1. Field of the Invention
The present invention relates to an electromagnetic relay and, particularly, to an electromagnetic relay for forward reverse control, such as a motor and a solenoid.
2. Description of the Related Art
In such forward reverse control circuit 1, since the terminal 4a of the load 4 is connected to the GND via a contact 2e of the first electromagnetic relay 2 and the terminal 4b is connected to the GND via a contact 3e of the second electromagnetic relay 3 in a normal state (when the first and the second electromagnetic relays 2 and 3 are in a non-excitation state), the load 4 does not operate in the normal state.
When a control voltage is applied to a coil terminal 2d of the first electromagnetic relay 2, a coil 2f of the first electromagnetic relay 2 is excited to change the position of the contact 2e, so that the terminal 4a of the load 4 is connected to the +E via the contact 2e of the first electromagnetic relay 2. In such state, the second electromagnetic relay 3 is turned off, and the terminal 4b of the load 4 is connected to the GND via the contact 3e of the second electromagnetic relay 3, so that a current flows to the load 4 in a direction (see an arrow A) of “+E→contact 2e of first electromagnetic relay 2→terminal 4a of load 4→terminal 4b of load 4→contact 3e of second electromagnetic relay 3→GND”.
When a control voltage is applied to a coil terminal 3d of the second electromagnetic relay 3, a coil 3f of the second electromagnetic relay 3 is excited to change the position of the contact 3e, so that the terminal 4b of the load 4 is connected to the +E via the contact 3e of the second electromagnetic relay 3. In such state, the first electromagnetic relay 2 is turned off, and the terminal 4a of the load 4 is connected to the GND via the contact 2e of the first electromagnetic relay 2, so that a current flows to the load 4 in a reverse direction (see an arrow B) of “+E→contact 3e of second electromagnetic relay 3→terminal 4b of load 4→terminal 4a of load 4→contact 2e of first electromagnetic relay 2→GND”.
As described above, since it is possible to change the direction of driving current applied to the load 4 such as a motor and a solenoid by the use of the forward reverse control circuit 1 of
By the way, since the forward reverse control circuit 1 of
Each of the pair of moving contact springs 13 and 14 is an L-shaped flat plate spring, and the moving contact spring 13 is disposed on the moving contact spring 14. Therefore, when the base 6 is viewed from above, the moving contact spring 14 cannot be seen since it is hidden under the moving contact spring 13.
A terminal 13a for connecting a load 17 is formed on a fixed end of the moving contact spring 13, and a terminal 14a for connecting a load 17 is formed on a fixed end of the moving contact spring 14. Moving contacts 13b and 13c are attached to opposite sides of the swinging end of the moving contact spring 13, and moving contacts 14b and 14c are attached to opposite sides of the swinging end of the moving contact spring 14.
The fixed contact terminal plate 15 is provided with a fixed terminal 15a for connecting to the +E and the GND, and the fixed contact terminal plate 16 is provided with a fixed terminal 16a for connecting to the +E and the GND. Fixed contacts 15b, 15c, 16b, and 16c are attached to the fixed contact terminal plates 15 and 16 at predetermined positions. The fixed contacts 15b, 15c, 16b, and 16c contact the moving contacts 13b, 13c, 14b, and 14c in predetermined combinations when the electromagnets 7 and 8 are excited.
The predetermined combinations are (1) the moving contact 13b and the fixed contact 15b, (2) the moving contact 13c and the fixed contact 16c, (3) the moving contact 14b and the fixed contact 16b, and (4) the moving contact 14c and the fixed contact 15c.
With such constitution, when the electromagnets 7 and 8 are not excited, the combinations of (2) the moving contact 13c and the fixed contact 16c and (3) the moving contact 14b and the fixed contact 16b are employed so that the GND is supplied to both ends of the load 17. When the electromagnet 7 on the left hand side in
When the electromagnet 8 on the right hand side in
[Patent Literature 1] Japanese Patent No. 2890581
The above-described conventional technology has the following drawbacks.
