An anti-short circuit structure (10) of a high-capacity relay, the structure (10) comprising a housing assembly (100) and a pushing assembly (200). The housing assembly (100) comprises two static contacts (110), a first magnetically conductive block (120), a cover body (130), a transition block (160), and a yoke plate (140). The first magnetically conductive block (120) is disposed on an inner side surface of the top part of the cover body (130). The pushing assembly (200) comprises a fixing support (210), a stop piece (220), a movable reed (230), a second magnetically conductive block (240), an elastic member (250), and a push rod (260). The fixing support (210) comprises two fixing side arms (211) and a receiving plate (212). One end of the stop piece (220) is connected to the tail end of one fixing side arm (211), and the other end of the stop piece (220) is connected to the tail end of the other fixing side arm (211). Two ends of the movable reed (230) are disposed facing the two static contacts (110) respectively, and the second magnetically conductive block (240) is disposed facing the first magnetically conductive block (120). The first magnetically conductive block (120) and the second magnetically conductive block (240) are used to form magnetic flux. In the described anti-short circuit structure (10), when a coil is excited, the positions of the first magnetically conductive block (120) and the second magnetically conductive block (240) do not change due to overtravel. A magnetic air gap does not increase as overtravel increases, and an increase in overtravel does not affect magnetic attraction and does not affect the anti-short circuit function of the relay.

A high frequency relay is provided with an insulating outer housing, a relay body including an electromagnet unit and a contact mechanism unit, and a shield member. The relay body has a plate-like relay terminal, and the relay terminal is disposed such that the plate surfaces of the relay terminal extend along second surfaces of the relay body and one of the plate surfaces is exposed from at least one of the second surfaces. On the second surface, an insulator capable of insulating the relay terminal and the shield member is provided between the plate surface of the relay terminal and the shield member.

A relay of the present disclosure includes an insulation cover, a first yoke plate, a contact assembly, a driving assembly and a pressure relief valve assembly. The first yoke plate is connected with the insulation cover and encloses a contact chamber with the insulation cover. The first yoke plate is provided with a pressure relief hole. The driving assembly is connected with the movable contact piece and configured to drive the movable contact piece move. The pressure relief valve assembly is arranged on the first yoke plate and configured to close the pressure relief hole when a gas pressure in the contact chamber is less than a threshold and configured to be broken to open the pressure relief hole when the gas pressure in the contact chamber is greater than or equal to the threshold.

A stationary contact spring for a relay includes a base section fixed in a housing of the relay, a contact area opposite the base section adapted to perform an electric switching with a contact force, a spring section extending between the base section and the contact area, and an abutting latch abutting the housing with a biasing force directed against the contact force.

A spring assembly for biasing an armature of a switching device includes a spring base and a spring arm protruding from the spring base. The spring base has an embossment positioning the spring assembly in the switching device. The spring arm biases the armature.

The disclosure provides fixing structure between a metal part and a plastic part of a relay/circuit breaker, comprising a metal part, a first plastic part and a second plastic part. A positioning groove is disposed on the first plastic part, one portion of the metal part is inserted and positioned in the positioning groove, and the other portion of the metal part is positioned between the first plastic part, and the second plastic part; a through hole is disposed at the second plastic part near to the positioning groove, glue is dispensed into the positioning groove though the through hole. A first glue blocking rib suitably fitting with a corresponding side of the other portion is respectively disposed at a position of the first plastic part corresponding to both sides of the positioning groove to prevent the glue from following to an inside of the relay/circuit breaker.

An electromagnetic contactor 1 includes a case including an arc extinguishing chamber, an arc extinguishing cover attached to the case and covering the arc extinguishing chamber, and terminal covers arranged on the arc extinguishing cover and attached to the case. The case is formed with a first engagement portion, and the terminal covers are formed with a second engagement portion that is engaged with the first engagement portion to hold the terminal covers on the case. Then, the terminal covers are held on the case in either a first state where there is a gap between the first and second engagement portions or a second state where the terminal covers move in directions away from the arc extinguishing cover and the first and second engagement portions are engaged.

An electromagnetic relay includes a support member, a first fixed terminal, a second fixed terminal, a movable contact piece, a movable member. The support member is made of an insulating material. The first fixed terminal includes a first fixed contact and is supported by the support member. The second fixed terminal includes the second fixed contact and is supported by the support member. The movable contact piece includes a first movable contact and a second movable contact. The movable member is connected to the movable contact piece and includes a first overlapping portion made of an insulating material. The first overlapping portion is disposed between the first fixed terminal and the second fixed terminal. The first overlapping portion overlaps with the support member when viewed from a longitudinal direction of the movable contact piece in an open state where the first movable contact is separated from the first fixed contact.

A contact device according to an embodiment includes: a fixed contact assembly including a first fixed contact and a second fixed contact; and a moving contact assembly including a first moving contact and a second moving contact. The moving contact assembly includes: a first moving member; and a second moving member. The second moving member is arranged, in a first direction, between the first moving member and the fixed contact assembly and fixed to the first moving member at one end in a second direction intersecting with the first direction. The first moving contact and the second moving contact move as the first moving member moves. A first distance from the one end in the second direction to the first moving contact is longer than a second distance from the one end in the second direction to the second moving contact.

A relay includes an armature, a yoke configured to be electromagnetically coupled to the armature, and a bracket-shaped clamping spring. The armature lies at least partially flat on the yoke, and a receiving depression is partly formed in the armature. The bracket-shaped clamping spring surrounds the armature and the yoke on an end face such that the armature is fixed on the yoke. The bracket-shaped clamping spring has a first clamping limb arranged in the receiving depression of the armature, and a second clamping limb lying on the yoke. The first clamping limb has an angled tab which engages elastically into a recess formed in the receiving depression of the armature.