable lead portion is deformed in accordance with the deformation of the bimetal, so that a gap between the first contact terminal and the second contact terminal The distance is variable, and the electrical connection between the first contact terminal and the second contact terminal is opened and closed.

Preferably, the input terminal has a first internal exposed surface exposed in the housing to be connected to the variable lead portion and has a first external exposed surface connected to an external electrical device, And the space between the exposed surface and the first external exposed surface is surrounded by the insulating material constituting the base and is sealed.

Preferably, the output terminal has a second internal exposed surface exposed in the housing to be connected to the resistance heating element, and has a second external exposed surface connected to the external electrical device, And between the second outer exposed surfaces is surrounded by the insulating material constituting the base and is sealed.

Preferably, the overload protecting means further includes a connection terminal extending to connect the fixed contact of the variable lead portion to one end of the resistance heating body through the one end thereof, wherein the variable lead portion is provided on the upper side of the resistance heating body, The connection terminal is exposed in the housing so as to be connected to the fixed contact of the variable lead portion and a third internal exposed surface exposed in the housing to be connected to the resistance heating body, And a fourth inner exposed surface, wherein the first inner exposed surface and the first outer exposed surface are embedded and sealed by an insulating material constituting the base.

Preferably, the cover and the base are hooked.

Preferably, the surface on which the cover and the base are in contact with each other is provided with an uneven surface corresponding to each other.

According to the overload protection device for a compressor motor according to the present invention, when a predetermined power is applied and a predetermined operating temperature is reached, the bimetal is deformed to cut off the electrical connection, so that an overload of the compressor motor can be prevented simply and simply.

In addition, the present invention is characterized in that a member composed of a conductor for electrical flow is embedded in a base made of an insulating material and sealed and isolated so that the arc generated when switching between the fixed contact and the movable contact is reflected on the conductor, .

In addition, the present invention has the advantage that the inside of the housing is sealed with an insulator as a whole and the connection between the terminals is sealed and isolated so that the explosion inside does not cause external explosion and the inside of the combustible gas is prevented from entering, It is effective.

In addition, the present invention is characterized in that the conductive member constituting the device is integrated with the base, which is the insulating member, so that the conductive member is completely fixed and the conductive member is stably fixed to the deformation of the base caused by the electrical, There is an effect of reducing the failure occurrence rate of the apparatus.

In addition, since the present invention can omit the process of assembling the conductive members for electric flow by inserting the conductive members into the base, it is possible to automate the production of the device, thereby reducing deviation occurring between the devices, .

In addition, in the present invention, the base and the cover constituting the housing are formed with concavities and convexities, and the cover is covered with the base. Thus, the base and the cover are firmly coupled to each other to reliably seal the inside of the housing. , Dust, and the like, thereby reducing the occurrence of the failure of the product.

The present invention has a structure in which a base and a conductive member are integrated with each other without having a structure for inserting a conductive member into a base, so that a base residue generated when a conductor is inserted is positioned between the stationary contact and the movable contact, There is an effect of reducing a trouble that interferes with the user.

Also, since the conductive member is embedded in the base as described above, thermal conduction of heat generated in a conductive member acting as a heating element is minimized, thereby reducing thermal deformation of the device and ensuring accurate operation.

1 is a view illustrating a structure of an overload protection device for a compressor motor according to an embodiment of the present invention.
2 is a view showing a structure of an overload protection device for a compressor motor according to an embodiment of the present invention.
3 is a view showing a coupling structure of various members coupled to a base and a base of an overload protecting device of a compressor motor according to an embodiment of the present invention.
4 is a view showing a coupling structure of various members coupled to the base and the base of the overload protection device of the compressor motor according to one embodiment of the present invention.
5 is a view showing a coupling structure of various members coupled to the base and the base of the overload protection device of the compressor motor according to one embodiment of the present invention.
6 is a view illustrating a cover of an overload protecting apparatus for a compressor motor according to an embodiment of the present invention.
7 is a view showing an operation between a bimetal and a variable lead portion of an overload protection device for a compressor motor according to an embodiment of the present invention.
8 is a view showing the operation between the bimetal and the variable lead portion of the overload protecting device of the compressor motor according to the embodiment of the present invention.