(1) Large Base Size
The length La of the base 6 is at least a total of a shaft length Lb of the electromagnets 7 and 8, a length Lc required for the movements of the armatures 9 and 10, and a length Ld required for mounting the two fixed contact terminal plates 15 and 16. In view of a mounting space in an appliance, it is desired that the lengths Lb, Lc, and Ld should be small as possible. Since the lengths Lb and Lc depend on the size of the electromagnets 7 and 8, an electromagnet appropriate for downsizing (electromagnet having a smaller Lb and Lc) is naturally used. Accordingly, a last object left for downsizing is the length Ld.
In order to downsize the length Ld, a thickness of the fixed contact terminal plates 15 and 16 and a gap between the fixed contact terminal plates 15 and 16 may be reduced, and the fixed contact terminal plates 15 and 16 may be disposed as close as possible to the electromagnets 7 and 8.
However, there are limits for the downsizing of the thickness and the gap of the fixed contact terminal plates 15 and 16 because the size of the fixed contact terminal plates 15 and 16 should no be smaller than the sizes of the contacts 15c, 15b, 16c, and 16b. Also, in order not to disturb the electrical insulation and the movements of the moving contact springs 13 and 14, the distance to the electromagnets 7 and 8 cannot be reduced by a large scale. Accordingly, since it is impossible to eliminate the length Ld in the constitution of the conventional technology, the conventional technology has the drawback of the long length (La) of the base 6 due to the length Ld.
(2) Difference in Spring Constant
A length of the moving contact spring 14 disposed under the moving contact spring 13 is shorter than a length of the moving contact spring 13. The difference in length is set in order to avoid disturbances between the moving contact springs 13 and 14 because each of the moving contact springs 13 and 14 is formed from a flat and L-shaped plate, and that the terminals 13a and 14a are formed on the ends of the L-shaped flat plates.
When lengths of a pair of plate springs formed from an identical spring material are varied, one of the springs becomes soft, and the other spring becomes hard, i.e., spring constants are varied. The same is applicable to the moving contact springs 13 and 14 of the conventional technology. Such difference in spring constant requires an independent designing of coils (the coils of the electromagnets 7 and 8) for driving the moving contact springs 13 and 14. That is, it is necessary to vary a resistance value depending on the coils in order to generate an appropriate attraction force in accordance with the spring constants or to design component parts independently for the coils. However, with such designing, designing of the appliance into which the electromagnetic relay 5 is to be integrated will be complicated due to the difference in coil resistance and the troublesome designing of different component parts.
In view of the above-described circumstance, an object of this invention is to provide an electromagnetic relay which resolves the problems of the large size base and the difference in spring constant.
An aspect of the invention is an electromagnetic relay comprising: housing, in a predetermined facing gap defined between a first electromagnet unit and a second electromagnetic unit disposed parallelly to each other on a base in such a fashion that axial directions thereof are oriented to an identical direction, a first moving contact spring and a second moving contact spring disposed in such a fashion as to be overlaid along a vertical direction on the base and an A-fixed terminal unit and a B-fixed terminal unit provided with a plurality of contacts with which contacts of the first and the second moving contact springs selectively contact depending on a state of excitation/non-excitation of the first and the second electromagnet units; and disposing at least one of component parts of the first electromagnet unit and the second electromagnet unit on an electric connection passage between the first and the second moving contact springs and a pair of C-terminals.
As used herein, the A-fixed terminal unit means a fixed terminal unit having an A-contact, i.e. a normal open contact. Likewise, the B-fixed terminal unit means a fixed terminal unit having a B-contact, i.e. a normal close contact.
Also, the overlaying along the vertical direction on the base means that, when a platform of the base is a horizontal plane, one of the first moving contact spring and the second moving contact spring is disposed above the other one along a line or plane making a right angle with the horizontal plane (the upper moving contact spring is detached from the horizontal plane, and the lower moving contact spring is disposed closer to the horizontal plane).
