KR20090127908A - Connecting unit for a pressure measuring cell - Google Patents

Abstract

The invention relates to a connecting unit (10) for a pressure measuring cell (14). Said connecting unit comprises at least one plug (40) having at least one contact plate (56), substantially oriented in the axial direction of the plug (40), via which an electrical signal influenced by the pressure measuring cell (14) can be tapped. The contact plate (56) is configured in such a manner as to allow at least one axial tolerance compensation with a contact element (86) of a slide-on mating element (80), an interior of the plug (40) accommodating at least part of the circuit support (20) on which at least one circuit (24) or at least one electronic component (26) for processing at least one output signal of the pressure measuring cell (14) is arranged.

Description

CONNECTING UNIT FOR A PRESSURE MEASURING CELL

The invention relates to a connection unit for pressure measuring cells according to the preamble of the independent claim.

In DE 10 2004 033 846 A1 a valve incorporating a pressure sensor is known. Since the pressure sensor is integrated in the valve dome, no additional mounting and supporting member is required. By the bore in the pole core of the valve dome, the pressure of the hydraulic fluid is transmitted to the thin film of the measuring cell. A plurality of through bores are formed in the printed circuit board, through which the electrical contacts of the pressure sensor and / or the electrical components of the valve pass. The contact of the pressure sensor is made by, for example, a bond.

It is an object of the present invention to provide a space saving and rigid connection unit for pressure measuring cells. This object is achieved by the features of the independent claims.

The connection unit for pressure measuring cells according to the features of the independent claim has the advantage that the proposed plug is designed to be particularly low and therefore does not have a decisive influence on the height. This is achieved, in particular, because the plug is formed around the pressure measuring cell or the circuit carrier so that the height of the pressure sensor can be used fully in the device plug. On the circuit carrier is placed at least one circuit or at least one electronic component for processing (filtering or amplifying the signal) at least one output signal of the pressure measuring cell.

At least one contact sheet is also provided for contact. In this way, preferably the required axial tolerance range of the connection unit can be realized. In addition, manufacturing tolerances due to the internal structure, installation and adjustment of the magnetic valve can also be compensated simply. By the contact sheet, electrical connection of a corresponding part is formed by sliding contact. In this way, contaminating particles, which may be present in the case of the contact counterparts at the time of joining, are pushed sideways. Thus, for example, the electrical contact is improved compared to eg the point contact of the spring pin to the contact plate. In the case of sliding contact by the contact sheet, frictional corrosion of the contact is minimized.

By placing the contact surface of the pressure sensor in the radial direction, a contact is made without affecting the structure height. The lateral force on the pressure sensor is also minimized because the receiving means of the connecting unit or the valve coil only make very small relative movements with respect to the pressure sensor.

In a preferred embodiment, the plug is designed in the sleeve and the contact sheet is arranged on the outer surface of the plug, preferably on the cylindrical outer surface of the plug. Thereby, the height of the assembly space is further reduced because the internal space can be used for the reception of the circuit carrier, and the counterpart of the plug surrounds the plug for contact from the outside.

In a preferred embodiment, the plug comprises a recess in the outer surface, in which the contact sheet is at least partially received. This design of the plug is economically realized by injection molding and is characterized by the compactness and secure fixing of the contact sheet. Preferably the contact sheet and plug can be connected to each other by hot caulking.

In a preferred embodiment, the contact sheet comprises at least one spring tongue, which spring tongue preferably comprises an embossed portion at the end. By means of the spring tongue the contacts or conductive bonding points of the circuit carrier are particularly simply and reliably contacted-by spring properties-in particular in the subsequent permanent connection by the conductive adhesive. Also preferably, the plug comprises at least one through hole, through which the spring tongue is guided into the plug. The feature of this arrangement is the compactness of the device. In addition, the mechanical fixation of the contact sheet on the plug is also improved. Preferably a through hole or bore is provided in the upper face of the plug at the top of the contact spring. In the connection of the contact carrier with the conductive adhesive and the circuit carrier a hot forming die can be provided through the bore so that the connection can be quickly cured in seconds.

In a preferred embodiment, the top surface of the plug is provided with at least one chamfer and / or at least one channel. The chamfer is used on the manifold block, for example as a joining aid in the assembly of the mounting control device. By means of the channel, the manufacture of the plug can be optimized because the plug can be moved by the channel, for example in a defined assembly position in the vibrator.