Hereinafter, preferred embodiments according to the present invention will be described with reference to the accompanying drawings. The present embodiments are not intended to be limiting.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention, and how to accomplish them, will become apparent with reference to the embodiments described in detail below with reference to the accompanying drawings. It should be understood, however, that the present invention is not limited to the embodiments disclosed herein but may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein, To the person having the invention, and this invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout the specification.

Spatially relative terms such as "top," "bottom ", and the like can be used to easily describe one member or components and other components or components as shown in the figures. Spatially relative terms should be understood to include, in addition to the orientation shown in the drawings, terms that include different orientations of members during use or operation. For example, when a member shown in the drawing is laid, the "up-down direction" can be interpreted as "lateral direction ". Thus, the exemplary terms "up" and " up & down " The members can also be oriented in different directions, so that spatially relative terms can be interpreted according to orientation.

The terminology used herein is for the purpose of describing the embodiments and is not intended to limit the present invention. In the present specification, the singular form includes plural forms unless otherwise specified in the specification. &Quot; comprises, "and / or" comprising ", as used herein, unless the recited element, step, operation and / Or additions.

Unless defined otherwise, all terms (including technical and scientific terms) used herein may be used in a sense that is commonly understood by one of ordinary skill in the art to which this invention belongs. Also, commonly used predefined terms are not ideally or excessively interpreted unless explicitly defined otherwise.

The thickness and size of each member in the drawings are exaggerated, omitted, or schematically shown for convenience and clarity of explanation. Also, the size and area of each component do not entirely reflect actual size or area.

Also, in the embodiment, the angles and directions mentioned in the process of describing the structure of the present invention are based on those shown in the drawings. In the description of the structures constituting the present invention in the specification, reference points and positional relationships with respect to angles are not explicitly referred to, refer to the related drawings.

1 and 2 are views showing a structure of a compressor motor overload protection device 1 according to an embodiment of the present invention. FIGS. 3 to 5 are views showing a compressor motor overload protection device 1 according to an embodiment of the present invention 6 is a view showing a cover 120 of the compressor motor overload protection device 1 according to an embodiment of the present invention. FIG. 6 is a view showing a cover 120 of the compressor motor overload protection device 1 according to an embodiment of the present invention. FIGS. 7 and 8 are views showing the operation between the bimetal 330 and the variable lead portion 320 of the compressor motor overload protection device 1 according to an embodiment of the present invention.

A compressor motor overload protection device (1) according to the present invention comprises: a housing (100) composed of an insulating material; An input terminal 210 and an output terminal 220 which are formed of a predetermined conductive electric terminal and extend in and out of the housing 100 to be connected to an external electrical device; And an overload protection unit (250) disposed in the housing (100) and provided between the input terminal (210) and the output terminal (220) for opening / closing an electrical connection between the input terminal (300)

The housing 100 includes a base 110 in which the input terminal 210 and the output terminal 220 are embedded and the overload protecting means 300 is received and a cover 120 covering the base 110 Including,

The overload protecting means 300 includes: a resistance heating element 310 having a predetermined resistance; A variable lead portion 320 made of a material having a conductive and elastic restoring force and disposed on the resistance heating body 310 and extending a predetermined length in the longitudinal direction; And a bimetal (330) disposed between the resistance heating element (310) and the variable lead portion (320) and having a variable shape by heat; / RTI >

One end of the resistance heating element 310 is electrically connected to the input terminal 210 and the other end is electrically connected to the variable lead portion 320. The resistance heating element 310 is configured to dissipate heat according to the application of electric power,

The variable lead portion 320 is composed of a fixed contact 322 whose one end in the longitudinal direction is electrically connected to the other end of the resistance heating element 310 and whose other end is in contact with the output terminal 220 The movable contact 324 and the output terminal 220 are electrically connected to each other by changing the shape of the bimetal 330. The movable contact 324 and the output terminal 220 are electrically connected to each other, To open and close the electrical connection between the electrodes.