Also, the at least one of component parts may be the yoke of each of the first electromagnet unit and the second electromagnet unit.
In this invention, the moving contact springs, the A-terminal unit, and the B-terminal unit are housed in the facing gap of the electromagnet units, and the moving contact springs are electrically connected to the C-terminals via the component parts of the electromagnet units.
Another aspect of the invention is an electromagnetic relay comprising: a) disposing a first electromagnet unit and a second electromagnet unit on a rectangular base made from an insulating material in such a fashion that one side of the first electromagnet unit is parallel to one side of the second electromagnet unit with a predetermined facing gap being defined therebetween and mounting an A-fixed terminal unit and a B-fixed terminal unit in the facing gap; b) attaching a first moving contact spring and a first return spring to a first iron piece disposed adjacent to a magnetic pole of the first electromagnet unit and fixing a tip of the first return spring to a first yoke disposed along the side of the first electromagnet unit; c) attaching a second moving contact spring and a second return spring to a second iron piece disposed adjacent to a magnetic pole of the second electromagnet unit and fixing a tip of the second return spring to a second yoke disposed along the side of the second electromagnet unit; d) overlaying the first moving contact spring and the second moving contact spring along a vertical direction on the base; and e) contacting a contact of the first moving contact spring and a contact of the second moving contact spring to a contact of the B-fixed terminal unit when both of the first electromagnet unit and the second electromagnet unit are not excited, contacting the contact of the first moving contact spring to the A-fixed terminal unit when the first electromagnet unit is excited, and contacting the contact of the second moving contact to the A-fixed terminal unit when the second electromagnet unit is excited.
With this invention, thanks to the item a), it is possible to keep a length of one of four sides of the base, which is parallel to a shaft of the electromagnet units, to be substantially equal to a length of the electromagnet units without influences of presence of the A-fixed terminal unit and the B-fixed terminal unit. Therefore, it is possible to downsize the base, thereby realizing an electromagnetic relay of a small mounting area.
Also, thanks to the item b), it is possible to retain the first iron piece at an initial position by a spring force of the first return spring when the first electromagnet unit is not excited, while it is possible to cause the first iron piece to approach to the magnetic pole of the first electromagnet unit against the spring force of the first return spring when the first electromagnet unit is excited.
Also, thanks to the item c), it is possible to retain the second iron piece at an initial position by a spring force of the second return spring when the second electromagnet unit is not excited, while it is possible to cause the second iron piece to approach to the magnetic pole of the second electromagnet unit against the spring force of the second return spring when the second electromagnet unit is excited.
Also, thanks to the item d), it is possible to avoid mutual disturbances of the first and the second moving contact springs, so that the first and the second iron pieces return to the initial positions and the first and the second moving contact springs approach in a swinging manner to the magnetic poles without any disturbance.
Also, thanks to the item e), it is possible to switch the contacts of the first and the second moving contact springs independently between the B-contact (normal close contact) and the A-contact (normal open contact) depending on the combinations of excitation and non-excitation of the first and the second electromagnet units, thereby making it possible to perform a forward reverse control of a motor or a solenoid, for example.
Still another aspect of the invention is the electromagnetic relay according to the aspect of the invention, wherein the first iron piece, the first return spring, and the first yoke are included in an electrical connection passage between one of a pair of C-terminals and the contact of the first moving contact spring, and the second iron piece, the second return spring, and the second yoke are included in an electrical connection passage between the other one of the C-terminals and the contact of the second moving contact spring.
With this invention, the C-terminals are electrically connected to the first and the second moving contact springs via the first and the second yoke and the first and the second return springs. Accordingly, it is unnecessary to connect the C-terminals to the first and the second moving contact springs by using a dedicated wiring or the like. Therefore, since troubles otherwise caused by disconnection do not occur, a production cost is reduced, and reliability is improved.
