DE3133455C2 - Method and device for automatic frequency adjustment of mechanical filter resonators by sandblasting - Google Patents

Abstract

Method for the automatic frequency adjustment of mechanical filter resonators by sandblasting, in which the resonance frequency of each filter resonator is first measured and the sandblasting time is controlled as a function of these measured values. The material is removed from the circumference of the filter resonator while it rotates. Another adjustment option is provided on the end face of the filter resonator.

Description

characterized by

f) that the balancing device (12) contains an axial holder for the filter resonator, the leaves one of its end faces and its lateral surfaces largely free,

g) that a drive is provided which the holder with the filter resonator around its longitudinal axis rotates during the adjustment,

h) that at least one sandblasting nozzle (29,30) on the lateral surface of a recess of the filter resonator is directed and

i) that an additional sandblasting nozzle (31) is directed at the free end face of the filter resonator is.

2. Apparatus according to claim 1, characterized in that a collet chuck as the axial holder (22) is provided with a stop (23).

3. Apparatus according to claim 1 or 2, characterized in that the sandblasting nozzles (29,30,31) are provided with a swivel device.

4. Apparatus according to claim 3, characterized in that the rotary magnets (34, 35) as the drive Swivel device are provided.

direction, via which the measured filter resonators are optionally fed to a controlled balancing device and with
e) a control connected to the measuring device for the sorting device and the balancing device.

Device for automatic frequency adjustment of mechanical filter resonators by sandblasting with

a) a shrinkage conveyor, the unbalanced and matched filter resonators are supplied with

k \ one Entn * i2 ^rf neiisisrvorricht «"' ^Y and a ο »γ» γϊ subsequent isolation, with

c) a magnetizing device for the defined pre-magnetization of the filter resonators and a Measuring device for measuring the resonance frequency of the filter resonators, and with

d) a sorting unit following the measuring device

From DE-PS 24 60 258 a method and a device for automatic frequency adjustment is mechanical Resonators known from sandblasting. The isolated filter resonators are via a Rotary indexing table of a sandblasting adjustment device 11 There the filter resonator is leveled by step-by-step sandblasting of its end face. The resonance frequency of the filter resonator is measured between the individual sandblasting processes.

From US-PS 28 76 599 a balancing device for mechanical filters is known in which a resonator as part of this filter is clamped in brackets on both sides and an adjustment by material removal Excitations for an automatic frequency adjustment are made on the outer surface of the rotating resonator cannot be found in this reference. For filter resonators with, for example, two grooves, so-called dumbbell vibrators, the adjustment must be made on the lateral surface (circumference) of the punctures and, if necessary take place on the face.

The device described in the introduction is not suitable for this purpose since it is only used for machining the end face the resonators can be used.

Up to now, the dumbbell vibrators have been calibrated manually with whetstones.

The object of the invention is to reduce the adjustment times for filter resonators through automation. Based on the method described in the introduction, this object is achieved by

f) that the adjustment device contains an axial holder for the filter resonator, one of its Leaves end faces and its outer surfaces largely free,

g) that a drive is provided which the holder with the filter resonator around its longitudinal axis during the adjustment rotates,

h) that at least one sandblasting nozzle is directed onto the lateral surface of a recess of the filter resonator is and

i) that an additional sandblasting nozzle on the free Face of the filter resonator is directed.

The rotating filter resonator causes a

Even material removal on the surface of the grooves. This leads to short adjustment times. the The geometry of the filter resonator is retained. This has a positive effect on the filter quality.

During the adjustment process, both grooves can be machined at the same time. With a small frequency offset only one sandblasting nozzle works.

It is also advantageous that a work material removal is also carried out is provided on at least one end face of the resonator.

before the punctures lead to a lowering of the resonance frequency leads, removal of material from one end face causes an increase in the resonance frequency. at With this method, filter resonators with positive and negative frequency tolerances can be adjusted will.

It is advisable that the sandblast is only directed onto the filter resonators after a short pre-blasting time will.

A pre-blasting time is useful in order to ensure an even To achieve sandblasting and thus an even material removal during the adjustment time. Only after the pre-blasting time is the sandblast directed onto the filter resonators and compensated for them. This Adjustment is so precise that generally only a few adjustments are required. Also the possibility of correction by irradiating the end face of the fiI-terresonatoviin allows the resonance frequency of the filter resonators to be adjusted with a single attempt want to achieve.

Further advantages of the invention and an advantageous device and its design are in the rest Subclaims indicated. An exemplary embodiment of the invention is illustrated by means of FIGS. 1 to 3 explained in more detail. It shows

F i g. 1 a device for automatic frequency adjustment,

F i g. 2 a matching device and

F i g. 3 is a side view of the balancing device.

