DE2654270A1 - Bourdon tube pressure gauge - has toothed segment operating lever arm in same plane as Bourdon tube end tip - Google Patents

Abstract

The pressure gauge has a support with a Bourdon tube fastened by one end to the support and carrying a tip at its other end. A pointer mechanism includes a toothed segment and a pivoted lever. A pull-rod rigid at least in the longitudinal direction, with constant length is pivoted on the segment lever arm and on the Bourdon tube tip. Round holes are made in the lever arm and in the tip for the pull-rod pins. The segment lever arm (31) is a plate-shaped element in the area between the segment pin (29) and the pivot hole. The tip (16) comprises a plate-shaped element whose largest dimensions lie in a plane common with the segment lever arm (31).

Description

Bourdon tube pressure gauge

The invention relates to a Bourdon tube pressure gauge with a measuring element carrier, a Bourdon tube firmly connected at one end to the measuring element support, at which the other end an end piece is attached, a pointer mechanism, which has a tooth segment, which includes a segment lever pivotably mounted on a segment axis, and an at least in the longitudinal direction rigid, length-invariable tie rod, which articulated at bearings both with the one lying on one side of the segment axis Segment lever arm and the end piece is connected, with circular at the bearing points Holes are formed in the segment lever arm and in the end piece. With a conventional The segment lever arm has a manometer of this type hook-shaped Section at the end of which there is the hole at which one end of the pull rod is hinged.

This hole defines the so-called articulation point. Furthermore is also the end piece is hook-shaped, with the hole again at the hook end is located on which the other end of the pull rod is hinged. This hole defines the so-called end point.

The hooks are used by bending or squeezing the respective Hook the position of the articulation point with respect to the segment axis or the end point to be able to change with respect to the end of the Bourdon tube and the pivot angle between Segment axis, articulation point and end point. These change options will be required in order to be able to adjust the measuring system of the manometer.

The flexible hooks on the segment lever and end piece make production more expensive of the pressure gauge. Other disadvantages of these hooks are that they limit the choice of materials restrict, since practically only hooks made of metal come into question, and that when attaching tight manufacturing tolerances of the end piece on the Bourdon tube must be adhered to, so that the correction of the position of the end point does not require too much effort.

Pressure gauges are already known that have at least one hook through an elongated hole in the segment lever arm or

End piece is replaced so that the end point or articulation point when adjusting can be moved. It is also known to adjust the length of the pull rod to be changeable in order to influence the articulation angle by changing the length. However, these options are no less complicated and expensive than that hook described above.

The invention is based on the object of a Bourdon tube pressure gauge to train the specified type so that production and adjustment of the pressure gauge less Cause costs without the accuracy of the pressure gauge being displayed.

This object is achieved according to the invention in that the segment lever arm a solid, plate-shaped element in the area between the segment axis and the bearing hole and that the end piece comprises a plate-shaped element, the largest dimensions of which lie in a plane common to the segment lever arm. "Massive" means that the segment lever arm does not have any incisions, recesses or in the area mentioned has the like that interrupt the straight line between the segment axis and the articulation point.

The manometer according to the invention is thus characterized by a "New kinematics" i.e. a new type of combination of end piece and tie rod and segment lever arm, which connect the end of the spring with the pointer mechanism. The special this new kinematics lies in the plate-shaped or flat design of End piece and segment lever arm and in the rigid, i.e. length-invariable design of all three kinematic elements: end piece, pull rod and segment lever arm.

The waiver of hooks, elongated holes and other options for changing the distance between segment axis and articulation point, articulation point and end point as well as end point and The spring end simplifies the manufacture of the kinematic elements. This waiver will possible through the plate-shaped or flat design of the segment lever arm and End piece1 because there is enough material or Sufficiently large areas are available around the holes for the end point and articulation point at the finished from measuring element carrier, Bourdon tube and pointer mechanism mounted measuring system according to this To be able to produce assembly, the position of the holes from the properties of the respective measuring system, in particular the spring deflection under nominal pressure, so determined that the span, i.e. the pointer deflection at nominal pressure, and the linearity of the display lie within the permissible tolerance fields. The inventive Manometer is thus adjusted, despite the kinematics of a simple construction, without a conventional adjustment by subsequently changing the position of the articulation point and end point or the tie rod length is required, so that on the one hand the production of Kinematic elements is less expensive and, on the other hand, the adjustment work is omitted.

