DE112018007265T5 - MOVING CONTACT SPRING FOR SAFETY RELAYS AND SAFETY RELAYS OF MOVING CONTACT SPRING - Google Patents

Abstract

A moving contact spring for a safety relay and a safety relay of the moving contact spring. The movable contact spring comprises a spring body in the form of a straight plate. A movable contact is fixedly connected to one side of the head of the spring body. The tail of the spring body is provided with a connecting portion which is attached to an outlet plate of the movable contact spring. The head of the spring body is also provided with an outwardly extending extension section. The extension portion comprises a first extension portion which is angled at about 90 degrees along the other side of the end piece of the head of the spring body and extends, and a second extension portion which is made by angling the tail end of the first extension portion towards the end of the spring body by about 90 degrees is formed and extends.

Description

TECHNICAL PART

The present disclosure relates to the technical field of relays, and more particularly, to a movable spring used for a safety relay and a safety relay of the movable spring.

BACKGROUND

A relay is an electrical control device that represents a device that causes a predetermined load jump in the controlled variable in the electrical output circuit when the change in the input variable (e.g. the excitation variable) reaches a certain requirement. It has an interactive relationship between the control system (also called the input loop) and the controlled system (also called the output loop). The relay is actually an "automatic switch" that uses a small current to control the operation of a large current and is usually used in an automatic control circuit that plays the role of automatic adjustment, safety protection and conversion circuit.

A safety relay (also called a relay with forcibly guided contacts) is a type of relay. The difference between a safety relay and an ordinary relay is that the safety relay can take regular action when a fault occurs and that it has a structure of positively driven contacts, which can ensure safety in the event of a welded contact. In the safety relays of the prior art, the positively driven contacts are essentially achieved by installing a delimiting groove on the actuator and arranging a movable spring in the positioning slot. That is, the movable spring is arranged between two opposite groove walls of the restriction groove of the actuator, when the actuator moves forward, one groove wall of the actuator pushes the movable spring forward, and when the actuator moves backward, the other groove wall of the actuator pushes the movable spring backward. The safety relay with the structure described above mainly has the following disadvantages:

1. It is difficult to assemble, assembly accuracy is difficult to guarantee, and parts can easily be unnecessarily scrapped.

2. The actuator is easy to rub on the housing, which makes the relay work unusually.

3. When the stem of the movable spring breaks, the movable spring falls obliquely into the base, and there is a possibility that the movable spring and the stationary spring may be mistakenly connected, thereby affecting the safety of the relay.

SUMMARY OF THE INVENTION

The object of the present disclosure is to overcome the weakness of the prior art and provide a movable spring used for a safety relay and a safety relay of the movable spring by improving the structure of the movable spring and the structure of the actuator which is applied to the movable spring is tuned to provide. At the same time as ensuring the restraint effect, the relay is easy to assemble and has high assembling accuracy, and it is not easy to cause scrapping of parts in assembling, and abnormal operation of the relay can be prevented and the safety of the relay can be improved.

The first aspect of the present disclosure provides a movable spring used for a safety relay. The movable spring has a spring body in the shape of a straight plate, one side of a head portion of the spring body is fixedly connected to a movable contact and a tail portion of the spring body is provided with a connecting portion for fixing to a terminal of the movable spring. The head portion of the spring body is also provided with an outwardly extending extension portion, the extension portion having a first extension portion extending in a direction of about 90 degrees that is angled from the other side of an end of the head portion of the spring body, and a second Has extension portion which extends in a direction of about 90 degrees, which is angled from one end of the first extension portion to the tail portion of the spring body.

The width of the extension section is equal to the width of the head section of the spring body.

The width of the head portion of the spring body is greater than a width of a central portion of the spring body and a width of the tail portion of the spring body.

