DE4125101C1 - Anemometer with rest position restoring insert in bearing bolt - holds cup vanes in radial working position by returning plate under spring pressure - Google Patents

Abstract

An anemometer has a housing contg. a rotatable axle with its upper end protruding from the housing and carrying a bearing part with radial cup vanes. The vanes can be moved from the radial deployed position into an upward folded rest position on bearing bolts in the bearing part. Restoring fittings on the bearing bolts (22) work in conjunction with a restoring plate (17) acted upon by a helical spring (18) so that the vanes are held in their radial position. An adjustable casing (30) on the housing brings the vanes (20) into the rest position and at least partly covers them. ADVANTAGE - Vanes are easily moved into rest position and are partly protected in it.

Description

The invention relates to an anemometer with a housing, in an axis is rotatably mounted, the end of which is at the top Housing protrudes and carries a bearing part on which is approximately radial extending shell wings are attached, which means an adjustment part from the radial working position into a Folded up rest position repellent from the housing are, the shell wing facing the bearing part in radial aligned and rotatably mounted bearing bolts in the bearing part leak.

An anemometer of this type is known from DE 28 24 771 C1. This known anemometer is in the rest position the shell wings unprotected in the extension of the axis and can easily be damaged because of weight reasons are only made with a small wall thickness. The adjustment the shell wing takes place over the bearing part, which thereby the axis is adjusted. The parts are in the bearing part housed in the adjustment of the shell wing swivel and secure in the set positions. Therefore the bearing part is very complicated and prone to failure.

It is an object of the invention to provide an anemometer at the outset to create the kind mentioned, in which the Shell wings are housed protected and the bearing part the rest position of the shell wings in a simple manner Working position.  

This object is achieved according to the invention in that the bearing pins reset lugs are formed, which in Bearing part with a compression spring Reset plates work together so that the shell wings are held in the radial working position, and that on the housing is a sleeve with which the Shell wing can be brought into the rest position and at least are partially coverable.

The sleeve not only serves as an actuator for the Shell wing, but also as a receptacle for protection the shell wing in the rest position. The compression spring in the Bearing part ensures in connection with the reset plate and Reset lugs on the bearing bolts of the shell wing for the automatic adjustment of the shell wings in the Working position when the sleeve is back on the housing is pushed back.

According to one embodiment, it is provided that the bearing part is designed as a pot in the area of the open side Bearing slots for receiving the bearing bolts of the shell wing has, and that the pot-like bearing part by means of a Bearing plate is closed, the radially directed bearing grooves for the bearing bolts of the shell wing and Reset plate and the compression spring over the rotatably mounted Bearing pin with the reset lugs. That is also ensured that the compression spring over the reset plate acts symmetrically on all reset approaches.

The connection of the bearing part with the axis is after one Design solved so that the axis in a threaded part  runs out, on which the bearing part by means of a screw nut, the compression spring designed as a coil spring, the Reset plate and the bearing plate are attached, the Bearing plate facing the housing.

So that the radially rotatable shell wings in the bearing part can be folded up unhindered, sees an embodiment that the shell wings have slightly bent arms, blunt on the sides facing the bearing part Form an angle. So that the shell wings after pushing back the sleeve on the housing safely into the rest position by itself pivot back, it is provided that the pivot angle of the Bearing pin is less than 90 °. The reset approaches are preferably designed as a wing in the working position the shell wing is perpendicular to the axis.

Is provided according to a further embodiment that the Housing in the end area facing the bearing part Display display and an electrical switch that carries by means of an actuating tongue molded onto the sleeve can be actuated, then the anemometer can simply be turned on and off switched off and the measured value slightly in the working position be read.

To get a compact anemometer, the design is made so that the sleeve is designed as a housing sleeve which is in the inner cross section on the outer cross section of the Housing is adapted, and that the axial length of the housing sleeve corresponds approximately to the axial length of the housing.

So that the anemometer can be set up in the working position can, an embodiment provides that the bearing part with  face of the sleeve facing away from the shell wings in one Level runs out perpendicular to the direction of adjustment of the sleeve is aligned and that the lower end face of the housing is uneven, e.g. B. at least two at an obtuse angle to each other has standing surfaces. Is the sleeve moved and the Put the anemometer in the rest position, then it cannot more with vertical axis.

The development of the anemometer according to the invention provides that in the housing the speed of the axis Measuring device is housed, the display controls and a corresponding to the wind speed Indicates signal, and that the measuring device comprises electrical generator, the measuring device of a battery housed in the housing, an accumulator or the like. is fed.

