KR900009757Y1 - Electronic relay - Google Patents

Abstract

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Description

Electronic relay

1 is a perspective view of an electronic relay according to a first embodiment of the present invention.

2 is a top view of the relay part notch.

3 is a cross sectional view taken along line 3-3 of FIG.

4 is a perspective view of an electronic block, an RF shield and a base used in the relay.

5 is a top view of the RF shield.

6 is a perspective view of a first embodiment of the relay of FIG.

7 is a perspective view showing a combination of a stator block and a balance spring according to a second embodiment of the relay of FIG.

8 is a perspective view of an electronic relay according to a second embodiment of the present invention.

9 is a plan view of the relay of FIG.

* Explanation of symbols for main parts of the drawings

10 base 11 bulkhead

12, 13 thread 14, 15 end wall

20: electronic block 30: excitation coil

31 bobbin 40 contact assembly

50: stator block 60: balance spring

61, 62: spring arm 70: RF shield

110: base 112: thread

130: excitation coil 131: bobbin

140: contact cooking body 141: fixed contact

142: movable contact spring 150: stator block

160: balanced spring 165: anchor plate

The present invention relates to an electronic relay, in particular an electronic relay having a stator block movable in a linear passage between two contact operating positions.

Electronic relays having linearly movable stator blocks are known in the art, for example as described in US Pat. No. 4,538,126. In this prior art relay, the stator block is held between a pair of separate balanced springs each extending in parallel to each other and loosely supported by the relay base. The separate arrangement of the balancing springs in the prior art relays requires a separate installation of the springs on the relay base, which makes the balancing springs more complicated to assemble. In addition, loose coupling each balance spring to the relay base makes it easy to pulsate the spring force acting on the stator block, requiring complex techniques to obtain the precisely balanced balance force required for the stator block, and each individually installed spring Independent of the spring force is applied. In this regard, the prior art relays are not satisfactory for conveniently assembling the balancing springs or providing a balancing effect consistent with the stator block.

The above problems have been eliminated in the present invention to provide an improved electronic relay. The relay according to the present invention includes a base for installing an electronic block and contact means and a faulty block therein. The stator block is magnetically coupled to the electronic block in such a way that it can be linearly moved between the two operating positions to actuate the contact means electronically to open and close the contact position. A feature of the present invention is that the stator block is fixed on the base by a U-shaped spring having a web connecting the parallel spring arms at one end of each arm and a pair of parallel springs in the form of a leaf spring. The use of a single parallel spring with a U-shaped structure is advantageous in that it reduces the number of spring parts, eases assembly and ensures stability and promotes an accurate equilibrium effect on the stator block. In addition, the U-shaped spring, which holds the stator block between the other ends of the spring arms, is fixed to the relay base at the web, and the stator block and the convenience spring combination can be assembled into the relay structure simply by peaking the web at the relay base. have.

Therefore, the main object of the present invention is to provide an improved electronic relay that can reduce the number of spring components, facilitate assembly and reliably provide stable and reliable balanced spring characteristics to the stator movement.

In a suitable example, the U-shaped balancing spring includes an integral bridge portion that bridges the other end of the spring arm near the junction of the spring arm with the stator block. With this bridge part, the balance spring will create a parallelogram by itself, improving the constant balance spring properties that can be expected in the desired linear motion of the stator block.

It is therefore an object of the present invention to provide an improved electronic relay in which the balance spring is reinforced with a bridge portion to give a constant balance spring effect on the stator block.

The bridge portion also acts as another support for the stator block, which firmly grips the stator block in cooperation with the other end of each spring arm. For this purpose, the bridge portion is fixed to the top surface of the stator block with a suitable adhesive. Suitably, it is in the form of a flat plate member wider at the center than the connecting end with a spring arm, in order to give the stator block a larger adhesive area as with other objects of the present invention.