The housing 100 constitutes the appearance of the compressor motor overload protection device 1 according to the present invention. The housing 100 may be made of a predetermined mold made of a material such as plastic which is excellent in insulation and heat shielding as a whole. The housing 100 has a predetermined internal space for accommodating the overload protecting means 300 constituting the substantial body of the compressor motor overload protecting apparatus 1 of the present invention, And a cover 120 coupled to the base 110 to cover the overload protecting means 300 accommodated in the receiving space.

Meanwhile, at this time, preferably, the cover 120 and the base 110 may be hooked. 1 to 6, for example, the base 110 may include a hook 132 protruding upward, and the cover 120 may include a hook joint (not shown) to which the hook 132 is connected The coupling can be achieved in such a manner that the hook 132 fits into the hook joint 134 so that a simple connection between the cover 120 and the base 110 is achieved .

On the other hand, uneven surfaces may be formed on the surfaces of the cover 120 and the base 110 that are in contact with each other. That is, the cover 120 and the base 110 are configured such that the concave and convex portions 142 and 144 are respectively formed at the portions where the cover 120 and the base 110 are in contact with each other, and the concave and convex portions 142 and 144 are coupled to each other, It is possible to achieve a structure in which firm coupling between the concave and convex portions 142 and 144 is achieved and the hermeticity inside the housing 100 is improved.

In addition, a predetermined first barrier rib 152 and a second barrier rib 154 may be provided to fix the position of the variable lead portion 320 to be described later and block the heat.

An input terminal 210 and an output terminal 220 which are formed of a predetermined conductive electric terminal and extend to the inside and the outside of the housing 100 and are connected to an external electric device are provided. The input terminal 210 and the output terminal 220 are formed of a predetermined conductive electric terminal and extend to the inside and the outside of the housing 100. In the inside of the housing 100, And is connected to an external electric device from the outside of the housing 100. Meanwhile, a predetermined external terminal 160 may be provided to facilitate connection between the input terminal 210 or the output terminal 220 and an external electrical terminal, but is not limited thereto.

The overload protection means (300) constitutes the main body of the compressor motor overload protection device (1) according to the present invention. The overload protection means 300 is disposed inside the housing 100 and is provided between the input terminal 210 and the output terminal 220 to electrically connect the input terminal 210 and the output terminal 220 to each other. Open or close the connection.

Specifically, the overload protecting means 300 includes: a resistance heating element 310 having a predetermined electrical resistance; A variable lead portion 320 made of a material having a conductive and elastic restoring force and disposed on the resistance heating body 310 and extending a predetermined length in the longitudinal direction; And a bimetal (330) disposed between the resistance heating element (310) and the variable lead portion (320) and having a variable shape by heat; .

The resistance heating element 310 is a member having an electrical resistance and may be constituted by a coil wound to a predetermined length or in a form capable of generating heat according to a resistance and one end is electrically connected to the input terminal 210 And the other end is electrically connected to the variable lead portion 320. The resistance heating element 310 is configured to radiate heat when electricity is applied as it has a coiled coil structure as shown in the drawing, or has a coiled structure or a heatable form such as a plate having a resistance, And may have a proper winding structure, length, shape, and the like so that heat of a predetermined temperature is generated in accordance with a predetermined power application.

The bimetal 330 is disposed between the resistance heating element 310 and the variable lead portion 320 and is configured to vary in shape by heat. That is, as the bimetal 330 is disposed adjacent to the resistance heating body 310, the shape of the bimetal 330 can be varied by heat generated from the resistance heating body 310. Since the shape of the bimetal 330 is variable when the bimetal 330 reaches a predetermined operating temperature, when the predetermined resistance is applied to the resistance heating body 310 as described above, the resistance heating body 310 is operated at a predetermined temperature or higher It can be understood that the shape of the bimetal 330 varies depending on the application of the predetermined power.

