A circuit assembly is provided with a circuit unit that includes an electrically conducting path on which electronic components are mounted, a heat discharging member that is placed on the circuit unit, and is configured to discharge heat of the circuit unit, and a spacer that is disposed between the circuit unit and the heat discharging member. The spacer is provided with a main portion that is disposed between the circuit unit and the heat discharging member, and accommodating portions that accommodate a part of the circuit unit.

A motor controller, including: a control box, a control circuit board, a first press strip, a control chip, and a plurality of plastic press blocks. The control box includes: an inner wall, a bottom, and a cavity formed by the inner wall and the bottom. The control circuit board is disposed on the bottom of the control box. The control chip is disposed on an outer edge of a top face of the control circuit board. The plastic press blocks are disposed in a middle of an end face of the first press strip. Two ends of the first press strip and the inner wall of the control box are assembled together. The control chip is pressed on the inner wall of the control box via the plastic press blocks.

The present disclosure pertains to an arrangement comprising a housing, a circuit board arranged in the housing and at least one flat contact to connect the circuit board with an electrical component arranged outside of the housing, whereby the housing has a breakthrough that the flat contact protrudes from, whereby the circuit board has breakthrough that the flat contact reaches through, that the circuit board has a contact tab on the side facing away from the housing breakthrough and whereby a molded seal is inserted in the housing breakthrough and the molded seal positively encloses the flat contact and whereby the contact tab is connected with the flat contact in an electrically conductive manner.

Systems, methods, and articles for a portable power case are disclosed. The portable power case is comprised of at least one battery and at least one PCB. The portable power case has at least one USB port and at least two access ports, at least two leads, or at least one access port and at least one lead. The portable power case is operable to supply power to an amplifier, a radio, a wearable battery, a mobile phone, and a tablet. The portable power case is operable to be charged using solar panels, vehicle batteries, AC adapters, non-rechargeable batteries, and generators. The portable power case provides for modularity that allows the user to disassemble and selectively remove the batteries installed within the portable power case housing.

An electronic control device (10) includes a housing having a plurality of housing members (1) joined together, a housing vent hole (2) formed through the housing member (1) so as to extend in a thickness direction of the housing member, a protection wall (3) covering an outer opening (2b) of the housing vent hole (2), with a gap (3b) left between the protection wall (3) and the outer opening (2b), a protection-wall vent hole (3a) formed in the protection wall (3) at a position apart from the housing vent hole (2) so as to extend from the gap (3b) in a radial direction of the housing vent hole (2), and an air-permeable waterproof membrane (5) fixed to an inner opening (2a) of the housing vent hole (2). A vent passage (6) with a bent part (6a) is formed between the air-permeable waterproof membrane (5) and the protection-wall vent hole (3a).

To provide an electronic control device capable of suppressing leakage of radio-frequency radiation noise, radiated from a noise source, to the outside. The electronic control device includes a radio-frequency circuit 104 at least a part of which is driven at a radio frequency, a printed circuit board 101 on which a low-frequency circuit 103 that is driven at a low frequency is mounted, a housing 100 made of metal that includes therein the printed circuit board 101 together with the radio-frequency circuit 104 and the low-frequency circuit 103, a plurality of radio-frequency connectors 106a to 106f for transmitting and receiving signals related to the radio-frequency circuit 104 mounted on the printed circuit board 101 to and from the outside of the housing, a low-frequency connector 105 for transmitting and receiving signals related to the low-frequency circuit 103 mounted on the printed circuit board 101 to and from the outside of the housing, and a partition wall 203 for suppressing propagation of radiation noise, radiated by driving the radio-frequency circuit 104, to the low-frequency connector 105.

The invention relates to a front plate for a housing of a control installation, having a feedthrough for a plug connector. The front plate has at least one compensation element for compensating a tolerance-related offset (V.sub.A, V.sub.R) between the plug connector and the feedthrough (10) is disposed in the feedthrough and/or adjacent to the feedthrough.

The invention relates to a modular assembly that comprises at least two housing parts (1), in which in each case a circuit board (L) is received, at least one internal connecting means (17), one cover element and one closing element. Each housing part (1) is formed from a base plate (3), a rear wall (5) and side walls (4) that are connected to said rear wall. The housing parts (1) are stacked in such a manner that the side walls (4) combine to form a first (6) and a second complete side wall (7), and that the rear walls (5) combine to form a complete rear wall (8). At least two of the housing parts (1) are stacked in such a manner that the base plate (3) of the one housing part (1) is connected to the side walls (4) of the other housing part (1). The at least one internal connecting means (17) extends in a direction perpendicular to the base plates (3) and connects multiple circuit boards (L) by way of first connectors (18). The cover element lies on the side walls (4) of precisely one housing part (1). The closing element is attached to a front side on the housing parts (1), said front side lying opposite the complete rear wall (8).

A circuit board of an electronic control device has a surface to which a connector is attached and on which a heat generating component is mounted. A metal casing that stores therein the circuit board has an opposing surface that faces the surface of the circuit board on which the heat generating component is mounted. A first fin that protrudes toward the surface on which the heat generating component is mounted is provided on the opposing surface of the casing. The first fin overlaps the heat generating component in the thickness direction of the circuit board.

A magnetically held diaper monitor comprises a power supply part and a control part. The power supply part comprises a lower shell, and a battery and a power circuit board embedded in the lower shell. The power circuit board is provided with a plurality of lower magnetic electrodes and two lower magnetic terminals. The control part comprises an upper shell and a control circuit board embedded in the upper shell. The control circuit board is provided with upper magnetic electrodes which are in one-to-one correspondence to the lower magnetic electrodes, and upper magnetic terminals which correspond to the lower magnetic terminals. A diaper sensor is clamped between the power supply part and the control part which are combined into a whole by attraction by means of a magnetic force and is connected to the control part via the magnetic electrodes. The control part obtains a power supply via the magnetic terminals.