The balance spring includes an anchor plate extending from the web in a direction substantially perpendicular to the plane of the spring arm for insertion into a compensation hole formed in the relay base. Both sides of the anchor plate serve to guide the stator block held by the spring vertically downwards into the relay base during installation and assembly of the stator block on the relay base by inserting the anchor plate into the correspondingly shaped groove hole. Thereby ending with a vertical guide end extending perpendicular to the longitudinal direction of the web to prevent axial movement of the stator block and its movable contact means which are supported on its side and extend in the longitudinal direction. The vertical end of the anchor plate thus makes it easier and more accurate to arrange between the movable contact means supported on the stator block and the fixed contact means installed on the relay base.

Therefore, another object of the present invention is to provide an improved electronic relay that can be easily assembled to a relay base with a stator block with movable contact means and to ensure a secure connection between the movable contact means on the stator block and the fixed contact means on the relay base. To provide.

The present invention also has more advantageous features in employing relays in RF circuits. For this purpose, an RF shield is installed in the relay base to surround the contact means consisting of movable contact means and fixed contact means. The RF shield has at least one ground terminal that extends out of the base, and yet another object of the present invention is to provide a single contact member with the movable contact means in the open contact position while being able to electrically insulate one contact member from the seat contact member for preventing RF signal leakage. It is supposed to be in electrical contact.

The above and other objects and advantages of the present invention will become apparent from the following detailed description of suitable embodiments of the present invention described in connection with the accompanying drawings.

U First Embodiment Referring to Figs. 1 to 4, an electronic relay according to a first embodiment of the present invention is shown. The relay has a form having a polarity including an installation base 10 for installing the electronic block 20, a contact assembly 40, and a fixed block 50. The base 10 is formed of an electrically insulating plastic material such that the partitions 11 have grooves, which are divided into chambers 12 and 13 which receive the electronic block 20 and the other which receive the contact assembly 40 by the partition 11. do. The partition 11 extends by the total distance between the opposite end walls 14 and 15, and its ends are integrally connected thereto. A cover 17 of the same insulating material is fitted to the base to surround the entire relay structure.

The electronic block 20 includes a central core 21 and a pair of side, bottom yoke legs 23 and 24 extending in parallel with the core 21 and having one end coupled to an adjacent end of the core 21, respectively. do. The free end of the excitation coil 30, which remains exposed, defines the first extreme end 22 and is disposed around the core 21 via the bobbin 31. As shown in detail in FIG. 4, the side and bottom yoke legs 23, 24 extend in isolation from one side and the bottom of the core 21, respectively.

The upper half of the free end of the yoke leg 23 is cut out and the side end of the free end of the bottom yoke leg 23 isolated from the side yoke leg 23 is the first extreme end of the central core 21. Curved upward to form a second pole end 25 that interacts with 22 to form a magnetic cap. The seat plate 26 is attached to the side of the core 21 so as to face the cutouts of the side yoke legs 23. The end of the excitation coil 30 extends outwardly through the base bottom when wound and assembled on the coil terminals 32 and 33 respectively supported on the extension of the bobbin 31.

The stator block 50 includes a straight plate member 51 made of an electrically insulating plastic material supporting the pair of pole plates 52 and 53 and the permanent magnet 54 at its longitudinal end.

The upper plates 52 and 53 are buried in the upper end portion of the flat plate member 51 with the permanent magnets 54 disposed therebetween so as to lower polarities so as to be different from each other. The permanent magnet is entirely contained within the thickness of the flat plate member 51, and the lower ends of the pole plates 52 and 53 protrude downward from the flat plate member 51 to magnetically engage with the pole ends of the electronic block 20.

A pair of longitudinally spaced protrusions 55 are formed integrally with one side of the flat plate member 51 in which bottom cavities (not shown) are formed, respectively, for connecting with the pair of elongate movable contact springs 42, respectively. Each movable contact spring 42 is held in the center by a vertical strut 44 made of an electrically insulating material, and the upper end of the strut 44 is connected to a fixing block 50 fitted in the bottom cavity of each protrusion 55. Each contact spring 42 extends horizontally parallel to the longitudinal axis of the fixed block 50. As shown in Figs. 1 and 2, the movable contact springs 42 are staggered in the longitudinal direction with overlapping adjacent ends in an isolated state.