In Fig. 1 is the basic circuit diagram of a device shown for automatic frequency adjustment It contains a vibratory conveyor 1 in which the filter resonators be filled in randomly. The output of the vibratory conveyor is connected to an input pipe 2 Demagnetizer 4 connected. The filter resonators, possibly with Compressed air aid, transported The output of the demagnetization device 4 and the feed of the separator 6 is monitored by light barriers 3 or 5. These light barriers control the vibratory conveyor 1. The filter resonators pass from the demagnetizing device to the separator 6. This is the magnetizing device 7 upstream Here the filter resonators receive a defined current pulse certain bias. After the premagnetization, the filter resonators reach the measuring device 8. Here your resonance frequency is measured in a defined way.

For this purpose, the measuring device receives an excitation coil and a measuring coil. The measurement result is communicated to a controller 13. The output of the measuring device 8 is connected to a sorting device 9. Depending on the measurement result, the filter resonators pass via a switch 91 either to the balancing device 12 or to a chute 92. The filter resonators with the desired resonance frequency are stored in a container 93. The other resonators are z. B. stored as non-oscillators in the container 96, while the filter resonators, which are outside a predetermined tolerance range, are stored in the container 94 or 95. Normally a filter resonator has to be adjusted. It arrives at a transfer device 11 via the switch 91. A further light barrier 10 ensures that only a single filter resonator reaches the transfer device. The transfer device pushes a resonator to be adjusted into the adjustment device and i »nlfi» rnl Hpn ahacoVirhpnpn Filtprre «nnatnr iinH le.trt difi-

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sen in a container 97 from. Then the adjustment device is again opposite the transfer device sealed. The balanced resonators are in turn fed into the vibratory conveyor 1 in order to to check their resonance frequency in the measuring device. In general, they have to be cleaned beforehand will.

In Fig. 2 is the alignment device in plan view The balancing device contains a sand chamber 21. In it there is a collet 22 for receiving a filter resonator is provided. A stop 23 in the collet 22 ensures the correct adjustment of the Filter resonator. It is incorporated directly into the collet here. The collet is located in a rotating one Shaft 24, which is fastened in a bearing 27. The rotating shaft 24 is via a pulley 28 and a V-belt 25 driven by a motor 26. Two sandblasting nozzles 29 and 30 are direct aligned with the punctures of the filter resonator 32. A third sandblasting nozzle 31 aims at the end face of the filter resonator. The sandblasting nozzles are each attached to a shaft 37, 38, each with a clamp 33, which makes it possible to set the distance between the nozzles and the dumbbell vibrator and the angle of the beam independently of one another to adjust. The sandblasting nozzles 30 and 31 are mounted on the same shaft 38. All sandblasting nozzles 29, 30 and 31 are pivotable. The pivoting process is controlled by a rotary magnet 34 and 35 The rotary magnets are of course attached outside of the adjustment chamber. Open that and the collet chuck 22 is closed by means of a pneumatic cylinder 36.

The filter resonator 32 to be newly adjusted is entered from the transfer device through a window 45 into the Collet 22 inserted. The balanced filter resonator is collected in a container and in the Container 97 (Fig. 1) deposited. The adjustment chamber 2i is then closed.

During the adjustment process, the sand must of course be continuously vacuumed. This is done through an opening 39. Initially, the sandblasting nozzles 29 and 30 are not directed at the filter resonator. All sandblasting nozzles are controlled by the controller 13. First, wait a short time before the sandblast becomes even. Then it is pivoted onto the filter resonator 32. The material removal is determined by the duration of the sandblasting process b . If the resonance frequency of the filter resonator is too low, it is not the sandblasting nozzles 29 and 30, but the sandblasting nozzle 31 on the end face of the filter resonator that are put into operation. After the calibration process, the collet is opened by the pneumatic cylinder 36. The adjusted filter resonator is removed by the transfer device 11 and a new filter resonator to be adjusted is clamped in the collet 22.

In Fig. 3 shows the side view of the sandblasting chamber 21 again in section. The sandblasting chamber is closed by a ceiling 40 with ventilation slots 41. The Sand sucked through an opening 39.

For this purpose 3 sheets of drawings

Claims (1)

Patent claims: 1. Device for the automatic frequency adjustment of mechanical filter resonators Sandblasting with a) a vibratory conveyor (1), the unbalanced and matched filter resonators are supplied with b) a demagnetizing device (4) and an adjoining separator (6) with c) a magnetizing device (7) for the defined Premagnetization of the filter resonators and a measuring device (8) for measuring the Resonance frequency of the filter resonators, with d) a sorting device following the measuring device (8) (9), via which the measured filter resonators are optionally fed to a controlled balancing device (12), and with e) a control (13) connected to the measuring device (8) for the sorting device (9) and the adjustment device (12),