DE102020100309A1 - Folding armature relays suitable for high current loads - Google Patents

Abstract

The present disclosure of a hinged armature relay has a housing, a magnetic circuit system and a contact system. The magnetic circuit system has an armature iron, a yoke iron, an iron core and a coil wrapped with a magnet wire. The iron core leads through the coil. The yoke is L-shaped. One side of the yoke is connected to one end of the iron core and the other side of the yoke is mounted on the side surface of the coil. The contact system has a movable form spring, a static spring and a connection terminal. The movable form spring is L-shaped. One side of the movable form spring is connected to one side of the yoke iron and the other side of the movable form spring is connected to the anchor iron.

Description

TECHNICAL PART

The present disclosure relates to a folding armature relay / clapper type relay / folding type relay, and in particular relates to a folding armature relay suitable for large current loads.

STATE OF THE ART

A conventional hinged armature relay usually has a magnetic circuit system and a contact system. The magnetic circuit system has an armature iron / armature, a yoke iron / yoke, an iron core and a coil wound with enamelled wire / enamelled wire / enamelled wire. The contact system has a movable form spring / spring, equipped with a movable contact and a fixed spring output pin / spring output pin. The movable form spring of this type of relay is usually thin. When connected to a large current load, usually when the movable form spring is used as the output pin, the part of the output pin requires lamination in order to enlarge the current-carrying area of the movable form springs and to avoid high current densities of the movable form springs, which is the difficulty of mold making increased. In particular, the movable form spring is usually curved, which further increases the difficulty of the lamination of the starting pin, which makes it difficult to carry out the work process. In order to solve this problem in the prior art, a folding armature relay is disclosed in which the output pin of the movable form spring is arranged on the yoke iron. The advantage of this is that the construction is simpler and the work process is easy to accomplish and that it also simplifies the design of the movable form spring. However, the movable form spring is made of a copper alloy and the main material of yoke is pure iron, and the conductivity of iron is far less than the conductivity of copper, so that there are disadvantages of low conductivity and high temperature. In particular, when the loop current is higher, the high temperature rise will cause a decrease in the performance of the electromagnetic relay and the negative effects caused by the high temperature of the circuit board will increase.

SUMMARY

The present disclosure discloses a folding armature relay suitable for large current loads, which solves the existing night part of the existing folding armature relay, that the output pin of the movable form spring is arranged on the yoke.

The technical solution adopted by the present disclosure to solve the technical problem is therefore: A folding armature relay suitable for large current loads, which has a housing, a magnetic circuit system and a contact system. The magnetic circuit system has an armature iron, a yoke iron, an iron core and a coil wrapped with a magnet wire. The iron core runs through the coil. The yoke is L-shaped. One side of the yoke is connected to one side of the iron core and the other side of the yoke is mounted on the side surface of the coil. The contact system has a movable form spring and a static spring. The static spring is located on the coil and is equipped with a static contact and a static spring output pin. The movable form spring is L-shaped. One side of the movable form spring is connected to the other side of the yoke. The other side of the movable form spring is connected to the anchor iron and ensures that the anchor iron is pressed against a knife edge / thin edge of the yoke iron and that it corresponds to the other end of the iron core. The other side of the movable form spring is equipped with a movable contact which corresponds to the static contact of the static spring. The contact system also has a connecting terminal / connecting element / connecting part. The conductivity of the connection terminal is greater than the conductivity of the yoke and the thickness of the connection terminal is greater than the thickness of the movable form spring. The terminal is electrically connected on one side of the movable form spring and the end piece is equipped with a terminal output pin.

Furthermore, the terminal and the other side of the yoke are mounted with a stopper / position limit structure to prevent the terminal from moving in a direction parallel to the axis of the coil.

The terminal is also U-shaped. The left and right side of the connector are mounted on the left and right side of the other side of the yoke, and the left and right side of the connector and the other side of the yoke are mounted with the stop structure. The left and right side of the connection terminal are each electrically connected to one side of the movable form spring. The bottom of the connector is attached to one side where the end of the other side of the yoke is and a connector output pin is provided.

Furthermore, the stop construction has convex parts on the left and right side of the connection terminal and the Clamping recesses / clamping slots / clamping grooves are respectively arranged on the left and right ends of the other side of the yoke, or, the stop construction has convex parts on the left and right ends of the other side of the yoke and the clamping recesses are on the left and the right side of the connection terminal. Each convex part is clamped with the corresponding clamping recess.

Furthermore, the left and right sides of the connection terminal are each connected to one side of the movable form spring by using the riveting method.