At the upper portion of the flat plate member 51 adjacent to each of the protrusions 55, a circular sink 56 for receiving a suitable adhesive fluid is formed.

The adhesive fluid supplied to the sink 56 is provided with the top hole and the trough 57 of each protrusion 55 to improve the connection between the flat plate 51 and the support 44 of each movable contact spring 42. Flows through the bottoms joint.

The fixing block 50 thus adapted to support the movable contact spring 42 is supported on the base 10 by a U-shaped balancing spring 60 so that the longitudinal direction of the fixing block 50 between two contacting operating positions is provided. It is movable along a linear passage perpendicular to the axis. The U-shaped balancing spring 60 has a pair of parallel spring arms 61 and 62 in which one end is integrally connected by the web 63. As shown in FIG. The spring 60 is bent into a U-shaped structure by forging a metal sheet so that the parallel spring arms 61 and 62 can elastically move in the plane while restricting the web 63 from elastically moving in the plane.

The spring arms 61 and 62 extend along the axis of the fixing block 50 and each spring arm is fixed to and welded to each free end by a pin 59 integral with the flat plate member 51, respectively. Extends through (61, 62). The pin 59 connects the spring arms 61 and 62 to the plate member 51 at an equal distance from the web 63 so that the stator block 50 is laterally oriented like the elastic flexible parallel arms 61 and 62. Balanced spring arms 61 and 62 and web 63 cooperate with the plate member 51 to form a parallelogram so as to move linearly. The stator block 50 held between the balanced spring 60 and its spring arms 61 and 62 is both anchored at its upper end fixed to adjacent ends of the spring arms 61 and 62 and extending downward from the web 63. It is attached to the base 10 by 65. The anchor plate 65, which may be integral with the web 63, projects in a direction perpendicular to the plane of motion of the stator block 50 and has a correspondingly formed groove hole 16 formed in the end wall 15 of the base 10. ) Is caught and accommodated.

The side end 66 of the anchor plate 65 and the corresponding inner wall 16 of the groove 16 are perpendicular to the axial direction of the stator block 50 or the length of the web 63 so that the groove 16 While inserting the anchor plate 64 into the stator block 50 is a predetermined relationship to the fixed contact pin 41 on the base 10, the stator block 50 can be accurately and easily positioned while the base ( 10) can be guided straight down.

Bridge portion 64 bridges integrally between spring arms 61 and 62 at a point corresponding to pin 59 to reinforce parallelograms and to act as an additional element that couples to stator block 50. For this purpose, the bridge portion 64 is adhered to the upper surface of the flat plate member 51 using the same adhesive liquid, that is, the adhesive liquid supplied in the narrow groove 67 on the upper surface of the flat plate member 51. Thus, the weight of the stator block 50 is mainly supported by the bridge portion 64 and dividedly supported by a pair of parallel spring arms 61 and 62. The bridge portion 64 has the advantage of maintaining parallelogram until either or both of the spring arms 61 and 62 are deformed at the connection by the pin 59.

The fixed contact pins 41 consist of three longitudinally arranged pins extending equally apart from one another and vertically extending through the bottom of the seal 13 of the base 10 as shown in detail in FIG. Cooperatively with) to form contact assembly 40. One of the movable contact springs 42 is adapted to engage the sides of two adjacent fixed contact pins 41 at the longitudinal end and the other movable contact spring 42 is engageable at the longitudinal end of the pair of two other adjacent fixed points. It is provided on the opposite side of the contact pin 41. The movable contact spring 42 is arranged such that one movable contact spring 42 is in a closed contact with the corresponding fixed contact pin 41 when the other spring 42 is in an open contact.