The end piece is preferably rigid in the common plane connected to the end of the Bourdon tube. Particularly easy production of the segment lever arm results from the fact that the segment lever arm laterally of two straight edges is limited.

In an advantageous embodiment of the invention, a convex projection be provided on the end piece in the direction parallel to the longitudinal axis of the measuring element support pointing away from the end of the Bourdon tube. The protrusion makes it easier to measure the deflection of the spring end under nominal pressure to determine the locations of the end point and the articulation point, since the projection offers a suitable facility for a probe, for example.

The new kinematics can also be designed advantageously, that the pull rod is a plastic part, which has two approaches, which are snapped into the holes in the end piece and in the segment lever arm.

A particular advantage of the new kinematics is that they it enables a non-changeable stop in the pointer mechanism or on the measuring element support to be provided for a swiveling part of the pointer mechanism. This stop replaces, for example a stop pin on the dial of the pressure gauge, which is the case with conventional pressure gauges increases the manufacturing costs and brings with it the risk that he other dials damaged in storage. For example, according to the invention, a stop can be used as a stop Stud bolts of the pointer are used on which the toothed segment or the segment lever in Zero position is applied. This is made possible by the training according to the invention the kinematics that make it possible to make the holes for the pivot point and end point, while, for example, the segment lever rests on the stud bolt and the Bourdon tube is under the pressure that is assigned to the zero point position of the pointer. at With conventional pressure gauges, there is no changeable stop in the pointer mechanism possible, since the position of its movable parts can be changed for adjustment got to.

An embodiment of the invention is shown in the drawing and is explained in more detail below. They show: FIG. 1 a plan view of a Measuring system of an embodiment of a manometer according to the invention; Fig. 2 a partial representation of a modification of the measuring system according to FIG. 1; and Fig. 3 a pointer mechanism with a fixed stop.

Fig. 1 shows an embodiment of a measuring system 8 of an inventive Bourdon tube pressure gauge. The case, dial and pointer of the are not shown Manometer.

The measuring system includes a measuring element carrier 12 on which a Bourdon tube 10 is soldered at one end, and a pointer mechanism 20, which is a pointer shaft pinion 22 and a toothed segment 24 which is in engagement with the pointer shaft pinion. The toothed segment 24 has a segment lever 26 which is mounted on a segment axis 29 is pivotably mounted. The one on the side facing away from the pointer shaft pinion 22 The segment of the segment lever lying on the segment axis forms the segment lever arm 31.

At the free end of the Bourdon tube 10, an end piece 16 is for example attached by soldering. In the end piece there is a circular one which can only be seen in FIG. 2 Hole 18 that defines the end point E. Furthermore, there is 31 in the segment lever arm a circular hole 28 (see FIG. 3) which defines the pivot point A. In these Holes are attached rivets on which a tie rod 30 is articulated is that thus the deflection of the end of the Bourdon tube under pressure to the pointer mechanism 20 transmits and together with the end piece 16 and the segment lever 26, the kinematics of the pressure gauge. It goes without saying that the mounting of the tie rod is also on other way than by shoulder riveting. For example, the pull rod be a plastic part with two lugs that fit into the holes in the segment lever arm and end piece are snapped into place.

As can be seen from FIG. 1, the kinematics of the pressure gauge is stiff. Neither the segment lever arm 31, nor the pull rod 30, nor the end piece 16 leave one Change in length between segment axis 29 and pivot point A. or articulation point A and end point E or end point E and spring end closed.

The segment lever arm 31 is a plate-shaped, flat element that is bounded laterally by straight edges and in the area of the straight segment axis pivot point has no incisions or the like and no hook-shaped design. the in the plan view according to FIG. 1 visible area of the segment lever arm is so large, that the hole 28 for the pivot point A within sufficiently wide limits to more suitable Place could be manufactured.

