An electronic-component-equipped terminal block includes a terminal block including first and second through holes provided in a front wall; an electronic component including a component body first and second leads; and an electrically insulating attachment assistance tool. The attachment assistance tool includes a base portion arranged outside a housing such that a rear surface thereof abuts against the front wall; and first and second insertion portions protruding from the rear surface of the base portion to be thereby inserted into the first and second through hole, respectively. The attachment assistance tool is provided with a first passage portion through which the first lead is inserted, and a second passage portion through which the second lead is inserted, and a receiving portion that receives and accommodates a rear portion of the component body is provided at a front-side position.

In electrocardiography (ECG) system, a patient cable connecting one or more electrodes to a processing device for processing ECG signals may include one or more electrode connectors mechanically keyed to respective electrodes and/or a device connector mechanically and/or electronically keyed to a cable connector of the processing device. In some embodiments, keying between the cable and electrode is achieved, for example, with an electrode including a hollow-post portion that defines a bore in conjunction with a post protruding from an arm of the electrode connector that is sized to fit within the bore.

An embodiment is directed to a receptacle terminal for receipt of a mating terminal therein. The receptacle terminal includes a contact portion which has a bottom wall and resilient contact arms. The resilient contact arms extend from opposed sides of the bottom wall. Each of the resilient contact arms has an opening extending therethrough with a first resilient contact section and a second resilient contact section extending on either side of the opening. The first resilient contact sections and the second resilient contact sections have arcuate portions which extend from the bottom wall to mating terminal engaging members. The first resilient contact sections and the second resilient contact sections generate a contact force when a mating terminal is inserted into the terminal.

An embodiment is directed to a receptacle terminal for receipt of a mating terminal therein. The receptacle terminal includes a contact portion which has a bottom wall and resilient contact arms. The resilient contact arms extend from opposed sides of the bottom wall. Each of the resilient contact arms has an opening extending therethrough with a first resilient contact section and a second resilient contact section extending on either side of the opening. The first resilient contact sections and the second resilient contact sections have arcuate portions which extend from the bottom wall to mating terminal engaging members. The first resilient contact sections and the second resilient contact sections generate a contact force when a mating terminal is inserted into the terminal.

A gas sensor includes a sensing element having an electrode pad a metal terminal, and a separator that has insertion holes in which the metal terminal is held. The metal terminal includes a main body and an elastic portion that is integrally connected to the main body and is elastically connected to the electrode pad at a predetermined contact point. The main body includes a front-end-side restricting portion and a rear-end-side restricting portion that restrict the movement of the main body by contacting wall surfaces of the insertion hole when the main body moves in a direction intersecting the direction of an axial line. The contact point is located between the front-end-side restricting portion and the rear-end-side restricting portion in the direction of the axial line. The front-end-side restricting portion and the rear-end-side restricting portion are connected to each other so that a flat board portion is interposed therebetween.

Herein is described a n electrical earthing device formed from a sheet of material and comprising: an earthing device connector portion, for connection of the earthing device to a component to be earthed; and an earth cable connector portion, for connection to an earth cable. A first part of the earth cable connector portion is disposed in relation to a second part of the earth cable connector portion so as to define a clamping mechanism. In use, an earth cable positioned between the first and second parts is retained in position and maintained in electrical contact with the clamping mechanism by resilient biasing between the first and second parts of the clamping mechanism.

Herein is described a n electrical earthing device formed from a sheet of material and comprising: an earthing device connector portion, for connection of the earthing device to a component to be earthed; and an earth cable connector portion, for connection to an earth cable. A first part of the earth cable connector portion is disposed in relation to a second part of the earth cable connector portion so as to define a clamping mechanism. In use, an earth cable positioned between the first and second parts is retained in position and maintained in electrical contact with the clamping mechanism by resilient biasing between the first and second parts of the clamping mechanism.

A connection device includes: a first substrate; a second substrate located above the first substrate and disposed opposite to the first substrate; a protrusion provided on an upper surface of the first substrate and protruding from the first substrate toward the second substrate; a first terminal provided on the protrusion; and a second terminal provided on a lower surface of the second substrate and disposed opposite to the first terminal. The first terminal includes a first connector and a second connector, and the first connector and the second connector are electrically joined together. The second terminal includes: a third connector that contacts the first connector; and a fourth connector that contacts the second connector, and the third connector and the fourth connector are electrically joined together. The third connector is located above the first connector. The second connector is located between a first side surface of the protrusion and the fourth connector. The third connector has elasticity and presses against the first connector. The fourth connector has elasticity and presses against the second connector.

A connection device includes: a first substrate; a second substrate located above the first substrate and disposed opposite to the first substrate; a protrusion provided on an upper surface of the first substrate and protruding from the first substrate toward the second substrate; a first terminal provided on the protrusion; and a second terminal provided on a lower surface of the second substrate and disposed opposite to the first terminal. The first terminal includes a first connector and a second connector, and the first connector and the second connector are electrically joined together. The second terminal includes: a third connector that contacts the first connector; and a fourth connector that contacts the second connector, and the third connector and the fourth connector are electrically joined together. The third connector is located above the first connector. The second connector is located between a first side surface of the protrusion and the fourth connector. The third connector has elasticity and presses against the first connector. The fourth connector has elasticity and presses against the second connector.

An electrical power connector and an electrically conductive terminal are provided. The electrical power connector includes an insulating housing, multiple electrically conductive terminals, and at least one position fixing member. The insulating housing includes multiple column bodies and a convex rib structure, the column bodies extend in a first direction and are arranged at intervals, and the convex rib structure extends in a second direction and is formed in an intersecting arrangement. An inside of the insulating housing has multiple tunnels that correspondingly penetrate through the column bodies in the first direction. Multiple grid passages are formed by the convex rib structure. The electrically conductive terminals are respectively mated in the grid passages and the tunnels. The electrically conductive terminals are each connected to a cable. The at least one position fixing member is embedded on at least one side of the convex rib structure.