Furthermore, the hinged armature relay suitable for large current loads further has an arc shielding structure / arc blocking structure / arc flashover blocking structure and the arc shielding structure is arranged between the contact group / contacts (including the static contact and the movable contact) and the housing.

Furthermore, the arc shield structure has an arc shield piece / arc flash blocking part, and the coil is equipped with a stopper / position limit piece / position limiting part to limit the movement deflection of the other side of the movable form spring at a position outside the other side of the movable form spring, and the arc shield piece is arranged on the stop piece .

Furthermore, the arc shielding areas of the left and right portions of the arc shielding piece are different, and the portion with a large arc shielding area corresponds to a side where the contact group generates more electric arc spatter.

Further, the arc shield piece and the stop piece are integrally molded, and the two form an L shape.

Furthermore, the connection terminal consists of pure copper or a copper alloy material; the terminal and the output pin are integrally formed therefrom.

• 1. Das Kontaktsystem beinhaltet weiterhin die Anschlussklemme und die Leitfähigkeit der Anschlussklemme ist größer als die Leitfähigkeit des Jocheisens und die Dicke der Anschlussklemme ist größer als die Dicke der beweglichen Formfeder und die Anschlussklemme ist elektrisch angeschlossen an einer Seite der beweglichen Formfeder und die Anschlussklemme ist mit einem Anschlussklemmen-Ausgangsstift ausgestattet, so dass die vorliegende Offenbarung nicht nur für eine Arbeitsumgebung mit großen Stromlasten geeignet ist, sondern auch die Probleme von geringer elektrischer Leitfähigkeit und schwerwiegender Hitzeentwicklung löst, die in Relais bestehen, die einen Jocheisen-Ausgangsstift aufweisen.
• 2. Die Anschlussklemme und die andere Seite des Jocheisens sind mit einem Anschlagstück zur Beschränkung der Bewegung der Anschlussklemme in eine Richtung parallel zur Achse der Spule befestigt, so dass die Verformung der beweglichen Formfeder und der Einfluss auf die Produktleistung, verursacht durch die mangelnde Zugleistung der Anschlussklemme oder des Anschlussklemmen-Ausgangsstifts, wodurch diese während des Montageprozesses angehoben wird, vermieden werden kann.
• 3. Die Positionsbegrenzung beinhaltet vorzugsweise den konvexen Teil und die Klemmaussparung, welche die Eigenschaften einer einfachen Form, einer einfachen Herstellung und anderes besitzt.
• 4. Die Anordnung der Lichtbogenabschirmkonstruktion kann die Lichtbogenspritzer davon abhalten das Gehäuse vollzusprühen und dadurch vermeiden, dass das Gehäuse an der Stelle nahe der Kontaktgruppe geschmolzen wird von den elektrischen Lichtbogenspritzern. Dies liegt daran, dass im Fall einer großen Stromlast, nach Vergrößerung der Kontaktlücke, die elektrische Lichtbogenabtragung schwerwiegender ist und die elektrischen Lichtbogenspritzer nach außen sprühen, was die Plastikteile um den Kontakt leicht zum Schmelzen bringt.
• 5. Die Lichtbogenabschirmkonstruktion beinhaltet vorzugsweise das Lichtbogenabschirmstück. Das Lichtbogenabschirmstück ist am Anschlagstück angeordnet, was das Problem eines unangenehmen Einbaus und den bestehenden aufwändigeren Prozess beim gesonderten Einbau des Lichtbogenabschirmstücks lösen kann und einen weiteren Einbau und eine Anschlagkonstruktion der Spule, angepasst an das Lichtbogenabschirmstück, vermeiden kann, um so die Konstruktionskomplexität der Spule zu vermeiden.
• 6. Die Lichtbogenabschirmflächen des linken und rechten Abschnitts des Lichtbogenabschirmstücks sind unterschiedlich, und der Abschnitt mit einer großen Lichtbogenabschirmfläche entspricht der Seite, wo die Kontaktgruppe/Anschlussgruppe/Kontakte/Anschlüsse mehr elektrische Spritzer erzeugt, so dass die vorliegende Offenbarung das Lichtbogenabschirmstück so klein wie möglich machen kann unter Gewährleistung einer effizienten Lichtbogenabschirmung, und dadurch Materialkosten spart.