The handling of the anemometer is facilitated by the fact that the cross section of the housing and the sleeve substantially is triangular with rounded corners and that the sleeve is slightly bulged in the middle area.

The invention is illustrated by means of one in the drawings Embodiment explained in more detail. It shows:

Fig. 1 is a vertical section through part of the bearing part with the tray in the working position wing of an anemometer according to the invention,

Fig. 2 shows a cross section through the bearing part via the rotatably mounted and in the working position shell wings,

Fig. 3 to Fig. 1 corresponding partial section with folded-up into the inoperative position shell wings,

Fig. 4 is a side view of the anemometer according to the invention in the working position,

Fig. 5 in side view of the anemometer according to the invention in an intermediate position when moving the housing sleeve displaceable on the housing and

Fig. 6 in side view of the anemometer according to the invention in the rest position with the shell wings folded up and covered.

Referring to Figs. 1 to 3 the mounting of the shell wings 20 are illustrated in detail by the anemometer. On the upper side of a housing 10 , an axis 12 projects, which ends with a threaded part 15 . A pot-shaped bearing part 13 is pushed onto this axis, which has a corresponding hole in the bottom for a screw nut 16 which can be screwed onto the threaded part 15 of the axis 12 . This bearing part 13 faces the housing 10 with the open side and is closed with a bearing plate 14 . The bearing part 13 has bearing slots 14 in the region of the open side, in which bearing bolts 22 are rotatably mounted, which are molded onto the ends of the shell wings 20 . The bearing plate 14 has a central bore for the axis 12 and on the inside radially directed bearing grooves 26 in which the bearing bolts 22 of the shell wing 20 are rotatably mounted. At the ends of the bearing bolts 22 , wing-like reset lugs 23 are formed, which, as shown in FIG. 2, are perpendicular to the axis 12 in the working position of the shell wings 20 . In order that the shell wings 20 are held in the working position, a rest plate 17 loaded with a compression spring 18 rests on the bearing pin 22 with the restoring lugs 23 . The compression spring 18 is designed as a helical spring that can be pushed onto the threaded part 15 of the axis 12 and the reset plate 17 is provided with a central bore. The rear positioning plate 17 can also be designed as a guide for the helical spring, so that the restoring force is applied evenly to all canceling lugs of the bearing part 13 and the bearing grooves 26 of the bearing plate 14 rotatably mounted bearing pin in the bearing slots 24 22 of the plate wing 20th

As shown in FIG. 1, in the working position, the housing 10 protrudes from the top of a sleeve 30 designed as a housing sleeve. A display 11 is installed in the exposed area of the housing 10 in order to display the measured value, that is to say the wind speed detected by the rotational movement of the shell vanes 20 caused by the wind. The measuring device required for this, which can also be designed as a generator, is accommodated in the housing 10 and controls the display 11 . In the upper area of the sleeve 30 , an actuating tongue 31 is recessed, with which an electrical switch located behind it in the housing 10 can be actuated. The anemometer can therefore only be switched on and off in the working position. The anemometer can be supplied with power via a battery, an accumulator or the like, which is accommodated in the housing 10 .

As FIG. 2 shows, the cross section of the housing 10 is essentially triangular with rounded corners. The sleeve 30 , which is designed as a housing sleeve and is displaceable on the housing 10, has an inner cross section which is adapted to the outer cross section of the housing 10 . If, as indicated by dashed lines in FIG. 3, the sleeve 30 is pushed up over the bearing part 13 , then the shell wings 20 are folded up over their arms, since these come into contact with the upper end face of the sleeve 30 and remain until they are shown in FIG. 3 Have reached rest position. The shape of the arms between the bearing pin 22 and the shells 21 ensures that the shell wings 20 are pivoted continuously. The sides facing the bearing part 13 are slightly kinked and form an obtuse angle so that they do not touch the bearing part 13 and come together with their shells 21 in the rest position in a small space as possible. In the rest position of the shell wing 20 , which is maintained by the upwardly displaced sleeve 30 , the compression spring 18 is tensioned. The pivoting movement of the shell wing 20 is less than 90 °, so that the reset plate 17 can exert a corresponding reset torque on the reset lugs 23 when the sleeve 30 is pushed back onto the housing 10 . The shell wings 20 are automatically returned to their working position according to FIGS. 1 and 2.

Fig. 4 shows the anemometer according to the invention in the working position in which the lower end face of the sleeve 30 defines the footprint. The sleeve 30 is slightly bulged in the middle, which makes handling easier. Following the upper area of the sleeve 30 , the housing 10 with the display 11 protrudes. If the sleeve 30 is pushed up, the upper face takes the arms of the shell wings 20 with it, the shell wings 20 being rotated around the bearing bolts 22 and being folded up, as can be seen in FIG. 5.