The second aspect of the present disclosure provides a safety relay that includes a magnet system, a movable spring member, a stationary spring member, an actuator, and a base having. The movable spring part, the stationary spring part, the actuator and the magnet system are each installed on the base. A moving contact and a stationary contact are in an adjustment position. The actuators are connected between the magnet system and the movable spring part. The movable spring part and the stationary spring part have a plurality of contact groups. The movable spring part has a movable spring and a terminal of the movable spring described above. A tail portion of the spring body is attached to the terminal of the movable spring. The connector of the movable spring is inserted into the base. The actuator is provided with a pressure arm, and the pressure arm of the actuator is fitted into a recess which is surrounded by one end of the head portion of the spring body, a first extension portion and a second extension portion. When one side of the push arm of the actuator is pushed toward the end of the head portion of the spring body, the movable spring is moved toward stationary contact. When the other side of the pressure arm of the actuator is pushed toward a second extension portion, the movable spring is moved away from the direction of stationary contact. If the movable contact and the stationary contact are glued together, the actuator will not be able to move any further, thereby ensuring closure of the contact groups.

The pressure arm of the actuator is fitted with a clearance fit between the end of the head portion of the spring body and the second extension portion.

One side surface of the pressure arm of the actuator and / or the other side of the pressure arm of the actuator is an arcuate surface protruding outward in the center.

A lower surface of the first extension portion is configured to cooperate with an upper surface of the push arm of the actuator, whereby the actuator can be prevented from contacting a housing of the relay in a direction perpendicular to movement of the actuator. The housing is fixed on the base to accommodate the magnet system, contact portions of the movable spring part and the stationary spring part, and the actuator.

The actuator is provided with a slot for inserting the movable spring, and the pressure arm is arranged in the slot.

The recess of the movable spring is clamped down onto the pressure arm of the actuator. When the tail portion of the spring body is broken, the movable spring is retained on the actuator, thereby preventing accidental connection between the movable spring and the stationary spring and improving the safety performance of the safety relay.

In the center of the case, a downward convex rib is provided along a moving direction of the actuator. A groove is provided in the center of the base along the direction of movement of the actuator. When the housing is attached to the base, the convex ridge of the housing is fitted into the groove in the base.

The convex rib of the housing and the groove of the base are each provided in a plurality of corresponding portions.

A first support wall is provided in the center of the base along the direction of movement of the actuator. The plurality of contact groups are arranged symmetrically on both sides of the first support wall. The groove is provided on the uppermost part of the first support wall.

A second support wall is also provided in the base at a position between two adjacent groups of contacts that correspond to the same side of the first support wall to prevent splashes in the contacts from interfering with one another.

A third support wall is also provided in the base at a position between the movable spring and the stationary spring corresponding to the same contact group.

A base cavity for attaching the magnet system is provided in the base. A track groove is provided in the base cavity for pressing the magnet system into the base cavity along a horizontal direction.

Figure list

• 1 Figure 3 is a perspective schematic illustration of the moveable spring (with a port of the moveable spring) of the present disclosure;
• 2 Figure 3 is a perspective schematic illustration of the safety relay (without a housing) of the present disclosure;
• 3 Figure 3 is a top plan view of the safety relay (without housing) of the present disclosure;
• 4th FIG. 13 is a cross-sectional view taken along line AA in FIG 3 is included;
• 5 FIG. 13 is an enlarged schematic view of part B in FIG 4th ;
• 6th Figure 3 is a schematic representation of the distribution of the contact groups of the safety relay of the present disclosure;
• 7th Figure 3 is a perspective schematic illustration of the base of the safety relay of the present disclosure;
• 8th Figure 3 is a top plan view of the base of the safety relay of the present disclosure;
• 9 Figure 3 is a schematic illustration of the configuration of the housing (with the housing cavity facing downward) of the safety relay of the present disclosure;
• 10 Figure 3 is a schematic illustration of the configuration of the housing (with the housing cavity facing downward) of the safety relay of the present disclosure;
• 11 Figure 3 is a perspective schematic view of the actuator of the safety relay of the present disclosure;
• 12 Figure 3 is a top plan view of the actuator of the safety relay of the present disclosure;
• 13 Figure 3 is a schematic representation of a magnet system of the safety relay of the present disclosure.