Compared to the existing art, the advantageous effects of the present disclosure are as follows:

• 1. The contact system also includes the connection terminal and the conductivity of the connection terminal is greater than the conductivity of the yoke and the thickness of the connection terminal is greater than the thickness of the movable form spring and the connection terminal is electrically connected to one side of the movable form spring and the connection terminal is connected a terminal output pin, so that the present disclosure is not only suitable for a work environment with large current loads, but also solves the problems of low electrical conductivity and severe heat generation that exist in relays that have a yoke iron output pin.
• 2. The connector and the other side of the yoke are attached with a stopper to limit the movement of the connector in a direction parallel to the axis of the coil, so that the deformation of the movable form spring and the influence on the product performance caused by the lack of traction of the Terminal or the terminal output pin, which can be raised during the assembly process, can be avoided.
• 3. The position limitation preferably includes the convex part and the clamping recess, which has the properties of a simple shape, simple manufacture and others.
• 4. The arrangement of the arc shield construction can prevent the arc spatter from fully spraying the housing and thereby prevent the housing from being melted by the electrical arc spatter at the location near the contact group. This is because, in the event of a large current load, after widening the contact gap, electric arc ablation is more severe and the electric arc spatter spray outwards, which easily melts the plastic parts around the contact.
• 5. The arc shield construction preferably includes the arc shield piece. The arc shielding piece is arranged on the stop piece, which can solve the problem of unpleasant installation and the existing more complex process in the separate installation of the arc shielding piece and can avoid further installation and a stop construction of the coil, adapted to the arc shielding piece, so as to increase the construction complexity of the coil avoid.
• 6. The arc shielding areas of the left and right portions of the arc shielding piece are different, and the portion with a large arc shielding area corresponds to the side where the contact group / terminal group / contacts / terminals generates more electrical splashes, so that the present disclosure can make the arc shield piece as small as possible while ensuring efficient arc shielding, thereby saving material costs.

The present disclosure is described in more detail below with reference to the accompanying drawings and embodiments. However, a folding armature relay suitable for large current loads of the present disclosure is not limited to the embodiments.

Figure list

• 1 13 shows a structural view of the present disclosure;
• 2nd FIG. 14 shows a structural view of the present disclosure after rotating through an angle; FIG.
• 3rd FIG. 12 shows an installation view of the movable form spring, the connection clamp and the yoke of the present disclosure; FIG.
• 4th FIG. 2 shows an installation view of the two movable form springs, the connection clamp and the yoke of the present disclosure; FIG.
• 5 FIG. 12 shows a mounting view of the connector and yoke of the present disclosure;
• 6 13 shows a structural view of the stop structure and the arc shield structure of the present disclosure;

DETAILED DESCRIPTION

It is asked about the embodiments 1 . to 6 a hinged armature relay suitable for large loads is set forth in the present disclosure, and the relay is particularly foldable, but is not limited to this. The relay has a housing (not shown in the figure), a magnetic circuit system and a contact system. The magnetic circuit system has an anchor iron 4th , a yoke 3rd , an iron core (not shown in the figure) and one with a magnet wire 2nd wrapped coil 1 on. The iron core runs through the coil 1 . The yoke iron 3rd is L-shaped. A page 31 the yoke iron is connected to one end of the iron core and the other side 32 of the yoke is on the side surface of the coil 1 mounted, and is in particular on the window side of the wire winding of the coil 1 assembled. The contact system has a movable form spring 5 and a static spring 7 on. The static form spring 7 is on the coil 1 arranged, and is with a static contact 71 and a static spring output pin 72 Mistake. The movable form spring 5 is L-shaped. A page 51 The movable form spring is on the other side 32 of the yoke iron (in particular through the use of the riveting process, but not limited to this). The other side 52 the movable form spring is with the anchor iron 4th connected, and causes the anchor iron 4th against the thin edge of the yoke 3rd is pressed and corresponds to the other end of the iron core. The other side 52 The movable form spring is equipped with a movable contact, which is the static contact of the static form spring 7 corresponds. The contact system also has a connection terminal 8th on. The conductivity of the connection terminal 8th is greater than the conductivity of the yoke 3rd , and the thickness of the connector 8th is greater than the thickness of the movable form spring 5 . The connection terminal 8th is electrically connected on one side 51 the movable form spring, and the connection terminal 8th is with an output pin 81 fitted. The connector output pin 81 and the static spring output pin 72 are through the bottom surface of the coil 1 and are parallel to the axis of the coil 1 . The connection terminal 8th is made of pure copper or copper alloy material, and the connection terminal 8th and the terminal output pin 81 are made of it integrally.

In the present embodiment, the connection terminal 8th and the other side 32 of the yoke with a stop construction attached to the movement of the terminal 8th in a direction parallel to the axis of the coil 1 to prevent.