In a preferred embodiment, the plug is provided with at least one through hole, which through hole interacts with at least one locking nose of the circuit carrier. In this way, the assembly of the whole device is easy and the connection is fixed mechanically and positionally accurate.

Other embodiments are set forth in the other dependent claims and the following description of the examples.

An embodiment of a connection unit for a pressure measuring cell is shown in the figures and described in more detail below.

1 is a perspective view of a connecting unit consisting of a plug and a counterpart, disposed on a valve,

2 is a perspective view of a plug,

3 is a sensor electronic component covered by a plug,

4 are parts of the plug,

5 is another view of a carrier of the plug,

6 is a first cross-sectional view of a plug interacting with a pressure measuring cell,

7 is a cross-sectional view of rotating the cross-sectional view of Figure 6 90 °,

8 is a perspective view of a corresponding part for accommodating the plug.

In a vehicle, for example, a valve block (not shown) for control of a brake system comprises a plurality of valves 16. In order to detect the pressure of the fluid controlled by each valve 16, one pressure measuring cell 24 is arranged on each of the valves 16. For this purpose there is provided a connection unit 10 consisting of a counterpart 80 and a plug 40 detachably connected within the counterpart. The correspondence portion 80 forms an electrical contact between the plug 40 and the pressure measuring cell 14. The counterpart 80 is preferably arranged on the coil cover or on the coil base of the valve 16 in the other coil embodiment. Alternatively, it is also possible to be arranged in the winding carrier of the valve 16. Corresponding portion 80 is connected to lead frame 84 via contact tracks 82 for contact with the post-processed electronic components. Alternatively, the connection to the post-processed electronic component can be made by a flexible cable.

2 shows the plug 40 in more detail. The plug 40 is preferably embodied in a cylindrical or cap shape. In the circumferential direction the plug 40 comprises four recesses 55 which are open upwardly but closed towards the inner surface, preferably rectangular, which are adapted to the geometry of the recess 55. It is used for receiving the contact sheets 56. The contact sheets 56 are subsequently slid onto the plug 40 and secured by a hot caulking 58.

The plug 40 is disposed above the circuit carrier 20. The circuit carrier 20, which is embodied in a substantially rectangular shape, is equipped with, for example, an integrated circuit 24 and electronic components 26. The integrated circuit 24 and the electronic components 26 are in electrical contact with the connection points 18 of the measuring bridge 19 of the pressure measuring cell 14 via the electrical connections 27. The contact of each of the connection points 18 and the electrical connections 27 is preferably made by a conductive adhesive. Output signals of the integrated circuit 24 and the electronic components 26 are guided to the four conductive adhesive points 30 through the electrical connections 27. The conductive adhesion points 30 are separated from each other by webs 54 disposed on the top surface of the circuit carrier 20 and each axially disposed. The circuit carrier 20 is, for example, an injection molding part, and is implemented by so-called molded interconnect device (MID) technology. On two sides of the circuit carrier 20 are placed locking noses 42 which are arranged opposite. In order to support the positional connection between the circuit carrier 20 and the plug 40, the locking noses 52 interact with the two through holes 68 of the plug 40. The plug 40 slides onto the circuit carrier 20 until the locking noses 52 engage into the through holes 68.

The inner contour of the plug 40 is adapted to the outer contour of the circuit carrier 20 in which the circuits 24 or electronic components 26 are arranged. Recesses 74 in the plug 40 are provided for receipt of the webs 54 of the circuit carrier 20. In addition, one inner groove 76 is provided in the carrier 50 to accommodate the side of the circuit carrier 20, respectively. The groove 76 forms additional space for the components 26 or the integrated circuit 24 disposed on the circuit carrier 20.

The contact sheet 56 fitted to the recess 55 comprises a 90 ° spring tongue 60 with respect to the substantially rectangular shock contact surface in the upper middle section, which spring tongue includes an embossed portion 62 at its end. do. The geometry of the spring tongue 60, including the embossed portion 62, is designed such that the embossed portion 62 rests on the conductive bond point 30 in the assembled state. The webs 54 of the circuit carrier 20 prevent short circuits during conductive adhesive treatment. The spring tongues 60 comprising the embossed portions 62 of the contact sheets 56 elastically pressurize the circuit carrier 20. The contact sheet 56 between the circuit carrier 20 and the plug 40 is further bonded by a conductive adhesive and hot formed through the bores 65 of the plug 40 on the top surface of the carrier 50. It can be quickly cured using a die. The spring tongues 60 reach the inside of the plug 40 through the upper through holes 70 of the plug 40. The plug 40 also includes two channels 66 extending parallel to the top surface. A chamfer 64 formed at the upper outer edge of the plug 40 is used as a coupling aid when the valve 16 assembles a mounting control device on its manifold block. In assembly, the magnetic coil with a relatively sharp edge in the mounting control first slides over the pressure sensor.