DETAILED DESCRIPTION

1 shows a movable spring 1 that is used for a safety relay of the present disclosure that has a spring body 10 in the form of a straight plate. One side of the head section 11 the spring body is fixed with a moving contact 12 connected. The tail section 13 of the spring body is provided with a connecting portion for fixing with a terminal 14th of the movable spring, and the connecting portion may be formed as a rivet hole. The head section 11 of the spring body is also provided with an outwardly extending extension portion, the extension portion having a first extension portion 16 that extends in a direction of about 90 degrees from the other side of one end 15th of the head portion of the spring body is angled, and a second extension portion 17th which extends in a direction of approximately 90 degrees that is angled from one end of the first extension portion to the tail portion of the spring body.

In this embodiment, the width of the extension portion (ie, the first extension portion 16 and the second extension portion 17th ) equal to the width of the head section 11 of the spring body.

In this embodiment, the width of the head portion is 11 of the spring body greater than the width of the central portion of the spring body and also greater than the width of the tail portion 13 of the spring body.

With reference to 1 to 13 a safety relay of the present disclosure includes a magnet system 2 , a movable spring part, a stationary spring part 3 , an actuator 5 and a base 4th on. The movable spring part, the stationary spring part 3 , the actuator 5 and the magnet system 2 are each based on 4th Installed. A moving contact 12 the movable spring part and the stationary contacts 31 of the stationary spring part 3 are in an adjustment position. The actuator 5 is between the magnet system 2 and the movable spring member, and the movable spring member and the stationary spring member have a plurality of contact groups. As an example, this embodiment is provided with 6 contact groups, of which four contact groups use a normally open structure and two other contact groups use a normally closed structure (as in 6th shown). The movable spring member may be the movable spring described above 1 and a connector 14th the movable spring. The tail section 13 of the spring body is at the connection 14th attached to the movable spring. The connection 14th the movable spring is provided with rivet projections, and through the rivet hole of the spring body, which cooperates with the rivet projections of the terminal of the movable spring and uses the riveting method, to the movable spring 1 and the connection 14th to attach the movable spring together. The connection 14th the movable spring is in the base 4th introduced. The actuator 5 is with a pressure arm 51 provided, and the pressure arm 51 of the actuator is in the recess 18th fitted in from one end of the head portion 15th of the spring body, the first extension section 16 and the second extension portion 17th is surrounded. When one side of the pressure arm 51 of the actuator 5 to the end 15th of the head portion of the spring body is pressed, the movable spring 1 to inpatient contact 31 moved. When the other side of the pressure arm 51 of the actuator 5 to the second extension section 17th is pressed, the movable spring 1 from the direction of stationary contact 31 moved away. If the moving contact and the stationary contact are stuck together, the actuator can become 5 do not move further, which ensures the closure of the contact groups.

In this embodiment the pressure arm is 51 of the actuator with a clearance fit between the end 15th of the head portion of the spring body and the second extension portion 17th fitted.

In this embodiment, for example, a side surface of the pressure arm 51 of the actuator and / or the other side of the pressure arm of the actuator may be an arcuate surface that protrudes outward in the center.

In this embodiment, the lower surface of the first extension section acts 16 with the upper surface of the pressure arm 51 of the actuator together to the actuator 5 to prevent the housing 6th of the relay in a direction perpendicular to the movement of the actuator. The case 6th is on the base 4th attached to the magnet system 2 , the contact portions of the movable spring part and the stationary spring part and the actuator 5 accommodate.

In this embodiment, the actuator is 5 with a slot 52 provided for inserting the movable spring, and the pressure arm 51 is in the slot 52 arranged.

