EP1646854A1

EP1646854A1 - Sensor device

Info

Publication number: EP1646854A1
Application number: EP04738716A
Authority: EP
Inventors: Thomas Fessele; Masoud Habibi; Christian Roesser; Markus Ledermann; Jan Gebauer
Original assignee: Robert Bosch GmbH
Current assignee: Robert Bosch GmbH
Priority date: 2003-07-15
Filing date: 2004-06-18
Publication date: 2006-04-19
Also published as: CN1823267A; WO2005008205A1; DE10331967A1; JP2006510920A; US20050247133A1; US7036380B2

Abstract

The invention relates to a sensor device, especially a pressure sensor, comprising a housing (1) provided with a inner housing area (12) wherein a sensor element (9) is arranged, also comprising electric connection elements (7) which are guided from the outside though a housing part (2) into the housing inner area (19), further comprising connection elements (17) which are electrically connected to the sensor element on an inner side (14) of the housing part (2) and which enter the inner housing area at each inlet point (15). Said sensor device also comprises a protective covering (21) which covers the connection sections and the sensor element. A sealing material (20) is applied to the connection sections (17) at least in the region of the inlet points (15) of the connection sections (17) in the housing inner area (19) and to the part (13) of the inner side (14) of the housing part (2) surrounding the inlet points (15), and the protective covering (21) is disposed on the sealing material (20) and on the connection sections (17) in order to prevent air sacs from penetrating the protective covering.

Description

sensor device

State of the art

The invention relates to a sensor device, in particular a pressure sensor, with the features of the preamble of independent claim 1.

Such a sensor device is known for example from US Pat. No. 6,521,966 B1. In contrast to known sensor devices of older design, in which the sensor element was applied to a printed circuit board or a hybrid and the connection elements of the sensor device were contacted with the printed circuit board or the hybrid, the sensor element in the sensor devices shown in US Pat. No. 6,521,966 B1 which can also be a chip with an integrated evaluation circuit, inserted into a housing of the sensor device without using a printed circuit board or a hybrid. For this purpose, the sensor element can, for example, be bonded indirectly or directly to the inside of a housing part, which is, for example, an injection-molded part made of plastic, and then electrically contacted by means of bonding wires with connection sections of the connection elements that protrude into the interior of the housing. It is also possible to solder interference suppression capacitors (EMC capacitors) or similar components to the connection sections or to glue them on using a conductive adhesive and then to connect them to the sensor element using bonding wires. To protect against mechanical or chemical stress, a protective cover made of gel is applied to the sensor element provided with the integrated evaluation circuit, which also covers the bond wires and the exit point of the connection elements from the housing plastic. Advantages of the invention

When applying the gel, make sure that there are no air pockets in the gel and that no air bubbles form over the life of the sensor. Even if care is taken to ensure that when the gel is applied to the sensor element and the connection sections in the protective cover, there are initially no air inclusions, it cannot be ruled out in the case of the sensors known from the prior art that air from the area between the connection elements and the housing part, which was either enclosed from the beginning by the injection molding process or which only penetrated into this area from the outside along the connection elements after the manufacture of the sensor device, at the point of entry of the connection sections into the interior of the housing into the gel existing protective cover arrives. In the case of pressure sensors in particular, the air pockets that have entered the protective cover can expand explosively or shoot quickly through the gel and thereby cause damage to the bond wires. This makes the sensor unusable.

The sensor device according to the invention advantageously prevents air, which has penetrated into the area between the connection elements and the plastic of the housing part or was already contained there due to the production, from penetrating into the protective cover made of gel. This is advantageously achieved by a sealing material that is applied in the area of the entry point of the connection sections into the housing interior and the part of the inside of the housing part surrounding the entry point. The sealing material seals the entry point of the connection sections on the inside of the housing, so that no air can get into the protective cover.

Advantageous refinements and developments of the invention are made possible by the measures contained in the dependent claims.

In a particularly simple manner, a sealing adhesive can be used as the sealing material, which is applied to the inside of the housing part provided with the sensor element in the region of the entry point of the connection elements into the interior of the housing.

The sealing material can in particular be a curable sealing material. Advantageously, a receptacle for the sealing material surrounding the entry point of the connection sections is formed on the inside of the housing part, so that the sealing material can be applied with a metering device and then distributed in the receptacle.

drawing

An embodiment of the invention is shown in the drawing and is explained in the following description. The single figure shows a cross section through a sensor device according to the invention, which in the example shown is designed as a pressure sensor.