The variable lead portion 320 is provided to electrically connect the input terminal 210 and the resistance heating body 310. The variable lead portion 320 may include a fixed contact 322 extending in a predetermined length and electrically connected to the other end of the resistance heating element 310 at one end in the longitudinal direction, And a movable contact point 324 contacting the movable contact point. Accordingly, the variable lead portion 320 can electrically connect the input terminal 210 and the output terminal 220 to each other.

The bimetal 330 is positioned between the variable lead 320 and the resistance heating body 310 and the bimetal 330 is formed to be in contact with the bimetal 330 as the shape of the bimetal 330 varies according to heat. The variable lead portion 320 may also have a variable shape. At this time, the variable lead portion 320 is made of a material having an elastic restoring force in addition to the electrical conductivity so that the shape of the lead portion 320 can be varied and restored. For example, the variable lead portion 320 may be made of a material such as copper. In addition, it can be constituted by a plate-like member having a predetermined length and area so that the shape can be easily changed and restored.

Meanwhile, a predetermined fixed iron piece 326 is provided to fix the variable lead portion 320 to the base 110, facilitate the deformation and displacement of the variable lead portion 320, and improve electrical conductivity . The fixed iron piece 326 may be fixed on the upper surface of the fixed contact 322 of the variable lead portion 320 in a welding manner and the connection terminal 360 and the variable lead portion 320, So that they can be firmly connected.

The electrical connection between the movable contact 324 of the variable lead portion 320 and the input terminal 210 can be opened or closed as the shape of the variable lead portion 320 varies. More specifically, when the movable contact 324 of the variable lead portion 320 contacts the input terminal 210, electrical connection is established and the variable lead portion 320 is deformed by the change of the shape of the bimetal 330. [ The electrical connection between the input terminal 210 and the variable lead portion 320 can be released when the movable contact 324 is separated from the input terminal 210. [

In this case, as described above, the shape change of the bimetal 330 is performed by applying predetermined power and generating a predetermined operating temperature. As a result, when a predetermined power is applied, the variable lead 320 and the input The electric connection between the terminals 210 is released. This is because when the power exceeding the predetermined limit is applied, the electric connection of the compressor motor overload protection device 1 according to the present invention is released to protect the overload . ≪ / RTI >

Hereinafter, specific embodiments and configurations of the compressor motor overload protection device 1 according to the present invention will be described.

Preferably, when the resistance heating element 310 is formed in a coil shape, the variable resistance portion 320 is wound to extend in an annular shape, and the variable resistance portion 320 is wound on the resistance heating body 310, And the base 110 has a recess for accommodating the resistance heating body 310 in a torus shape so as to receive the resistance heating body 310. The resistance heating body 310 is formed by cutting the resistance heating body 310 in a radial direction.

That is, as shown in the drawing, the resistance heating body 310 is wound or manufactured in a toric shape so that the variable lead portion 320 is formed on the resistance heating body 310 of the annular shape, 310 across the resistance heating element 310 in the radial direction. The fixed contact point 322 and the movable contact point 324 provided at both ends in the longitudinal direction of the variable lead portion 320 can be respectively disposed on both side portions in the radial direction of the resistance heating element 310 .

According to the arrangement and the shape, heat generation by the resistance heating element 310 is easily performed, and the generated heat can be easily transmitted to the bimetal 330. In addition, the deformation of the variable lead portion 320 is also deformed in the longitudinal direction, so that the deformation of the variable lead portion 320 facilitates electrical connection and disconnection. In order to accommodate the resistance heating body 310, the base 110 may be provided with a resistance heating body 310 corresponding to the shape of the resistance heating body 310, The coil receiving recess 112 in which the resistance heating body 310 is accommodated can be formed.

At this time, the bimetal 330 is deformed by the heat generated from the resistance heating element 310, and pushes up the variable lead portion 320 disposed at the upper portion according to thermal deformation, so that the movable contact 324 The contact between the movable contact 324 and the output terminal 220 is released.

