1. Field of the Invention
The present invention relates to a relay with multiple coils, and more particularly to a relay having multiple coils disposed thereon for increasing an efficiency of an electromagnetic induction and lowering a consumption of the coils.
2. Description of Related Art
A relay is an electrically operated switch for controlling a circuit by applying a low electric current. The most common types of relays used are electromechanical relays, reed relays, and solid state relays, etc. A conventional electromagnetic relay in accordance with the prior art comprises an iron core. A single coil is wound around the iron core. A magnet is disposed above the iron core and the single coil. A spring is connected to the magnet for restoring the magnet. Accordingly, two distal ends of the single coil is respectively applied two different voltages to generate an electric current for passing through the single coil, such that a magnetic field is induced by the electric current for attracting the magnet to move toward the iron core. And when no electric current passes through the single coil, the magnetic field is disappeared. The magnet is drawn back by the spring.
However, the conventional electromagnetic relay only has the single coil. The induced magnetic field can be enhanced without changing the input voltages by increasing a length or a diameter of the coil or increasing a length of the iron core. This causes an increase of a size of the single coil and is inconvenient to dispose on a small-scale relay.
The present invention has arisen to mitigate and/or obviate the disadvantages of the conventional electromagnetic relay with a single coil.
The main objective of the present invention is to provide an improved relay with multiple coils for increasing an induced magnetic field.
To achieve the objective, a relay with multiple coils comprises a base having at least two fixed contacts disposed thereon, a coil assembly mounted on the base, the coil assembly further comprising at least one U-shaped armature, at least one U-shaped iron core, at least two tubular bobbins respectively and coaxially receive between the U-shaped armature and the U-shaped iron core, at least two coils respectively and coaxially wound around each of the tubular bobbins, a spring member movably located above the coil assembly, the spring member having at least two moving contacts respectively disposed on two opposite ends thereof for corresponding to each of the fixed contacts of the base, at least one protecting insulator rivetedly mounted on a bottom of the spring member, the top of the U-shaped armature enclosed by the protecting insulator such that the U-shaped armature is indirectly mounted on the spring member, at least one coil spring compressively disposed between the spring member and the coil assembly, the spring member selectively provides a restoring force between the moving contacts and the fixed contacts; wherein when each coil of the coil assembly is induced a magnetic field by supplying electric current, the U-shaped armature mounted on the spring member is magnetically attracted to move toward and connect with the U-shaped iron core by the magnetic field and the coil spring is vertically compressed by the U-shaped armature such that the two moving contacts simultaneously move downwardly to connect with the two fixed contacts of the base; when no electric current is supplied to the two coils and the magnetic field is disappeared, the coil spring provides the restoring force to draw the spring member backward such that the moving contact moves upwardly to leave the fixed contact again; thereby the relay acts as a switch for adapting to open/close a circuit connected to the relay.
Each of the U-shaped armatures has two spaced upper legs extending downwardly therefrom and each of the U-shaped iron cores has two spaced lower legs extending upwardly therefrom.
Each of upper legs has an indentation and each of the lower legs has a protrusion; thereby the U-shaped iron core is firmly engaged with the U-shaped armature by an engagement between the indentations and the protrusions.
Each of upper legs has a protrusion and each of the lower legs has an indentation; thereby the U-shaped iron core is firmly engaged with the U-shaped armature by an engagement between the indentations and the protrusions. Each tubular bobbin selectively has a round cross section or a square cross section.
Further benefits and advantages of the present invention will become apparent after a careful reading of the detailed description with appropriate reference to the accompanying drawings.
Referring to the drawings and initially to
A coil assembly 3 is mounted on the top of the base 1 and located between the two walls. The coil assembly 3 comprises at least one U-shaped armature 30 which has two spaced upper legs 301 extending downwardly therefrom, at least one U-shaped iron core 31 which has two spaced lower legs 311 extending upwardly therefrom, and at least two tubular bobbins 32 respectively and coaxially receive between the upper legs 301 of the U-shaped armature 30 and the lower legs 311 of the U-shaped iron core 31 (Here are one U-shaped armature 30, one U-shaped iron core 31 and one pair of tubular bobbins 32 in the present embodiment). Each tubular bobbin 32 has a square cross section. At least two coils 33 are respectively and coaxially wound around each of the tubular bobbins 32. Each of upper legs 301 has an indentation 302. Each of the lower legs 311 has a protrusion 312. The U-shaped iron core 31 is firmly engaged with the U-shaped armature 30 by an engagement between the indentations 302 and the protrusions 312, such that the engagement can prevent the U-shaped armature 30 and the U-shaped iron core 31 from bias movement due to any electromagnetic interaction between two tubular bobbins 32 with coils 33.
A spring member 2 is movably located above the coil assembly 3. The spring member 2 has at least two moving contacts 21 respectively disposed on two opposite ends thereof for corresponding to each of the fixed contacts 11 of the base 1 (Here is one pair of moving contacts 21 in the present embodiment). At least one protecting insulator. 22 is rivetedly mounted on a bottom of the spring member 2 (Here is one protecting insulator 22 in the present embodiment). The top of the U-shaped armature 30 is enclosed by the protecting insulator 22 such that the U-shaped armature 30 is indirectly mounted on the. spring member 2. At least one coil spring 23 is compressively disposed between the spring member 2 and the coil assembly 3 (Here is one coil spring 23 in the present embodiment). One end of the coil spring 23 is abutting against the protecting insulator 22 and another end of the coil spring 23 is abutting against the tubular bobbins 32. In this way, the spring member 2 selectively provides a restoring force between the moving contact 21 and the fixed contact 11.
The operation of the relay with multiple coils in accordance with the present invention will be described in detailed below. As shown in
As shown in
With reference to
With reference to
Therefore, the induced magnetic field of the conventional relay with a single coil maybe enhanced without changing the input voltages by increasing a length or a diameter of the coil or increasing a length of the iron core. The relay with multiple coils in accordance with the present invention overcomes above disadvantages by providing the multiple coils to increase the induced magnetic field and enhance the operation of the relay.
Although the invention has been explained in relation to its preferred embodiment, it is to be understood that many other possible modifications and variations can be made without departing from the spirit and scope of the invention as hereinafter claimed.
This application is a Continuation-In-Part Application of Ser. No. 12/857,561, filed 17 Aug. 2010, and entitled “RELAY WITH MULTIPLE COILS”, now pending.
Number | Date | Country | |
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Parent | 12857561 | Aug 2010 | US |
Child | 13489420 | US |