Abstract: In a system and method for open fitting hearing aid frequency response sound measurements, a test space is provided having located therein a sound source, a hearing aid with a microphone, and an open fit receiver. An acoustic shield is provided and within the acoustic shield an ear simulator coupler is provided having an ear extension attached thereto, the ear extension having mounted thereto at least a portion of the open fit receiver. A measurement unit receives sound signals from the ear simulator coupler.

Abstract: A power semiconductor module having a housing, a pressure member, a substrate including at least one contact surface, and at least one connection element leading towards the exterior of the housing. The connection element has a first contact device, a resilient section and a second contact device. The pressure member has two stop elements. The first contact device is electrically conductively connected to the contact surfaces of the substrate. The second contact device is arcuate in shape and has at least one deformation at the beginning and at the end of the arc, wherein, as a result of the deformations of the second contact device co-operating with the two stop elements of the pressure member, the connection element is prestressed.

Abstract: A tool is provided with which a receiver of a hearing aid can be easily fitted into an earpiece or an ear mold and removed therefrom. The tool has an elongate main body, a first tool part for removing the receiver from a first earpiece, a second tool part for removing the receiver from a second earpiece, and a third tool part for fitting the receiver into the first or second earpiece. The elongate main body is divided into a first subsidiary body and a second subsidiary body). The two subsidiary bodies can be plugged at least partially one inside the other in the direction of the longitudinal axis of the main body. In addition, two of the three tool parts are arranged on one of the two subsidiary bodies, and the remaining tool part is arranged on the other of the two subsidiary bodies.

Abstract: A power semiconductor module that includes a substrate having at least one power semiconductor element; a heat sink for dissipation of heat from the at least one power semiconductor element and a housing having a cutout which is arranged on a lower face of the housing facing the heat sink and holds the substrate; and to a method for production of such power semiconductor modules. The power semiconductor module has at least one holding element, which engages in a recess, which is associated with the at least one holding element, on the lower face of the housing and is designed such that it limits any movement of the substrate in the direction of the lower face of the housing.

Abstract: A housing for a power semiconductor module in which load-connecting elements having contact devices are arranged. The contact devices are arranged in housing troughs on the exterior of the housing. The housing troughs are formed at an associated lateral wall of the housing. The housing is closed off by a cover. The housing is preferably formed as a unitary piece of material having a circumferential sealing frame and the cover includes an outer rim that extends over the circumferential sealing frame, to prevent the penetration of fluid or moisture into the power semiconductor module when the cover is closed. On its inner rim, each housing trough includes a sealing rib formed of a section of the sealing frame. The associated load-connecting element is crimped about the sealing rib, so that the contact device is disposed within the trough.

Abstract: A circuit arrangement includes a power module combined with a printed circuit board. The power module and the printed circuit board are disposed between a heat sink and a pressing device and are contact-connected to one another by pressure contact elements. The power module has at least one module board element and a housing formed with shafts for the pressure contact elements. The shafts open out from the housing base facing printed circuit board at opening orifices. The base is formed with orifice sealing ribs around the opening orifices. Moreover, the base of the housing may have a peripheral edge sealing rib along its outer edge. Furthermore, a sealing area element can be provided between the printed circuit board and the base of the housing.

Abstract: A power semiconductor module having a housing, a pressure member, a substrate including at least one contact surface, and at least one connection element leading towards the exterior of the housing. The connection element has a first contact device, a resilient section and a second contact device. The pressure member has two stop elements. The first contact device is electrically conductively connected to the contact surfaces of the substrate. The second contact device is arcuate in shape and has at least one deformation at the beginning and at the end of the arc, wherein, as a result of the deformations of the second contact device co-operating with the two stop elements of the pressure member, the connection element is prestressed.

Abstract: In a system and method for open fitting hearing aid frequency response sound measurements, a test space is provided having located therein a sound source, a hearing aid with a microphone, and an open fit receiver. An acoustic shield is provided and within the acoustic shield an ear simulator coupler is provided having an ear extension attached thereto, the ear extension having mounted thereto at least a portion of the open fit receiver. A measurement unit receives sound signals from the ear simulator coupler.

Abstract: A power semiconductor module that includes a substrate having at least one power semiconductor element; a heat sink for dissipation of heat from the at least one power semiconductor element and a housing having a cutout which is arranged on a lower face of the housing facing the heat sink and holds the substrate; and to a method for production of such power semiconductor modules. The power semiconductor module has at least one holding element, which engages in a recess, which is associated with the at least one holding element, on the lower face of the housing and is designed such that it limits any movement of the substrate in the direction of the lower face of the housing.

Abstract: An arrangement with an associated production method, of a power semiconductor module in a pressure contact embodiment and a cooling component. The module includes load terminals embodied as metal molded bodies with a flat portion and a contact device originating at the flat portion, disposed within a housing. Each flat portion is disposed parallel to, and spaced from, the surface of the substrate. Contact feet extend from the flat portions to conductor tracks on the substrate. A pressure plate exerts pressure on the load terminals to hold them in place and establish electrical contact between the contact feet and the conductor tracks, while also establishing thermal contact between the load terminals and the cooling component. The cooling component, the housing, and the pressure plate form a first unit, which is mechanically decoupled from a second unit comprising the substrate and the load terminals.