Description of an embodiment

The single figure shows a sensor device in cross section, which in the example shown is a pressure sensor. The sensor device has a housing 1 which hides an interior 19 of the housing. The housing 1 is formed in two parts with a first housing part 2 and a second housing part 3, which can be placed on the first housing part 2. The second housing part 3 has a pressure connection 4 with a pressure channel 5 opening into the housing interior 19. The first housing part 2 can be connected to the second housing part 3 by gluing, snapping, welding or in another suitable manner. Both housing parts 2, 3 are made of plastic in the exemplary embodiment shown here. The first housing part 2 has connection elements 7, which are introduced into the first housing part 2 as insert parts. This can be done, for example, by an injection molding process. The connection elements 7 are felt from the outside through the housing part 2 into the housing interior 19 and have connection sections 17 which enter the housing interior 19 on the inside 14 of the first housing part 2 at one entry point 15 each. The outer ends 18 of the connection elements 7 facing away from the connection sections 17 are led out of the housing part 2 to the rear (not shown in the figure) and serve to contact the sensor device with external devices. The part 13 of the inside 14 surrounding the entry point 15 of the connection sections 17 forms a receptacle which is delimited by an outer wall 12 on the side facing away from the sensor element and by an inner wall 11 on the side facing the sensor element. Between the inner wall 11 and the outer wall 12, a sealing material 20 is applied to the part 13 of the inside of the housing part 2 in such a way that the sealing material in the region of the entry point 15 covers the outer wall of the connecting sections 17 and the part 13 surrounding the inside. The sealing material 20 can advantageously be a curable sealing material, for example a curable sealing adhesive, which hermetically seals the entry point 15.

The sealing adhesive should be as thin as possible in the uncured state so that it can penetrate well into the capillaries. In the hardened state, the sealing adhesive should be resistant to temperature changes and still be tough and not brittle in order not to form cracks when subjected to temperature changes. For example, a one- or two-component epoxy resin adhesive could be used as the sealing adhesive. However, a poly-urethane adhesive, an acrylate adhesive or another suitable adhesive can also be used.

The ends of the connecting sections 17 protruding into the interior 19 protrude a little from the sealing material 20 and are connected to the sensor element 9 via bonding wires 16. The sensor element 9 is a pressure sensor chip which is applied to a glass base 8, which in turn is glued to the inside 14 of the housing part 2, for example. A protective cover 21 made of a gel, for example a silicone gel, is applied to the inside 14 of the housing part 2 within the area delimited by the outer wall 12. The gel completely covers the ends of the connection sections 17 protruding from the sealing material, the bonding wires 16, the inner wall 11 and the sensor element 9.

It can be seen that air inclusions that could get into the housing interior 19 and the protective cover 21 at the entry point 15 of the connection elements 17 without a countermeasure are prevented from this by the sealing material 20. Damage to the bond wires 16 is thus advantageously avoided.

Claims

Expectations

1. Sensor device, in particular pressure sensor, with a housing (1) with a housing interior (12) in which a sensor element (9) is arranged, and with electrical connection elements (7), which from the outside through a housing part (2) into the Are passed through the housing interior (19) and on an inner side (14) of the housing part (2) at each entry point (15) in the housing interior entering, directly or indirectly electrically connected to the sensor element, connecting sections (17), and one with the connecting sections and the protective cover (21) covering the sensor element, characterized in that a sealing material (20) on the connection sections (17) at least in the area of the entry point (15) of the connection sections (17) into the interior of the housing (19) and the area surrounding the entry point (15) Part (13) of the inside (14) of the housing part (2) is applied and that the protective cover (21) on the sealing material (20) and the connecting section itte (17) is applied.

2. Sensor device according to claim 1, characterized in that the sealing material (20) is a curable sealing material.

3. Sensor device according to claim 1 or 2, characterized in that the sealing material (20) is a sealing adhesive.

4. Sensor device according to claim 1, characterized in that the protective cover (21) is made of a gel, in particular a silicone gel.

5. Sensor device according to claim 1, characterized in that the part (13) surrounding the connection sections (7) of the inside (14) of the housing part (2) has a receptacle for the sealing material with an inner wall (11) facing the sensor element (9). and forms an outer wall (12) facing away from it.

6. Sensor device according to claim 5, characterized in that the outer wall (12) also forms a frame which laterally delimits the protective cover (21).

7. Sensor device according to one of claims 1 to 6, characterized in that the connecting sections (17) are electrically connected to the sensor element (9) via bonding wires.

8. Sensor device according to one of claims 1 to 7, characterized in that the protective cover (21) completely covers the sealing material (20).

9. Sensor device according to claim 8, characterized in that the protective cover (21) from the sealing material (20) projecting ends of the connecting sections (17) completely covers. The method for providing a sensor device according to one of claims 1 to 9, characterized in that in a first step a sealing material (20) on the connection sections (17) at least in the area of the entry point (15) of the connection sections (17) into the interior of the housing and the the part (13) surrounding the entry point (15) of the inside (14) of the housing part (2) is applied and then in a second step the protective cover (21) is applied to the sealing material (20) and the connecting sections (17).