In this embodiment there are two pressure arms 51 in the slot 52 arranged, and the upper surfaces of the two pressure arms 51 are each with the first extension section 16 customized.

In this embodiment, the recess 18th the movable spring 1 down on the pressure arm 51 of the actuator 5 clamped. When the tail section 13 of the spring body breaks, the movable spring becomes 1 on the actuator 5 held, thereby preventing the accidental connection between the movable spring and the stationary spring and improving the safety performance of the safety relay.

In this embodiment there is a downwardly convex rib 61 along the direction of movement of the actuator in the middle of the housing 6th intended. In the middle of the base 4th is a groove 41 provided along the direction of movement of the actuator. When the case 6th at the base 4th is attached, the convex rib fits 61 of the housing into the groove 41 the base. The actuator 5 is with through holes 53 provided through which the convex ribs 61 go through.

In this embodiment the ribs are convex 61 of the housing and the groove 41 the base is each provided in a plurality of corresponding sections.

In this embodiment there is a first support wall 42 along the direction of movement of the actuator in the center of the base 4th intended. A plurality of contact groups are symmetrical on either side of the first support wall 42 arranged, and the groove 41 is on the top of the first retaining wall 42 intended. Three groups of contacts are on each side of the first retaining wall 42 distributed.

In this embodiment there is also a second support wall 43 in the base 4th provided at a position between two adjacent contact groups, which corresponds to the same side of the first support wall, in order to prevent the splashes in the contacts from interfering with one another. That is, two second retaining walls 43 are provided on either side of the first support wall to separate the three contact groups on each side.

In this embodiment there is also a third support wall 44 in the base 4th at a position between the movable spring and the stationary spring corresponding to the same contact group. That is, three third retaining walls 44 are provided on both sides of the first support wall to separate the movable spring and the stationary spring in the three contact groups on each side.

In the embodiment is a base cavity 45 for attaching the magnet system 2 in the base 4th intended. A ruts 46 is for pressing the magnet system 2 into the base cavity 45 provided along the horizontal direction. Another aspect of the present disclosure provides a movable spring used for a safety relay and a safety relay of the movable spring. The head section 11 of the spring body of the movable spring is further provided with an outwardly extending extension portion, the extension portion having a first extension portion 16 that extends in a direction of about 90 degrees from the other side of the end 15th of the head portion of the spring body is angled, and a second extension portion 17th which extends in a direction of about 90 degrees that is angled from the end of the first extension portion to the tail portion of the spring body. A recess 18th is from the end 15th of the head section of the spring body, the first extension section 16 and the second extension portion 17th is surrounded so that the movable spring forms an inverted J-shaped structure. There is also a pressure arm 51 provided on the actuator and the pressure arm 51 of the actuator is in the recess 18th fitted to the movable spring. The recess is fitted on the push arm with the opening facing downward so that the movable spring hangs on the push arm of the actuator, thereby constraining the relay in the front and rear directions. That is, when the actuator 5 moves forward, the movable spring moves forward, and when the actuator moves backward, the bending portion (i.e., the second extension portion) of the movable spring pulls the push arm of the actuator and is moved backward together with the actuator when the movable contact and the stationary contact are glued together, can the actuator 5 Do not move any further, which ensures the closure of the contact groups.

The movable spring used for a safety relay and the safety relay of the movable spring in the present disclosure allow the lower surface of the first extension portion 16 with the upper surface of the pressure arm 51 of the actuator cooperates, so that the actuator 5 can be prevented from touching the housing of the relay in a direction perpendicular to the movement of the actuator. That is, it is equivalent to limiting the upper portion of the actuator 5 to prevent the friction between the actuator and the housing which will cause the relay to function abnormally.