In the present embodiment, the connector is 8th U-shaped. The bottom 83 the connection terminal 8th is attached on one side to the end of the other side 32 of the yoke and the terminal output pin 81 provided. The other side 52 The movable form spring is equipped with a bending structure so that the part is on the other side 52 the movable form spring close to one side 51 the movable form spring is outside the connection terminal 8th and the rest of it is inside the connection terminal 8th located. In this way, the requirements of the reaction force of the form spring can be met. A page 51 The movable form spring is also partially as a left and right thin side 511 arranged, which can increase the flexibility of the movable form spring, so that the attraction force and the reaction force are matched to ensure the attraction performance. The left and right side 82 of the connector 8th are on the left and right side surfaces of the other sides, respectively 32 of the yoke iron, and each electrically with the side surface 51 connected to the movable form spring. Especially the left and right page 82 of the connector 8th is with one side surface 51 the movable form spring is firmly and electrically connected, using the riveting process. However, the connection method for the connector is 8th and the movable form spring 5 not limited to the riveting process and the welding or other joining process can also be used. The two riveting points on the left and right side 82 of the connector 8th and one side 51 the movable form spring are not parallel to the two riveting points on one side 51 the form spring and the other side 32 of the yoke iron, to prevent interference between the four riveting points after the expansion of the rivet setting head due to the close spacing.

In the present embodiment, the left and right sides are 82 of the connector 8th and the other side surface 32 of the yoke iron each connected to the stop construction. The stop construction includes in particular the convex parts 821 , each on the relative side inner surfaces of the left and right side surfaces 82 of the connector 8th are arranged and the clamping recesses 321 , each on the side outer surfaces of the left and right ends of the other side surface 32 of the yoke are arranged. Any convex area 821 is in each case with the associated clamping recess 321 clamped. The specific contour of the stop construction is not limited to this. In other embodiments, the stop structure has convex areas, respectively on the left and right ends of the other side 32 of the yoke are arranged and in which the clamping recesses on the left and right side surfaces 82 of the connector 8th are arranged on. The span of the connector 8th and the yoke iron 3rd can meet the requirements of fully automatic assembly. When reassembling, after riveting the connector 8th and the form spring 5 , the automatic assembly device is geared to the clamping process of the connector 8th and yoke iron 3rd and finally the riveting process of the movable form spring 5 and yoke iron 3rd executed in order to form an integral, conductive component.

In the present embodiment, the present disclosure includes an arc shield construction. The arc shield construction used to prevent the arc spatter (or called contact spatter) that occurs during the work process from spraying on the housing is between the contact group (including the static contact) 71 and the moving contact 6 ) and the housing. The arc shield construction includes the arc shield piece 91 and is made of stainless steel, but is not limited to this. The sink 1 is with a stop piece 9 equipped to the movement rash of the other side 52 the movable form spring at a point outside the other side 52 the movable spring. The arc shield piece 91 is on the stop piece 9 arranged and the two are made integrally and result in an L-shaped contour. Therefore, it can also be considered that the arc shield plate 91 is made by one end of the stop piece 9 close to the contact group in the direction where the contact group is located. In this way, the fact that the arc shield piece can be avoided 91 must be installed separately, which leads to an improvement in the assembly process and to the need for the stop construction on the coil 1 to arrange and assemble. The specific side of the stop 9 is in the lower part of the coil 1 inserted around the downward movement distance of the other side surface 52 limit the movable form spring. The left and right side of the stopper 9 is with clamp hooks 92 equipped so that the stop piece 9 firmly in the lower part of the coil 1 is clamped and thereby the stop piece 9 position effectively.

In the present embodiment, the shielding surfaces are the left portion and the right portion of the arc shield piece 91 different and the portion with a large arc shielding area corresponds to a side on which the group of contacts generates more electric arc spatter. Experiments show that arc spatter generated by the contact group is sprayed more in the direction where the right part of the arc shielding piece is located. Therefore, the arc shield area is the right portion of the arc shield piece 91 larger than the arc shielding area of the left portion of the arc shield piece 91 . In particular the outer edge area of the arc shielding piece 91 is strikingly trapezoidal and the two central areas of the trapezium are each an oblique edge and a right-angled side. The portion on which the right-angled side is located represents a portion with a large arc shielding area.