Abstract: A power semiconductor module in a pressure contact embodiment, for disposition on a cooling component, in which load terminals are formed as metal molded bodies, each with at least one flat portion and having a plurality of contact feet extending from the flat portion. Each flat portion of the load terminal is disposed parallel to, and spaced from, the substrate. The contact feet also extend from the flat portion to the substrate, where they form the contacts of the terminal elements. A molded insulation body is disposed between the flat portions of the load terminals and the substrate, and this molded insulation body has recesses for permitting the passage therethrough of the contact feet.

Abstract: A power semiconductor module having an electrically insulating substrate, to be arranged with a circuit board. The circuit board is spaced apart from the substrate by a housing. First conductor tracks are disposed inside the substrate, facing the circuit board, for receiving power semiconductor devices which can be driven by a control IC device. Second conductor tracks are provided on the inside of the circuit board facing the substrate. In the housing, elastic connecting elements are pressure-contacted by a rigid pressure body to establish electrical connection between the first and second conductor tracks. An optimum electromagnetic compatibility is achieved due to the fact that IC conductor tracks and the control IC device are also provided on the inside of the substrate.

Abstract: A circuit arrangement includes a power module combined with a printed circuit board. The power module and the printed circuit board are disposed between a heat sink and a pressing device and are contact-connected to one another by pressure contact elements. The power module has at least one module board element and a housing formed with shafts for the pressure contact elements. The shafts open out from the housing base facing printed circuit board at opening orifices. The base is formed with orifice sealing ribs around the opening orifices. Moreover, the base of the housing may have a peripheral edge sealing rib along its outer edge. Furthermore, a sealing area element can be provided between the printed circuit board and the base of the housing.

Abstract: A housing for a power semiconductor module in which load-connecting elements having contact devices are arranged. The contact devices are arranged in housing troughs on the exterior of the housing. The housing troughs are formed at an associated lateral wall of the housing. The housing is closed off by a cover. The housing is preferably formed as a unitary piece of material having a circumferential sealing frame and the cover includes an outer rim that extends over the circumferential sealing frame, to prevent the penetration of fluid or moisture into the power semiconductor module when the cover is closed. On its inner rim, each housing trough includes a sealing rib formed of a section of the sealing frame. The associated load-connecting element is crimped about the sealing rib, so that the contact device is disposed within the trough.

Abstract: There is described a hearing aid device, in particular a hearing aid such as, for example, an ITE device, comprising a section which can be provided in or on an ear and from which a multi-channel tube projects, the free end section of which can be inserted into an outer auditory canal of the ear, wherein an earpiece channel of the multi-channel tube is acoustically connected to an earpiece and an auditory canal microphone channel of the multi-channel tube is acoustically connected to an auditory canal microphone, in each case inside the hearing aid device.

Abstract: A power semiconductor module, for placement on a cooling component. The module includes a substrate, at least two power semiconductor components arranged on the substrate, a housing and outwardly routed load and control connections. The substrate has an insulator body with a first main area that faces the interior of the power semiconductor module, and has interconnects at load potential arranged thereon. Each load connection is formed as a shaped metal body with outer contacts, a strip-like section and with inner contacts extending from the strip-like section to the substrate and making circuit-compliant contact therewith. In addition, the load connections are substantially completely encased by insulation except in the vicinity of the outer and inner contacts and accordingly are electrically insulated from one another.

Abstract: A power semiconductor module having an electrically insulating substrate, to be arranged with a circuit board. The circuit board is spaced apart from the substrate by a housing. First conductor tracks are disposed inside the substrate, facing the circuit board, for receiving power semiconductor devices which can be driven by a control IC device. Second conductor tracks are provided on the inside of the circuit board facing the substrate. In the housing, elastic connecting elements are pressure-contacted by a rigid pressure body to establish electrical connection between the first and second conductor tracks. An optimum electromagnetic compatibility is achieved due to the fact that IC conductor tracks and the control IC device are also provided on the inside of the substrate.

Abstract: An arrangement with an associated production method, of a power semiconductor module in a pressure contact embodiment and a cooling component. The module includes load terminals embodied as metal molded bodies with a flat portion and a contact device originating at the flat portion, disposed within a housing. Each flat portion is disposed parallel to, and spaced from, the surface of the substrate. Contact feet extend from the flat portions to conductor tracks on the substrate. A pressure plate exerts pressure on the load terminals to hold them in place and establish electrical contact between the contact feet and the conductor tracks, while also establishing thermal contact between the load terminals and the cooling component. The cooling component, the housing, and the pressure plate form a first unit, which is mechanically decoupled from a second unit comprising the substrate and the load terminals.

Abstract: A power semiconductor module in a pressure contact embodiment, for disposition on a cooling component, in which load terminals are formed as metal molded bodies, each with at least one flat portion and having a plurality of contact feet extending from the flat portion. Each flat portion of the load terminal is disposed parallel to, and spaced from, the substrate. The contact feet also extend from the flat portion to the substrate, where they form the contacts of the terminal elements. A molded insulation body is disposed between the flat portions of the load terminals and the substrate, and this molded insulation body has recesses for permitting the passage therethrough of the contact feet.

Abstract: The aim is to manufacture molded tubes for hearing instruments and other hearing devices more cost-effectively. To this end, there is provision for producing a bending mold with the aid of a rapid-prototyping method. An unmolded tube is inserted into the bending mold. Heat is then applied to the bending mold, including the inserted tube, such that after cooling the tube permanently assumes the shape predetermined by the bending mold. Rapid prototyping makes it possible to produce a bending mold for a variety of tube forms quickly and cost-effectively. It is thus no longer necessary to bend the tubes manually, as a result of which the degree of automation can ultimately be increased.