The movable spring used for a safety relay and the safety relay of the movable spring in the present disclosure enable the movable spring 1 on the pressure arm 51 of the actuator is clamped, when the tail portion 13 (ie the foot portion) of the spring body breaks the movable spring 1 still on the pressure arm 51 of the actuator is clamped, and the spring body will not fall down when suspended, so there should not be accidental connection, which can ensure the safety of the safety relay. However, in the prior art safety relay, if the root portion of the spring tongue breaks, the spring tongue may fall obliquely into the base, and then the terminal of the movable spring and the stationary spring member are connected, thereby affecting the safety of the relay.

The movable spring used for a safety relay and the safety relay of the movable spring in the present disclosure enable a rib convex downward 61 along the direction of movement of the actuator in the middle of the housing 6th is provided. In the middle of the base 4th is a groove 41 provided along the direction of movement of the actuator. When the case 6th at the base 4th is attached, the convex rib fits 61 of the housing into the groove of the base. The present disclosure serves three functions through the cooperation of the convex rib 61 and the groove 4th . First has the convex rib 61 a guiding and limiting effect on the movement of the actuator 5 which reduces the occurrence of the situation that the functional lag of the contacts becomes smaller due to the deflection of the actuator, which affects the life of the relay. Second, the convex rib acts 61 together with the base, thereby increasing the creepage distance and the air gap between the left and right contact groups (i.e. both sides of the first retaining wall). Third is the convex rib 61 against the base 4th pressed to a role in limiting the housing 6th to play, thereby ensuring the distance between the surface of the housing and the actuator and the distance between the surface of the housing and the movable spring, and ensuring the flexibility of the actuator and the movable spring.

The movable spring used for a safety relay and the safety relay of the movable spring in the present disclosure enable a second support wall to be also provided 43 in the base 4th is provided at a position between two adjacent contact groups corresponding to the same side of the first support wall, which can prevent splashes in the contacts from interfering with each other, and this can reduce pollution from splashes between the contact groups and ensure the reliability of the contacts. The present disclosure also enables a third retaining wall 44 in the base 4th is provided at a position between the movable spring and the stationary spring corresponding to the same contact group, which can protect the stationary spring and strengthen the insulation between the contacts. When the contacts (normally open ends) are held, the third support wall restricts movement of the stationary spring in the direction of movement towards the movable spring, thereby ensuring that the gap between the contacts of the normally closed ends is sufficient. On the contrary, the normally closed ends are held in place, this ensuring that the gap between the normally open ends is sufficient. The third retaining wall can also increase the creepage distance between the contacts and increase the insulation between the contacts.

The movable spring used for a safety relay and the safety relay of the movable spring in the present disclosure enable a track groove 46 to press the magnet system 2 into the base cavity 45 is provided along the horizontal direction. The base cavity 45 uses a rail structure. When the magnet system is installed, the track groove has 46 the basis a guiding effect on the yoke 21st of the magnet system 2 this can prevent the coil from colliding with the base and closing Damage results in the enamelled wire during the installation process.

Compared to the prior art, the present disclosure has the following advantageous effects:

1. The present disclosure enables the head portion of the spring body of the movable spring to be further provided with an outwardly extending extension portion, the extension portion having a first extension portion extending in a direction of about 90 degrees from the other side one end of the head portion of the spring body is angled, and has a second extension portion extending in a direction of about 90 degrees that is angled from one end of the first extension portion to the tail portion of the spring body. A recess is surrounded by the tail portion of the head portion of the spring body, the first extension portion and the second extension portion (it is synonymous to form the movable spring in an inverted J-shaped structure). In addition, a pressure arm is provided on the actuator and the pressure arm of the actuator is fitted into the recess of the movable spring (the recess is actually attached to the pressure arm with the opening facing downwards, or it can be said that the movable spring is attached to the pressure arm of the Actuator is clamped), whereby the forced guidance of the relay in the forward and reverse direction is achieved. That is, if the actuator 5 is moved forward, the movable spring is moved forward, and when the actuator is moved backward, the bending portion (ie, the second extension portion) of the movable spring pulls the push arm of the actuator and is moved backward together with the actuator. When the moving contact and the stationary contact are glued together, the actuator is allowed to 5 stop moving, ensuring that the contact groups are closed.