That is, the bimetal 330 may be disposed between the variable lead portion 320 and the resistance heating body 310, and may be configured to push up the variable lead portion 320 disposed at the upper portion in accordance with thermal deformation have. 7 and 8, one end in the longitudinal direction of the variable lead portion 320 is composed of the fixed contact 322. Accordingly, the variable lead portion 320 is connected to the bipolar plate 330, The other end constituted by the movable contact 324 may be tilted about the fixed contact 322 as shown by the arrow B by thermal deformation such as A in FIG. The movable contact 324 is displaced upward and the distance between the movable contact 324 and the input terminal 210 is increased so that the contact between the movable contact 324 and the input terminal 210, The connection can be released.

Preferably, the bimetal 330 is formed in a disc shape having a predetermined area. The bimetal 330 has a curved dish shape and has a recessed surface 332. The depressed direction is reversed in accordance with thermal deformation, 320 may be deformed.

That is, as shown in FIGS. 7 and 8, the bimetal 330 has a recessed surface 332 having an inner surface recessed like a dish, and has a configuration in which the recessed direction is reversed as heat is applied and deformed Lt; / RTI > Here, in a normal state in which there is no thermal deformation, there is a downwardly recessed arrangement, and in a deformed state in accordance with thermal deformation, the depressed direction is inverted and may have a depressed shape upwardly. In other words, the dish-shaped bimetal 330 can be deformed into an inverted form as the heat is applied.

The variable lead portion 320 disposed on the bimetal 330 and in contact with the bimetal 330 is pushed by the bimetal 330 so that the contact between the movable contact 324 and the input terminal 210 Can be achieved. Of course, as described above, since the variable lead portion 320 is made of a material having resiliently deformed and restoring force, when the bimetal 330 reaches the predetermined return temperature and is restored to its original state, the shape of the variable lead portion 320 And the electrical connection between the movable contact 324 and the input terminal 210 is again established.

At this time, preferably, the overload protecting means 300 includes: a first contact terminal 340 disposed on the input terminal 210; And a second contact terminal (350) disposed on the movable contact (324) of the variable lead portion (320); As shown in FIG.

The first contact terminal 340 and the second contact terminal 350 are disposed at the input terminal 210 and the movable contact 324 of the variable lead portion 320, respectively. The first contact terminal 340 and the second contact terminal 350 are formed of conductive terminals having excellent conductivity so that contact between the input terminal 210 and the variable lead portion 320 is easily achieved. Accordingly, the first contact terminal 340 and the second contact terminal 350 are in contact with each other and are electrically connected to each other, and the variable lead portion 320 is deformed according to the deformation of the bimetal 330, The distance between the first contact terminal 340 and the second contact terminal 350 can be varied so that the electrical connection between the first contact terminal 340 and the second contact terminal 350 is opened or closed Configuration.

The input terminal 210 preferably has a first internal exposed surface 212 exposed in the housing 100 to be connected to the variable lead portion 320, And the first outer exposed surface 212 and the first outer exposed surface 214 are surrounded by an insulating material constituting the base 110 and sealed.

That is, the input terminal 210 is formed of a predetermined conductive terminal, and is connected to the inside and the outside of the housing 100, and is exposed inside the housing 100 to be connected to the variable lead portion 320 And a first external exposed surface 214 exposed outside of the housing 100 and connected to an external electrical device. A portion between the first outer exposed surface 214 and the first inner exposed surface 212 is embedded in the base 110. That is, a portion between the first outer exposed surface 214 and the first inner exposed surface 212 may be embedded and sealed with an insulating material constituting the base 110. To accomplish this, the base 110 may have a predetermined first cover region 114 that covers the input terminal 210, and the base 110 may include a plurality of input terminals 210, And may be constituted by injecting and curing a predetermined material in a state of being located in the mold.

The output terminal 220 preferably has a second internal exposed surface 222 exposed in the housing 100 to be connected to the variable lead portion 320 and connected to the external electrical device And the second outer exposed surface 224 is surrounded by the insulating material constituting the base 110 and sealed between the second inner exposed surface 222 and the second outer exposed surface 224. [ .