6, the interaction between the plug 40 and the circuit carrier 20 is shown in more detail. The spring tongues 60 reach the contact conductive adhesion point 30 through the upper through hole 70 in the plug 40. Electrical contact between the contact sheet 56 and the conductive adhesive point 30 is formed by a conductive adhesive. The bore 65 is disposed on the conductive bonding point 30. The recess 76 is well formed for the electronic components 26 or the integrated circuit 24. The circuit carrier 20 is mechanically and electrically connected with the pressure measuring cell 14. Thus, the electrical signals of the measuring bridge 19 are transmitted to the respective electronic components 26 or the integrated circuits 24 via the electrical connection 27 and their output signals are transmitted to the conductive adhesive points 30. do. Electrical signals applied to the conductive adhesive points 30 may be tapped through the contact sheets 56.

7 shows how the locking noses 52 of the circuit carrier 20 interact with the through holes 68.

Corresponding portion 80 is shown in more detail in connection with FIG. 8. The counterpart 80 is embodied in the form of a sleeve and the inner contour is embodied in a substantially cylindrical shape. The outer contour of the counterpart 80 has an octagonal structure. Every second outer surface of the octagonal outer surface of the counterpart 80 includes a recess 87 which has two opposing guide slits 88 extending axially to the side. . Recesses 87 and corresponding guide slits 88 are each used to receive one contact track 82. The upper region of the contact track 82 is received by the guide slit 88. In the upper region, contact springs 84 are provided which face towards the inner side, which contact springs interact with the contact sheets 56 of the plug 40. The width of the contact track 82 decreases in the direction of the end of the upper region, bends by 90 ° and projects outward in the radial direction. The end of the radial region projecting out of the contact track 82 bends 90 degrees upwards from the end side. The areas of the contact tracks 82 with the side bent upwards are used as connection points for the coil lead frame 84 which are bent upwards by 90 ° even at certain connection points. The counterpart 80 is closed by the contact surface 83 at the bottom. In the contact surface 83, openings may be provided for fixing the receiving means 80 on the valve 60.

The pressure measuring cell 14 is arranged on the pole core of the valve 16. The valve 16 may be a component of the manifold block, which is also part of the vehicle's brake system. Such devices can be used in particular in anti-lock braking systems or electronic stability systems. The pressure measuring cell 14 includes a measuring bridge 19, which detects the pressure of the fluid in the valve 16 by the expansion of the membrane. The measuring bridge 19 or the pressure measuring cell 14 comprises for example four electrical connection points 18. The electrical signals applied to the connection points 18 are particularly tapped and processed in a compact form and forwarded to the subsequent processing control device. In addition to the high degree of miniaturization, the connection unit 10 must also meet high tolerance requirements (primarily with respect to the length and slope of the valve 16). In addition, frictional corrosion of electrical contacts should be minimized. The incorporation of the pressure measuring cell 14 on the valve 16 allows the separation of further control devices from the pump housing. To minimize the tolerance, the counterpart 80 is disposed on the valve coil, preferably on the coil cover, or on the coil base in other coil embodiments. Alternatively, counterpart 80 may also be disposed on the winding carrier. In addition, the counterpart 80 may be implemented as a cap. That is, the cap can also be implemented as a top closure.

Contact of the contact tracks 82 to the subsequent processing electronics (eg control device) is via the coil lead frame 84. In some cases, the required tolerance compensation may be further given by the curved portion 85 in the coil lead frame 84. Alternatively, connection by flexible cable is also possible.