2. The present disclosure enables the lower surface of the first extension portion to cooperate with the upper surface of the pressure arm of the actuator so that the actuator can be prevented from contacting the housing of the relay in a direction perpendicular to the movement of the actuator. That is, it is equivalent to limiting the upper portion of the actuator, thereby preventing the friction between the actuator and the housing, which will cause the relay to function abnormally.

3. The present disclosure allows the movable spring to be clamped to the actuator's pressure arm. If the tail portion (i.e., the foot portion) of the spring body breaks, the movable spring will still be clamped to the pressure arm of the actuator. The spring body will not fall down when it is suspended, thus there will be no accidental connection, and the safety of the safety relay can be ensured. However, in the prior art safety relay, if the root portion of the spring tongue breaks, the spring may fall obliquely into the base, and then the terminal of the movable spring and the stationary spring member are connected, and this affects the safety of the relay.

4. The present disclosure enables a downwardly convex rib to be provided along the direction of movement of the actuator in the center of the housing. A groove is provided in the center of the base along the direction of movement of the actuator. When the housing is attached to the base, the rib of the housing fits into the groove in the base. The present disclosure serves three functions through the interaction of the rib and the groove. First, the convex rib has a guiding and limiting effect on the movement of the actuator, thereby reducing the occurrence of the situation that the functional lag of the contacts due to the deflection of the actuator becomes smaller, which affects the life of the relay. Second, the convex rib cooperates with the base, thereby increasing the creepage distance and air gap between the left and right contact groups (i.e., both sides of the first retaining wall). Third, the convex rib is pressed against the base to play a role in constraining the housing, thereby ensuring the distance between the surface of the housing and the actuator and the distance between the surface of the housing and the movable spring, while maintaining the flexibility of the Actuator and the movable spring is guaranteed.

5. The present disclosure enables the base also to provide the second support wall at a position between two adjacent contact groups corresponding to the same side of the first support wall, which can prevent splashes in the contacts from interfering with each other Reduce splash contamination between groups of contacts and ensure contact reliability.

6. The present disclosure enables a third support wall also to be provided in the base at a position between the movable spring and the stationary spring corresponding to the same contact group, which can protect the stationary spring and reinforce the insulation between the contacts . When the contacts (normally open ends) are held, the third support wall restricts the movement of the stationary spring in the direction towards the movable spring, ensuring that the gap between the contacts of the normally closed ends is sufficient. In contrast, the normally closed ends are restrained, ensuring the gap between the normally open contacts. The third retaining wall can also increase the creepage distance between the contacts and increase the insulation between the contacts.

7. The present disclosure enables a track groove for pushing the magnet system into the base cavity along the horizontal direction to be provided in the base cavity. The base cavity uses a rail structure when installing the magnet system. The track groove of the base has a guiding effect on the yoke of the magnet system, which can prevent the coil from colliding with the base and causing damage to the enameled wire during the installation process.

The disclosure describes in detail an embodiment with reference to the accompanying figures and embodiments. However, the movable spring provided in the safety relay and the safety relay of the movable spring are not limited to the embodiments.

The above is only a preferred embodiment of the present disclosure and does not limit the present disclosure in any form. Without departing from the scope of the technical solutions of the present disclosure, any person skilled in the art can use the technical content disclosed above in order to make a large number of possible changes and modifications to the technical solutions of the present disclosure or to modify them into equivalent embodiments. Therefore, any simple and equivalent change and modification made to the above-described embodiments on the basis of the technical nature of the present disclosure without departing from the technical solutions of the present disclosure falls within the scope of the technical solutions of the present disclosure.