According to the invention, since the moving contact springs, the A-fixed terminal unit, and the B-fixed terminal unit are housed in the facing gap between the electromagnet units, it is possible to keep a length of one of four sides of the base, which is parallel to a shaft of the electromagnet units, to be substantially equal to a length of the electromagnet units without influences of presence of the A-fixed terminal unit and the B-fixed terminal unit. Therefore, it is possible to downsize the base, thereby realizing an electromagnetic relay of a small mounting area.
Also, since the moving contact springs are electrically connected to the C-terminals via the component parts of the electromagnet units, it is unnecessary to form the C-terminals integrally with the moving contact springs as in the conventional technology (see the terminals 13a and 14a of
Hereinafter, one embodiment of this invention will be described based on the drawings. Identifications and examples of details as well as exemplifications of values, letters, and other symbols in the following description are not more than references used for clarifying idea of this invention, and it is apparent that the idea of this invention is not limited by whole or part of the references. Also, explanations for known methods, known processes, known architectures, known circuit constitutions, and the like (hereinafter referred to as known particulars) are avoided in the following description, and such avoidance is for the purpose of simplifying the description and is not for the purpose of excluding whole or part of the known particulars. Since the known particulars had been familiar to those skilled in the art at the time of filing of this patent application, the known particulars are naturally included in the following description.
The second electromagnet unit 25 is provided with a bobbin 36 made from an insulating material, a coil 37 wound around the bobbin 36, a yoke (hereinafter referred to as second yoke 38) made from a conducting material, the second yoke 38 being disposed along one end face and one side of the bobbin 36 and bent at an angle of about 90 degrees, an iron core 39 to be inserted into a shaft hole 36a of the bobbin 36 and a through-hole 38a formed on the second yoke 38, and an iron piece (hereinafter referred to as second iron piece 40) disposed adjacent to a magnetic pole 39a of the iron core 39. The second electromagnet unit 25 is further provided with a moving contact spring (hereinafter referred to as second moving contact spring 41) to be caulked to one side (the side not shown in
Though not shown, an assembled state of the first electromagnet unit 24 before attaching the iron piece 31, the first moving contact spring 32, and the first return spring 33 is the same as that of the second electromagnet unit 25. It can be said that the assembled state of the first electromagnet unit 24 is different from that of the second electromagnet unit 25 since the assembled state of the first electromagnet unit 24 is the same as a mirror projection image of the assembled state of the second electromagnet unit 25. That is, the first electromagnet unit 24 in the assembled state and the second electromagnet unit 25 in the assembled state are different from each other only from the viewpoint that they are in a mirror projection relationship when shaft lines of the iron cores 30 and 39 are aligned parallel to each other.
Shown in
The first moving contact spring 32 which is bent to form a substantially L-shape and the first return spring 33 are caulked to a reverse side (side not shown in
A contact 32a is attached to one side of the first moving contact spring 32 in the vicinity of a tip of the first moving contact spring 32, and a contact 32b is attached to the other side of the first moving contact spring 32 in the vicinity of the tip of the first moving contact spring 32. A hole 33a to be used for the caulking to the first yoke 29 is formed on the first return spring 33 in the vicinity of a tip of the first return spring 33. In the same manner, contacts 41a and 41b are attached to opposite sides of the second moving contact spring 41 in the vicinity of a tip of the second moving contact spring 41, and a hole 42a for caulking to the first yoke 29 is formed on the second return spring 42 in the vicinity of a tip of the second return spring 42.
In
As described in the foregoing, the second iron piece 40 is disposed adjacent to the magnetic pole 39a of the iron core 39 (see
Though not shown, the movement of the first electromagnet unit 24 after attaching the first iron piece 31, the first moving contact spring 32, and the first return spring 33 is the same as that of the second electromagnet unit 25. That is, the first iron piece 31 of the first electromagnet unit 24 moves in directions from the position at which the first return spring 33 is attached to the first yoke 29 depending on absence or presence of the magnetic force of the magnetic pole 30a. Thus, the first moving contact spring 32 attached to the first iron piece 31 follows the movements of the first iron piece 31 to move in directions of approaching to and departing from the side of the first yoke 29.