The inner diameter of the counterpart 80 is set to surround the pressure measuring cell 14 or the measuring bridge 19 and the circuit carrier 20 disposed thereon. Also substantially cylindrical, the inner diameter of the counterpart 80 serves to receive the plug 40. Until the two locking noses 52 of the circuit carrier 20 are locked into the through holes 68 of the plug 40, the device plug 40 with the contact seats 56 assembled into the inner channel 66. Is engaged with the sides of the circuit carrier 20. Within the recesses 74, the webs 54 of the circuit carrier 20 are placed, whereby the webs are each electrically bonded points 30 and electrical contacts 27 by a conductive adhesive, for example a silver conductive adhesive. ) Prevents a short circuit between the conductive adhesive points 30. Spring tongues 60, including the embossed portions 62 of the contact sheet 56, elastically pressurize the circuit carrier 20. Contact surfaces 56 between the circuit carrier 20 and the plug 40 are further bonded by a conductive adhesive and cured using a hot forming die through the bores 65 of the plug 40. Two channels 66 are provided on the top surface so that the plug 40 can be directed and guided for assembly. In this way, the plug 40 can be arranged in a predetermined defined position (assembly position) in the vibrator.

As the plug 40 reaches the interior of the receiving means 80, the plug 40 and the counterpart 80 are connected to each other. In engagement, the contact track 84 may rub on the bottom surface of the contact sheet 56, thereby improving contact, because in some cases the particles present in the area are not wiped out and clamped. In the assembled state, the pressure measuring cell 14 is optionally embossed with the electronic components 26 or the integrated circuit 24, the conductive contact points 30, the spring tongues 60 via the electrical connection 27. 62, contact sheets 56, contact springs 84 of connecting tracks 82, including coil lead frame 84, are optionally in contact with the subsequent processing device.

Claims (17)

As connection unit 10 for pressure measuring cell 14 comprising at least one plug 40, The plug 40 comprises at least one contact sheet 56 substantially axially facing the plug 40, and at least one affected by the pressure measuring cell 14 by the contact sheet. An electrical signal can be tapped, and the contact sheet 56 is formed to allow at least one axial tolerance compensation by means of the contact means 86 of the slidable insert 80. The internal space is at least partly used for the reception of the circuit carrier 20 and at least one circuit 24 or at least one electron for processing at least one output signal of the pressure measuring cell 14 on the circuit carrier. Connection unit for the pressure measuring cell in which the part 26 is arranged. The method of claim 1, The plug 40 is formed into a sleeve and the contact sheet 56 is disposed on an outer surface of the plug 40, preferably on a cylindrical outer surface of the plug 40. Connection unit for the cell. The method according to claim 1 or 2, The plug (40) comprises at least one recess (55) on its outer surface, wherein the contact sheet (56) is at least partially received in the recess. The method according to any one of claims 1 to 3, And the contact sheet (56) is connected to the plug (40) by a hot caulking portion (58). The method according to any one of claims 1 to 4, Connection unit for pressure measuring cell, characterized in that the contact sheet (56) comprises at least one spring tongue (60). The method according to any one of claims 1 to 5, And the plug (40) comprises at least one through hole (70), through which the spring tongue (60) is guided into the plug (40). The method according to any one of claims 1 to 6, Connection unit for a pressure measuring cell, characterized in that the upper surface of the plug (40) is provided with a chamfer (64) and / or at least one channel (66). The method according to any one of claims 1 to 7, At least one internal channel (66) is provided inside the plug (40) to receive the circuit carrier (20). The method according to any one of claims 1 to 8, At least one through hole (68) is provided in the plug (40), the through hole interacting with at least one locking nose (52) of the circuit carrier (20). The method according to any one of claims 1 to 9, At least one recess (74) is provided in the plug (40) to receive at least one web (54) of the circuit carrier (20). The method according to any one of claims 1 to 10, At least one groove 76 is provided inside the plug 40, and the groove receives at least one circuit 24 and / or electronic component 26 disposed on the circuit carrier 20. Connection unit for a pressure measuring cell, characterized in that the role of. The method according to any one of claims 1 to 11, At least one recess or through hole (70) is provided on the outer surface of the plug (40) for fixing the contact sheet (56). The method according to any one of claims 1 to 12, At least one through-hole or bore (65) is arranged on the upper surface of the plug (40) above the contact spring. The method according to any one of claims 1 to 13, At least one contact means 86 is provided in the counterpart 80, the contact means 86 being capable of conductive contact with the contact sheet 56 of the plug 40. . The method according to any one of claims 1 to 14, The contact means of said counterpart (80) comprises at least one contact spring (84). The method according to any one of claims 1 to 15, The contact means of said counterpart (80) is formed as a contact track (82), said contact track being at least partially directed in a radial direction. The method according to any one of claims 1 to 16, And said counterpart (80) is substantially sleeve-shaped and said counterpart (80) is at least partially surrounding said plug (40).

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