That is, like the above-described input terminal 210, the output terminal 220 is formed of a predetermined conductive terminal, and is connected to the inside and the outside of the housing 100, and is exposed inside the housing 100 A second internal exposed surface 222 to be connected to the resistance heating element 310 and a second external exposed surface 224 exposed outside the housing 100 and connected to an external electrical device. A portion between the second outer exposed surface 224 and the second inner exposed surface 222 is buried in the base 110. That is, a portion between the second outer exposed surface 224 and the second inner exposed surface 222 may be embedded and sealed with an insulating material constituting the base 110. In order to achieve this, the base 110 may have a second cover region 116 covering the output terminal 220, and the base 110 may have the output terminal 220 described above, A predetermined material is injected and cured in a state of being placed in a mold of a mold.

The input terminal 210 and the output terminal 220 are provided as described above and the input terminal 210 and the output terminal 220 are embedded in the base 110 except for a predetermined exposed surface, The area where the input terminal 210 and the output terminal 220 are unnecessarily exposed may be reduced.

That is, when the input terminal 210 and the output terminal 220 are excessively exposed in the housing 100, heat generated in the exposed portion may inadvertently thermally deform the bimetal 330 , Which may interfere with the intended correct power and strain at operating temperatures. However, according to the present invention, as the input terminal 210 and the output terminal 220 are buried in the base 110 except for a predetermined exposed surface, unnecessary heat exposure to the bimetal 330 as described above Overload protection at the correct power and operating temperature can be achieved.

The overload protection means 300 preferably includes a connection terminal 360 extending to connect the fixed contact point 322 of the variable lead portion 320 to one end of the resistance heating element 310, ; ≪ / RTI > That is, one end of the fixed contact point 322 of the variable lead portion 320 and the end of the resistance heating element 310 may be connected to each other through a connection terminal 360 formed of the predetermined conductive terminal .

The connection terminal 360 includes a third internal exposed surface 362 exposed in the housing 100 to be connected to the resistance heating element 310 and a second internal exposed surface 362 connected to the fixed contact of the variable lead portion 320 And a fourth inner exposed surface (364) exposed in the housing (100) so that the first inner exposed surface (212) and the first outer exposed surface (214) And may be buried and surrounded by an insulating material.

In other words, like the input terminal 210 and the output terminal 220 described above, the connection terminal 360 may have a third internal exposed surface 362 and a fourth internal exposed surface 364 exposed inside the housing 100 And may be connected to the resistance heating body 310 and the fixed contact 322 of the variable lead portion 320, respectively. Accordingly, the connection terminal 360 may also be provided by injecting and curing a predetermined material in a state where the connection terminal 360 is located in a predetermined mold.

The connection terminal 360 is provided as described above and the connection terminal 360 connects the resistance heating body 310 and the variable lead portion 320 so that the resistance heating body 310, The area where the connection region between the housing 100 and the housing 320 is exposed to the outside can be reduced.

That is, when the resistance heating body 310 and the variable lead portion 320 are connected to each other by providing the base 110 and the resistance heating body 310 and the variable lead portion 320 are connected to each other, the position of the resistance heating body 310 and the position of the variable lead portion 320 The connection can be extended for a long time, and accordingly, the extended portion can be excessively exposed inside the housing 100. [0051] As shown in FIG. In this case, heat generated in the exposed portion may inadvertently thermally deform the bimetal 330, which may interfere with the intended correct power and deformation at the operating temperature. However, according to the present invention, the connection terminal 360 is provided, and most of the area except for the third inner exposed surface 362 and the fourth inner exposed surface 364 is formed in the The bimetal 330 is prevented from being unnecessarily exposed to heat, so that the overload protection can be performed at the correct power and operating temperature. Meanwhile, a predetermined third cover region 118 covering the connection terminal 360 may be provided.