As shown in FIG. 2, the stator block 50 provided on the base 10 by the balance spring 60 has a pole plate 52 between the first pole end 22 and the second pole end 25. And the first pole end 22 of the core 21 is magnetically coupled to the electronic block 20 disposed below in such a manner that it extends between the pole plates 52 and 53. Thus, as soon as the excitation coil 30 is de-energized, the stator block 50 has pole plates 53 and 52 attracted to the first and second pole ends 22 and 25, respectively, to complete the magnetic flux of the permanent magnet 54. Is maintained stable in the first contact operating position. In this position, one of the movable contact springs 42 is operated in the closed position and the other spring 42 is operated in the open position. When the exciting coil 30 is excited with a special polarity, the stator block will linearly move to a second contact acting position for contact reversal where the pole plate 52 is pulled to the first pole end 22 of the core magnetized to a different polarity. . In this way, the stator block 50 is driven to flexibly flex the spring arms 61 and 62 of the balance spring 60 to move linearly between the two contact actuation positions. During this linear movement of the stator block 50, the element 34 integrally protruding from the coil bobbin 31 and slidably received in the opening 68 is used to smoothly guide the stator block 50 in its linear passage. It helps.

The contact assembly 40, which consists of a fixed contact pin 41 and a movable contact pin 42, is surrounded by an RF (radio frequency) shield 70 having a plurality of isolated ground pins 71.

The RF shield 70 is formed into a rectangular conductive sheet and is accommodated in the seal 13 in a state in which the ground pin 71 extending outwardly through its inner wall and the base bottom wall is in intimate contact. Each convex portion 74 into which the adjacent movable contact spring 42 is grounded when in the open position while electrically insulating one movable contact in the open position from the movable contact spring 42 and associated circuitry when in the open position is a fixed contact pin. It protrudes on the inner surface of the RF shield 70 at the position corresponding to 41. The RF shield 70 is integrally formed with an adjustable stud that can engage with the integral extension 69 of the spring arm 61. If necessary, the adjustment stud may be well coupled to the extension 69 which biases the balance spring 60 in one direction to give the stator block 50 a desirable balance effect.

6 shows the use of the improved bridge portion 64a to bridge the free ends of the spring arms 61a and 62b of the balancing spring 60a and the first embodiment except that the adjusting studs 72 and associated parts have been removed. A first variant of the second embodiment, such as the structure and operating state of the embodiment.

For ease of reference, the same reference numerals are given to the same parts. The bridge portion 64a of the variant is shaped to have a flat central portion that is wider than the connecting ends with spring arms 61a and 62b. Increasing the width of the bridge element 64a will increase the top and adhesive surface area of the stator block 50 which bonds between the adhesive materials.

7 shows that the balance spring 60b and the stator block 50b are integrally combined to provide a combination block 80 in one piece. The other structure of the relay is the same as that of the first embodiment, and thus a detailed description thereof will be omitted. The combination block 80 is formed of an electrically insulating material thickly formed such that the stator block 50b and the anchor plate 65b have a rigid structure.

The stator block 50b and the anchor 65b are connected by a pair of integrally formed thin members to form parallel spring arms of the balanced spring 60b. The spring arms 61b and 62b are interconnected by the upper end of the anchor plate 65b forming the U-shaped web 63b and cooperate with the integral stator block 50b to form a parallelogram, so that the stator blocks ( 50b) is linearly moved in the axial direction in which the spring arms 61b and 62b are elastically bent in the same manner as in the first embodiment. The stator block 50b is formed with an opening for accommodating both the pair of pole plates 52b and 53b and the permanent magnet 54b, and a protrusion for accommodating the set of movable contact springs 42b.

U Second Embodiment According to Figs. 8 and 9, there is shown a polar electronic lily in accordance with a second embodiment of the present invention, the electronic relay comprising a base 110, an electronic block 120, Contact assembly 140 and stator block 150. The electronic block 120 is accommodated in the elongated thread 112 of the base 110 surrounded by the side wall 113 and the end walls 114 and 115.

A set of longitudinally isolated contact assemblies 140 consisting of fixed contacts 141 and movable contact springs 142 are provided on each side wall 113. These contacts 141 and 142 have respective terminal supports 145 and 146 extending downward through the side walls 113. One end wall 115, which is higher than the opposing wall 114, has a groove hole 116 in which a combination of stator blocks and balance springs 160 is provided.