The height H1a is equal to a height from the base 21 to the center of the contacts 41a and 41b of the second moving contact spring 41 when the second electromagnet unit 25 is attached to the base 21. The height H1b is equal to a height from the base 21 to the center of the contacts 32a and 32b of the first moving contact spring 32 when the first electromagnet unit 24 is attached to the base 21. The gap D1 between the walls 22a and 22b is set in accordance with a degree of the movement (see two-headed arrow Y of
Each of the A-fixed terminal unit 22 and the B-fixed terminal unit 23 having the above-described constitutions is mounted on the base 21 at a predetermined position. When the A-fixed terminal unit 22 and the B-fixed terminal unit 23 are mounted on the base 21, the terminals 32a and 32b of the first moving contact spring 32 are disposed in the gap (gap D1) between the walls 22a and 22b of the A-fixed terminal unit 22, and the terminals 41a and 41b of the second moving contact spring 41 are disposed in the gap (gap D1) between the walls 23a and 23b of the B-fixed terminal unit 23.
When both of the first electromagnet unit 24 and the second electromagnet unit 25 are not excited, the right contact 32a of the first moving contact spring 32 contacts the contact 23f of the wall 23b of the B-fixed terminal unit 23, while the left contact 41a of the second moving contact spring 41 contacts the contact 23d of the wall 23a of the B-fixed terminal unit 23 (normal close state of
When the first electromagnet unit 24 is excited, the first moving contact spring 32 moves to the left in the drawing so that the left contact 32b of the first moving contact spring 32 contacts the contact 22f of the wall 22b of the A-fixed terminal unit 22 (see
When the second electromagnet unit 25 is excited, the second moving contact spring 41 moves to the right in the drawing so that the right contact 41b of the second moving contact spring 41 contacts the contact 22d of the wall 22a of the A-fixed terminal unit 22 (see
When the first and the second electromagnet units 24 and 25 are not excited, both ends of the load 45 are connected to the GND via the C-terminals 35 and 44, the contacts 32a and 41a of the first and the second moving contact springs 32 and 41, and the contacts 23d and 23f of the B-fixed terminal unit 23. Accordingly, the load 45 does not operate.
When the first electromagnet unit 24 is excited, a passage of the +E, the terminal 22c, the wall 22b, the contact 22f, the contact 32b, the first moving contact spring 32, the first return spring 33, the first yoke 29, the C-terminal 35, the load 45, the C-terminal 44, the second yoke 38, the second return spring 42, the second moving contact spring 41, the contact 41a, the contact 23d, the terminal 23c, and the GND is formed.
When the second electromagnet unit 25 is excited, a passage of the +E, the terminal 22c, the wall 22a, the contact 22d, the contact 41b, the second moving contact spring 41, the second return spring 42, the second yoke 38, the C-terminal 44, the load 45, the C-terminal 35, the first yoke 29, the first return spring 33, the first moving contact spring 32, the contact 32a, the contact 23f, the terminal 23c, and the GND is formed.
The above two passages in the excited states are reverse to each other. Therefore, it is possible to control the load 45 in a forward reverse manner.
By the way, the conceptual diagram of
Also, the wall 23a of the B-fixed terminal unit 23 is disposed under the wall 22b of the A-fixed terminal unit 22, and the wall 22a of the A-fixed terminal unit 22 is disposed under the wall 23b of the B-fixed terminal unit 23. Further, the contact 23d of the B-fixed terminal unit 23 is disposed under the contact 22f of the A-fixed terminal unit 22, and the contact 22d of the A-fixed terminal unit 22 is disposed under the contact 23f of the B-fixed terminal unit 23.
As described in the foregoing, the following effects are achieved according to the electromagnetic relay 20 of this embodiment.
Number | Date | Country | Kind |
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2005-006614 | Jan 2005 | JP | national |
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Number | Date | Country | |
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20060152310 A1 | Jul 2006 | US |