According to the compressor motor overload protection device 1 according to the present invention, when the predetermined electric power is applied and the bimetal 330 reaches a predetermined operating temperature, the bimetal 330 is deformed to cut off the electrical connection, And the overload of the compressor motor can be prevented simply.

In addition, in the present invention, a member composed of a conductor for electrical flow is embedded in a base 110 made of an insulating material and sealed and isolated, so that an arc generated upon switching of the fixed contact 322 and the movable contact 324 The phenomenon of reflection and generation of radiant heat can be eliminated. That is, in the conventional case, when switching between the fixed contact point 322 and the movable contact point 324 of the variable lead portion 320, a predetermined arc is generated and reflected in the operation process. However, in the present invention, The output terminal 220, and the connection terminal 360 may be embedded in the base 110 to prevent generation and reflection of the arc.

In addition, the present invention is characterized in that the conductive member constituting the device is integrated with the base 110, which is the insulating material, so that the conductive member is completely fixed so that the deformation of the base 110 caused by the electrical, Is stably fixed and there is an effect of reducing the overall failure rate of the apparatus. That is, by positioning the members in a predetermined mold such that the input terminal 210, the output terminal 220, and the connection terminal 360 are embedded in the base 110 and injecting the plastic casting into the mold, ), So that the conductive member may be embedded in the base 110. So that the member can be stably fixed to the base 110.

In addition, according to the above, the present invention can omit the process of assembling the conductive members for the electric flow by inserting the conductive members into the base 110, so that it is possible to automate the production of the device, The product can be produced. The present invention has a structure in which the base 110 and the conductive member are integrated with each other without having a structure for inserting the conductive member into the base 110. The base 110 residues, which are generated when the conductive member is inserted, 322 and the movable contact 324, thereby reducing the malfunction that disturbs the electrical connection.

In addition, the present invention is configured such that the conductive member is embedded in the base 110 as described above, thereby minimizing the thermal conduction generated by the conductive member acting as the heating element, thereby reducing thermal deformation of the device and ensuring accurate operation have. In other words, the cover regions 114 and 116 and the barrier ribs 152 and 154 are provided so that the conductive member is buried in the base 110 and unnecessary heat transmission is blocked so that unnecessary heat radiation to the bimetal 330, The operation at the correct operating temperature can be ensured.

In addition, in the present invention, the inside of the housing 100 as a whole is sealed by an insulator, and the connection portion between the terminals is sealed and isolated so that the internal explosion does not cause external explosion and prevents entry of the external combustible gas It is possible to secure safety.

The present invention is configured such that the base 110 and the cover 120 constituting the housing 100 are formed with concavities and convexities and the cover 120 is covered on the base 110, The interior of the housing 100 is reliably sealed so that the inflow of water, gas, dust, and the like from the outside is prevented, thereby reducing the failure rate of the product.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It should be understood that various modifications can be made by those skilled in the art, and such modifications are not to be understood individually from the technical idea or viewpoint of the present invention.

1: compressor overload protection device
100: Housing
112:
110: Base
112: receiving groove
114: first cover area
116: second cover area
118: third cover area
120: cover
132: Hook
134: hook joint
142:
144:
152: first partition
154: second partition
160: External terminal
210: input terminal
212: first inner exposed surface
214: first outer exposed surface
220: Output terminal
222: second inner exposed surface
224: second outside exposed surface
300: Overload protection
310: Resistance heating element
320: variable lead portion
322: Fixed contact
324: Adjustable contact point
326: Fixed iron piece
330: Bimetal
332: Depressed surface
340: first contact terminal
350: second contact terminal
360: Connection terminal
362: third inner exposed surface
364: fourth inner exposed surface

Claims (11)