The end piece 16 is also a plate-shaped, flat element that lies in the same plane as the segment lever arm 31. The end piece 16 has in this Like the segment lever arm, cover such a large area that the hole for the end point E could be manufactured at a suitable location within sufficiently wide limits.

At the end piece 16 there is a convex projection 17, -der in to Measuring member support longitudinal axis M-M pointing away from the end of the Bourdon tube 10 in a parallel direction and its (in Fig. 1) located furthest point below the spring end is. The projection can also have the shape shown in FIG. The lead serves to place a measuring sensor, by means of which the spring deflection is measured.

In Fig. 3, the pointer mechanism 20 is shown schematically in the state which it has at the zero point position and during the production of the hole 28. Included a stud bolt 27 of the pointer mechanism serves as a stop against which the segment lever 26 is present. This stop can also be dated Measuring element carrier 12, for example the edge of which, as shown in FIG. 1, are formed.

Patent claims: Our reference: AS-51 REFERENCE CHARACTERISTICS LIST (LISTE OF REFERENCE NUMERALS) 1 2 2 4 4 5 5 6 6 7 7 8 8 9 10 Bourdon tube 10 11 Messqliedträqer 11 12 12 13 13 14 14 15 15 16 end piece 16 17 projection 17 18 hole ~ 18 19 19 20 Zeicrerwerk 20 21 21 22 Pointer shaft pinion 22 23 23 24 Tooth segment 24 25 25 g Seqment lever 26 27 Stud ~ 27 28 Hole 28 29 Segment axle 29 30 Pull rod 30 31 Segment lever arm E end point; A pivot point

Claims (8)

Claims 1. Bourdon tube manometer with a measuring element carrier, a Bourdon tube firmly connected at one end to the measuring element support, at which the other end an end piece is attached, a pointer mechanism, which has a tooth segment, which includes a segment lever pivotably mounted on a segment axis, and an at least in the longitudinal direction rigid, length-invariable tie rod, which articulated at bearings both with the one lying on one side of the segment axis Segment lever arm as well as the end piece is connected, with put to the bearing circular holes are formed in the segment lever arm and in the end piece, thereby q e k e n n n e i c h n e t that the segment lever arm (31) is in the area between Segment axis (29) and bearing hole (28) is a solid, plate-shaped element and that the end piece (16) comprises a plate-shaped element, the largest dimensions of which lie in a plane common to the segment lever arm. 2. Bourdon tube pressure gauge according to claim 1, characterized in that g e k e n n -z e i c h n e t that the end piece (16) is rigid in the common plane with the end the Bourdon tube (10) is connected. 3. Bourdon tube pressure gauge according to claim 1 or 2, characterized in that g e k en n z e i c h n e t that the segment lever arm (31) laterally of two straight edges is limited. 4. Bourdon tube pressure gauge according to one of claims 1 to 3, g e k e n n z e i c h n e t by a convex projection (17) on the end piece (16), which in to Measuring element carrier longitudinal axis (M-M) parallel direction from the end of the Bourdon tube (10) points away. 5. Bourdon tube pressure gauge according to claim 4, characterized in that g e k e n n -z e i c h n e t that the point of the projection furthest from the end of the Bourdon tube (10) (17) on a parallel running through the end to the longitudinal axis of the measuring element carrier (M-M) lies. 5. Bourdon tube pressure gauge according to one of claims 1 to 4, characterized in that g It is not noted that the pull rod (30) is a plastic part that has two Has lugs into the holes (18, 28) in the end piece (16) and in the segment lever arm (31) are snapped into place. 6. Bourdon tube pressure gauge according to one of claims 1 to 5, g e k e n n z e i c h n e t by a non-changeable zero stop (27) in the pointer mechanism (20) or on the measuring element support (12) for a pivotable part (24) of the pointer mechanism. 7. Bourdon tube pressure gauge according to claim 6, characterized in that g e k e n n -z e i c h n e t that the pivotable part is the toothed segment (24). 8. Bourdon tube pressure gauge according to claim 7, characterized in that g e k e n n -z e i c h n e t that a stud bolt (27) of the pointer mechanism (20) forms the zero stop.