A hinged armature relay suitable for large current loads is disclosed in the present disclosure. The construction of the connection terminal 8th and the terminal output pin 81 can meet the requirements of automated assembly and can replace the output pin of the movable form spring. Not only is the construction of the movable form spring 5 is simplified and the process is easy to implement, which is advantageous for the miniaturization and compactness of the product, but the present disclosure is also able to cope with a work environment with large power loads. In addition, the present disclosure also solves the low conductivity and severe heat problems that exist in the present relays that use a yoke iron output pin. The connection terminal 8th is U-shaped and the left and right sides thereof are on the left and right sides of the other side, respectively 32 of the yoke iron, so that the overall construction can be kept compact and occupies only a small space. The left and right side 82 the connection terminal 8th and the other side 32 of the yoke are assembled with the stop construction, which is the connection terminal 8th limit in the vertical direction and which the deformation of the movable form spring 5 and the impact on product performance caused by the lack of pulling power of the connection terminal 8th or the terminal output pin 81 , which can be raised during the assembly process.

The arrangement of the arc shield piece 91 can effectively eliminate electrical arc spraying towards the housing when the contact gap is increased and the electrical arc meltdown is more severe at high current loads and thereby prevent the housing from being partially melted by the electrical arc spatter. In particular, the arc shield piece 91 and the stop piece 9 are formed integrally. During the arc shielding effect of the arc shield piece 91 is guaranteed, the installation problem of the arc shield piece 91 effectively solved.

The embodiment described above is only used to further explain a folding armature relay of the present disclosure, which is suitable for high voltages, but the present disclosure is not limited to the embodiment. Any simple modification, equivalent change, and modification of the above-described embodiment in accordance with the essence of the invention of the present disclosure are within the scope of the technical solutions of the present disclosure.

Claims (10)

Folding armature relays suitable for large current loads, with a housing, a magnetic circuit system and a contact system, the magnetic circuit system comprising an armature iron, a yoke iron, an iron core and a coil wound with a magnet wire, which guides the iron core through the coil, the yoke iron L -shaped and one side of the yoke is connected to one end of the iron core and the other end of the yoke is attached to a side surface of the coil; wherein the contact system comprises a movable form spring and a static spring, the static spring being arranged on the coil and being equipped with a static contact and a static spring output pin, the movable form spring being L-shaped, having one side of the movable form spring the other side of the yoke iron is connected and the other side of the movable form spring is connected to the anchor iron so that the anchor iron is pressed against a thin edge of the yoke iron and corresponds to the other end of the iron core; the other side of the movable form spring is provided with a movable contact which corresponds to the static contact of the static spring; and wherein the contact system further comprises a connection terminal, the conductivity of the connection terminal is greater than the conductivity of the yoke, the thickness of the connection terminal is greater than the thickness of the movable form spring, and the connection terminal is electrically connected to one side of the movable form spring and the connection terminal is connected to a connector output pin. Folding armature relay suitable for large current loads according to Claim 1 , wherein the terminal and the other side of the yoke are equipped with a stop structure to restrict the movement of the terminal in a direction parallel to the axis of the coil. Folding armature relay suitable for large current loads according to Claim 2 , wherein the terminal is U-shaped, left and right sides of the terminal are attached to left and right sides of the other side of the yoke, left and right sides of the terminal and the other side of the yoke are equipped with the stop structure, and the left and right sides of the connection terminal are each electrically connected to one side of the movable form spring; and wherein a bottom of the connector is mounted on one side where the end of the other side of the yoke is and a connector output pin is provided. Folding armature relay suitable for large current loads according to Claim 3 , wherein the stop structure has convex parts which are respectively arranged on the left and right sides of the connecting terminal, and clamping recesses which are respectively arranged on the left and right ends of the other side of the yoke, or, the stop structure has convex parts, which respectively are arranged on the left and right ends of the other side of the yoke, and the clamping recesses, which are respectively arranged on the left and right sides of the connection terminal, and each convex part is clamped in the corresponding clamping recess. Folding armature relay suitable for large current loads according to Claim 3 , wherein the left and right sides of the connecting terminal are each fixed with one side of the movable form spring by using a riveting process. Folding armature relay suitable for large current loads according to Claim 1 , further with an arc shield construction, which is arranged between a contact group and the housing, the contact group having the static contact and the movable contact. Folding armature relay suitable for large current loads according to Claim 6 wherein the arc shield structure includes an arc shield piece, the spool is provided with a stopper to limit the movement of the other side of the movable mold spring at a position outside the other side of the movable mold spring, and the arc shield member is arranged on the stopper. Folding armature relay suitable for large current loads according to Claim 7 , where arc shielding areas of the left and right portions of the arc shielding piece are different, and a portion having a large arc shielding area corresponds to a side where the contact group generates more electric arc spatter. Folding armature relay suitable for large current loads according to Claim 7 , wherein the arc shield piece and the stop piece are integrally formed and form an L-shape. Folding armature relay suitable for large current loads according to Claim 1 , wherein the terminal is made of pure copper or a copper alloy material; and the terminal and its terminal output pin are integrally molded.

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