If the sleeve 30 is brought into the upper position, the shell wings 20 assume the rest position shown in FIG. 6, in which they are covered except for the shells 21 and are therefore protected. The housing 10 , which has approximately the same axial length as the sleeve 30 , protrudes on the lower end face of the sleeve 30 .

Since the lower end face 25 of the housing 10 is uneven, the anemometer cannot be set up vertically in the rest position. It can only be placed horizontally, the cross section of the sleeve 30 ensuring that the anemometer cannot roll.

Claims (13)

1. Anemometer with a housing in which an axis is rotatably mounted, the end of which protrudes from the top of the housing and carries a bearing part to which are attached approximately radially extending shell vanes, which by means of an adjustment part from the radial working position to one facing away from the housing , folded up rest position can be brought, the shell wings facing the bearing part running out in radially aligned and rotatably mounted bearing bolts in the bearing part, characterized in that
that reset lugs ( 23 ) are integrally formed on the bearing bolts ( 22 ), which cooperate in the bearing part ( 13 ) with a return plate ( 17 ) under the action of a compression spring ( 18 ) so that the shell wings ( 20 ) are held in the radial working position , and
that on the housing ( 10 ) a sleeve ( 30 ) is adjustable, with which the shell wings ( 20 ) can be brought into the rest position and at least partially covered. 2. Anemometer according to claim 1, characterized in
that the bearing part ( 13 ) is designed as a pot which has bearing slots ( 24 ) in the region of the open side for receiving the bearing bolts ( 22 ) of the shell wings ( 20 ), and
that the pot-like bearing part ( 13 ) is closed by means of a bearing plate ( 14 ), which has radially directed bearing grooves ( 26 ) for the bearing bolts ( 22 ) of the shell wings ( 20 ) and the reset plates ( 17 ) and the compression spring ( 18 ) can be rotated about them mounted bearing pin ( 22 ) with the reset lugs ( 23 ). 3. Anemometer according to claim 1 or 2, characterized in that the axis ( 12 ) ends in a threaded part ( 15 ) on which by means of a screw nut ( 16 ) the bearing part ( 13 ), the compression spring ( 18 ) designed as a coil spring, the Reset plate ( 17 ) and the bearing plate ( 14 ) are fastened, the bearing plate ( 14 ) facing the housing ( 10 ). 4. Anemometer according to one of claims 1 to 3, characterized in
that the shell wings ( 20 ) have slightly bent arms which form an obtuse angle on the sides facing the bearing part ( 13 ) and
that the pivot angle of the bearing pin ( 22 ) is less than 90 °. 5. Anemometer according to one of claims 1 to 4, characterized in that the housing ( 10 ) in the end portion facing the bearing part ( 13 ) carries a display ( 11 ) and an electrical switch which is formed by means of a on the sleeve ( 30 ) Actuating tongue ( 31 ) can be actuated. 6. Anemometer according to one of claims 1 to 5, characterized in
that the sleeve ( 30 ) is designed as a housing sleeve which is adapted in the inner cross section to the outer cross section of the housing ( 10 ), and
that the axial length of the housing sleeve corresponds approximately to the axial length of the housing ( 10 ). 7. Anemometer according to one of claims 1 to 6, characterized in that
that the bearing part ( 13 ) with the shell wings ( 20 ) facing the end of the sleeve ( 30 ) ends in a plane which is aligned perpendicular to the direction of adjustment of the sleeve ( 30 ) and
that the lower end face ( 25 ) of the housing ( 10 ) is uneven, for. B. has at least two obtuse angles to each other. 8. Anemometer according to one of claims 1 to 7, characterized in that in the housing ( 10 ) accommodates a measuring device which detects the rotational speed of the axis ( 12 ), which controls the display ( 11 ) and emits a display signal corresponding to the wind speed. 9. Anemometer according to claim 8, characterized, that the measuring device comprises an electric generator.   10. Anemometer according to claim 8 or 9, characterized in that the measuring device is fed by a battery, an accumulator or the like housed in the housing ( 10 ). 11. Anemometer according to one of claims 1 to 10, characterized in that the cross section of the housing ( 10 ) and the sleeve ( 30 ) is substantially triangular with rounded corners. 12. Anemometer according to one of claims 1 to 11, characterized in that the sleeve ( 30 ) is somewhat bulged in the central region. 13. Anemometer according to one of claims 1 to 12, characterized in that the reset lugs ( 23 ) are designed as wings which are perpendicular to the axis ( 12 ) in the working position of the shell wing ( 20 ).