Claims (14)

A movable spring, which is used for a safety relay, with a spring body in the form of a straight plate, one side of a head portion of the spring body is fixedly connected to a movable contact, and a tail portion of the spring body with a connecting portion for attaching to a terminal of the movable A spring is provided, the head portion of the spring body also being provided with an outwardly extending extension portion, the extension portion having a first extension portion extending in a direction of about 90 degrees that angled from the other side of a tail end of the head portion of the spring body and has a second extension portion extending in a direction of approximately 90 degrees that is angled from one end of the first extension portion to the tail portion of the spring body. The movable spring after Claim 1 used for the safety relay, wherein a width of the extension portion is equal to a width of the head portion of the spring body, and the width of the head portion of the spring body is greater than a width of a central portion of the spring body and a width of the tail portion of the spring body. A safety relay having a magnet system, a movable spring part, a stationary spring part, an actuator and a base, wherein the movable spring part, the stationary spring part, the actuator and the magnet system are each installed on the base, and a movable contact and a stationary contact are each installed are in an adjustment position, wherein the actuator is connected between the magnet system and the movable spring part, and the movable spring part and the stationary spring part have a plurality of contact groups, the movable spring part having a movable spring and a connection of the movable spring Claim 1 or 2 having a tail portion of the spring body attached to the terminal of the movable spring, the terminal of the movable spring being inserted into the base, the actuator being provided with a pressure arm and the pressure arm of the actuator being fitted into a recess formed by a End of the head portion of the spring body, a first extension portion and a second extension portion is surrounded, wherein when one side of the pressure arm of the actuator is pushed toward the end of the head portion of the spring body, the movable spring is moved to stationary contact when the other side of the pressure arm of the actuator is pushed towards the second extension portion, the movable spring is moved away from the direction of the stationary contact, when the movable contact and the stationary contact are glued together, the actuator is unable to move any further, creating a closure of the contact groups ensured becomes. The safety relay after Claim 3 , the pressure arm of the actuator with a clearance fit is fitted between the end of the head portion of the spring body and the second extension portion. The safety relay after Claim 3 wherein one side of the pressure arm of the actuator and / or the other side surface of the pressure arm of the actuator represents an arcuate surface which protrudes outward in the center. The safety relay after Claim 3 , wherein a lower surface of the first extension portion is configured to cooperate with an upper surface of the pressure arm of the actuator, thereby preventing the actuator from contacting a housing of the relay in a direction perpendicular to movement of the actuator, the housing on the Base is attached to accommodate the magnet system, contact portions of the movable spring part and the stationary spring part, and the actuator. The safety relay after Claim 3 wherein the actuator is provided with a slot for inserting the movable spring and the pressure arm is arranged in the slot. The safety relay after Claim 3 , wherein the recess of the movable spring is clamped down on the pressure arm of the actuator, wherein when the tail portion of the spring body breaks, the movable spring is held to the actuator, thereby preventing accidental connection between the movable spring and the stationary spring and a Safety performance of the safety relay is improved. The safety relay after Claim 6 , wherein a downward convex rib is provided along a moving direction of the actuator in the center of the housing, a groove is provided along the moving direction of the actuator in the center of the base, wherein when the housing is attached to the base, the convex rib of the Housing is fitted into the groove of the base. The safety relay after Claim 9 wherein the convex ridge of the housing and the groove of the base are each provided in a plurality of mutually corresponding portions. The safety relay after Claim 9 wherein a first support wall is provided along the moving direction of the actuator in the center of the base, the plurality of contact groups are symmetrically arranged on both sides of the first support wall, and the groove is provided on the uppermost part of the first support wall. The safety relay after Claim 3 wherein a second support wall is provided in the base at a position between two adjacent contact groups corresponding to the same side of the first support wall to prevent splashes in the contacts from interfering with one another. The safety relay after Claim 3 wherein a third support wall is provided in the base at a position between the movable spring and the stationary spring corresponding to the same contact group. The safety relay after Claim 3 , wherein a base cavity is provided for fixing the magnet system in the base, a track groove for pressing the magnet system into the base cavity along a horizontal direction is provided in the base cavity.

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