The electron block 120 is U-shaped with opposite pole ends 122 and 125 at both ends. The excitation coil 130 supported by the bobbin 131 is disposed around the center of the core 121 having opposing pole ends 122, 125 projecting upward from the end of the bobbin. The coil ends of the exciting coil 130 are connected to respective coil terminals 132, 133 which, when assembled, extend through the bobbin 131 and through the bottom of the seal 112.

The stator block 150 includes a rectangular plate member 151 made of an electrically insulating material that supports, at the longitudinal end, a permanent magnet 154 disposed between the pair of pole plates 152, 153. Upper ends of the pole plates 152 and 153 are fitted together with permanent magnets in the vertical holes 156 in the longitudinal end of the plate member 151 so that the lower ends of the pole plates 152 and 153 polarized to the opposite polarity by the permanent magnet 154 protrude. do. Opposite pole ends 122 and 125 which magnetically couple the stator block 150 and the electromagnet 120 protrude between the pole plates 152 and 153 at each end of the stator block 150. An integral protrusion 155 having a pin 159 is formed at the longitudinal center of each side of the flat plate member 151. In addition, an integral card 157 is formed at the longitudinal end of each side of the plate member 151 to drive the corresponding movable contact spring 142 according to the linear motion of the stator block.

The balance spring 160, which installs the stator block 150 on the relay base 110, has a U-shaped structure with a pair of parallel spring arms 161, 162 integrally connected at one end with a web sheet 163. It is made and formed. The anchor plate 165 extends integrally downward from the web 163 inserted into the groove hole 116 of the base 110.

Stator block 150 is retained between spring arms 161 and 162 by inserting pins 159 through the free end of each spring arm and modifying them in a fixed connection with each spring. The connecting ends of the spring arms 161 and 162 are at the same distance from the web 164 and the axial distance between the connecting ends of the spring arms 161 and 162 is approximately equal to the length of the web 164 so that the parallel spring 160 is the stator block 150. Or the same length as the portion between the connecting ends of the spring arms to form a parallelogram that causes the stator block 150 to move linearly in the axial direction. In this regard, the combination of the stator block 150 and the balance spring 160 is anchor plate 165 of the balance spring 160 into the groove hole 116 of the base 110 in the same manner as in the previous embodiments and variations. It should be understood that by simply inserting it, it can be easily assembled as a single unit on the relay base 110.

During operation, when the exciting coil is excited by a given voltage polarity, the stator block 150 is driven to linearly move to the first contact operating position as shown in FIG. 9, with one pole plate 152 or 153 of each set. Is towed to the adjacent pole end 122 or 125 and the other pole plate 153 or 152 is isolated therefrom and pushes the movable spring on one side of the stator block 150 in the card 157 on the other side of the stator block 150. The contact is opened while leaving the movable spring elastically bent to close the contact. The stator block 150 remains stable unless the exciting coil 130 is excited with a voltage antipolarity. After excitation, the stator block 150 is linear to another contact actuation position where each set of other pole plates 153 or 152 is towed to the adjacent extreme end 122 or 125 while reversing the contact by the same action of the card 157. Driven to move.

Claims (11)