An overload protection device for a compressor motor,
A housing made of an insulating material;
An input terminal and an output terminal which are formed of a predetermined conductive electric terminal and extend in and out of the housing to be connected to an external electrical device; And
And an overload protection means disposed in the housing and provided between the input terminal and the output terminal for opening and closing an electrical connection between the input terminal and the output terminal,
The housing includes:
A base in which the input terminal and the output terminal are embedded and in which the overload protection means is accommodated,
And a cover for covering the base,
The overload protecting means includes:
A resistance heating element having a predetermined electrical resistance;
A variable lead portion made of a material having conductivity and elastic restoring force and disposed on the resistance heating element and extending a predetermined length in the longitudinal direction; And
A bimetal disposed between the resistance heating body and the variable lead portion and having a variable shape by heat; / RTI >
Wherein the resistance heating body is configured such that one end is electrically connected to the input terminal and the other end is electrically connected to the variable lead portion,
The variable lead portion includes:
And one end in the longitudinal direction is constituted by a fixed contact electrically connected to the other end of the resistance heating element,
And the other end in the longitudinal direction is constituted by a movable contact which contacts the output terminal,
Electrically connecting the input terminal and the output terminal,
And an electrical connection between the movable contact and the output terminal is opened or closed by varying the shape of the bimetal as the shape of the bimetal varies. The method according to claim 1,
The resistance heating body may include:
And a heating coil wound with a predetermined length,
The heat-
And is wound so as to extend in a torus shape,
The variable lead portion includes:
Wherein the heat generating coil is disposed on an upper portion of the heat generating coil so as to cross the heat generating coil in the radial direction,
The base includes:
An overload protection device for a compressor motor having a coil receiving recess formed to be recessed in a torus shape to receive the heat generating coil. The method according to claim 1,
Wherein the stationary contact and the movable contact,
Wherein the heat generating coils are disposed on both side portions in the radial direction of the heat generating coil. The method according to claim 1,
The bimetal may comprise,
The shape is changed by heat generated in the heat generating coil,
The movable lead is displaced upward by pushing up the variable lead portion disposed at the upper portion in accordance with thermal deformation,
And the contact between the movable contact and the output terminal is released. The method of claim 4,
The bimetal may comprise,
And has a disc shape having a predetermined area,
Having a curved dish shape and having a recessed surface,
And the depression direction is reversed in accordance with thermal deformation to deform the variable lead portion. The method of claim 4,
The overload protecting means includes:
A first contact terminal disposed on the input terminal; And
A second contact terminal disposed at the movable contact of the variable lead portion; Further comprising:
Wherein the first contact terminal and the second contact terminal are in contact with each other and are electrically connected,
The variable lead portion is deformed according to the deformation of the bimetal, and the distance between the first contact terminal and the second contact terminal is varied,
And an electrical connection between the first contact terminal and the second contact terminal is opened or closed. The method according to claim 1,
The input terminal
And a first inner exposed surface exposed in the housing to be in contact with and connectable to the variable lead portion,
And having a first external exposed surface connected to an external electrical device,
Between the first inner exposed surface and the first outer exposed surface
Wherein the base is embedded and sealed by an insulating material constituting the base. The method according to claim 1,
Wherein the output terminal comprises:
And a second internal exposed surface exposed in the housing to be connected to the resistance heating element,
And a second external exposed surface connected to the external electrical device,
And between the second inner exposed surface and the second outer exposed surface
Wherein the base is embedded and sealed by an insulating material constituting the base. The method according to claim 1,
The overload protecting means includes:
And a connection terminal extending to connect the fixing contact of the variable lead portion and one end of the resistance heating body through the one end,
The variable lead portion includes:
Wherein the resistance heating body is disposed across the resistance heating body in a radial direction,
The connection terminal includes:
And a third internal exposed surface exposed in the housing to be connected to the resistance heating element,
And a fourth inner exposed surface exposed in the housing to be connected to the fixed contact of the variable lead portion,
Between the third inner exposed surface and the fourth outer exposed surface
Wherein the base is embedded and sealed by an insulating material constituting the base. The method according to claim 1,
The cover and the base,
Overload protection device for compressor motor connected by hook. The method according to claim 1,
On the surface where the cover and the base are in contact with each other,
Wherein the uneven surface is formed to correspond to each other.

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