Bases 10 and 110 for installing the electromagnet blocks 20 and 120 and the contact means 40 and 140, and magnetically coupled to the electromagnet blocks 20 and 120 installed in the base to be magnetically driven to operate the contact means 40 and 140 in the open and close contact positions. In an electronic relay comprising a stator block (50,150) linearly moved between two operating positions, the stator block (50,150) is a web that integrally bridges parallel spring arms (61, 62, 161, 162) at one end of each arm. Supported on bases 10 and 110 by U-shaped balance springs 60 and 160 with a pair of flat spring arms 61, 62, 161 and 162 in the form of leaf springs, the balance springs 60 and 160 being stator blocks 50 and 150. The parallel spring arms 61, 62, 161, 162 and the webs 63, 163 coincide with the stator blocks 50, 150 to allow pivoting in a linear passage parallel to the length of the webs 63, 163. One end of each spring arm 61, 62, 161, 162 is connected to each of the opposite sides of the stator blocks 50, 150 at a point equidistant from the other end of each spring arm 61, 62, 161, 162 to form a stator block 50, 150. ) Is fixed to the base (10,110) at the web (63,163). 2. The other end of the balanced spring arms 61, 62 is integrally connected by the bridge portion 64 at a point corresponding to the connection point of each spring arm 61, 62, 161, 162 to the stator block 50. Electronic relay, characterized in that. 3. Electronic relay according to claim 2, characterized in that the bridge (64, 64a) is bonded to the stator block (50). 2. The contact means (40,140) according to claim 1, wherein the contact means (40,140) comprise movable contact spring means (41,142) transferred on stator blocks (50,150) engageable with fixed contact means (41,141) mounted on the base (10,110), The movable contact spring means 42, 142 comprise at least one movable contact spring 42, 142 carried on a stator block 50, 150 extending in parallel with the spring arms 61, 62, 161, 162, the balance springs 60, 160. Includes anchor plates 65 and 165 angularly extending from the webs 63 and 163 with respect to the face of the parallel spring arms 61, 62, 161 and 162 for insertion into the complementary groove holes 16 formed in the bases 10 and 110. The anchor plates 65 and 165 are movable contact springs 42 and 142 without causing axial displacements when the stator blocks 50 and 150 are assembled to the bases 10 and 110 together with the anchor plates 65 and 165 inserted into the groove holes 16 and 116. Above) Vertical guide ends coupled to vertical sidewalls of corresponding shapes on both sides of the grooved holes 16 and 116, respectively, so as to be properly positioned in the means 41 and 141, and perpendicular to the length of the webs 63 and 163 and extending parallel to the movable contact springs. An electronic relay characterized by being formed along side ends having 66 and 166, respectively. 5. The bridge end 64, 64a according to claim 4, wherein the other ends of the parallel spring arms 61, 62, 161, 162 are corresponding to the points connecting the respective spring arms 61, 62, 161, 162 to the stator blocks 50, 150. Electronic relay, characterized in that integrally connected. 5. The bridge portion (64a) according to claim 4, wherein the bridge portion (64a) is in the form of a flat plate member wider at its center than at the connection point ends with spring arms (61, 62), and the wide plate central portion is formed of a stator block (e.g. 50) an electronic relay, characterized in that bonded to. 7. Electronic relay according to claim 6, characterized in that the bridge portion (64a) is bonded to the stator block (50). 5. The parallel spring arm (61, 62) of the balanced spring (60) has an extension (69) extending beyond the connection of the fixed bottom block (50), the free end of which is the base. Abutment engagement with an adjustment stud 72 protruding on 10, wherein the adjustment stud 72 is a spring on which the balance spring 60 acts on the stator block 50 during a linear movement between the two operating positions. Electronic relay, characterized in that the manual deformation to adjust the force. 5. The shield according to claim 4, further comprising an RF shield (70) fitted to the partition (13) formed in the base (10) to surround the fixed contact means (41) and the movable contact means (42). (70) has at least one ground terminal (71) extending out of the base (10) and a movable contact spring means (42) together with said stationary contact means (41) in an open contact position by a stator block (50). Electronic relay, characterized in that arranged in electrical contact with the movable contact spring means (42) when operated. The method of claim 9, wherein the partition wall 13 is separated from the electromagnet block 20 by the partition wall 11 formed integrally with the base 10, the electromagnet block 20 is to separate the partition wall (11) And a yoke member (23) extending along almost the entire length of said partition wall (11) in close contact therewith for reinforcement. 5. The movable contact spring (42) according to claim 4, wherein the fixed contact means (41) comprises three fixed contact pins arranged in a straight line, wherein the movable contact spring means (42) has one movable contact spring (42) with a different movable contact spring (42). Are arranged in the longitudinal direction disposed over the adjacent ends of each of the straight lines and are arranged in parallel with each other on both sides of the straight line, each of the movable contact springs 42 is two adjacent fixed contacts with different movable contact springs 42 The two movable contact springs 42 and the adjacent two fixed contact pins 41 for opening and closing the contact such that one movable contact spring 42 is in the closed contact position with the corresponding two fixed contact pins 41 when in the open contact position with the pins 41. And an electronic relay disposed at the longitudinal end so as to be engageable.