DE102012024482A1 - Method for calibrating tester used for measuring microwave components, involves recording changes in position of probes at each contact position by related to fixed reference calibration measurement on reflectance standard - Google Patents

Abstract

The method involves making contact of an automated testing apparatus (100) to a test device at defined contact positions through the probes (10,30). The changes in position of the probes are recorded at each contact position by a related to a fixed reference calibration measurement on a reflectance standard, so that acquired disturbances are compensated by a de-embedding procedure. The laser distance measurements are performed using light barrier (25), so that exact alignment of the test probes is determined.

Description

The invention relates to an injection molding machine, comprising a machine bed on which a fixed platen is arranged, wherein on the machine bed, a displaceable platen is further arranged, which is displaceable relative to the first platen in a closing direction, wherein on one of the platen with a number of spars with a longitudinal axis are fastened, which are lockable for applying a tool closing force relative to the other platen by means of locking means and wherein between the spars and one of the platens piston-cylinder elements are effectively arranged, which are adapted to apply a tool clamping force.

Injection molding machines of this type are referred to as two-plate machines and have the advantage that can be dispensed with a (third) plate, as it corresponds to the typical design of an injection molding machine. The machine concept is particularly suitable for larger and larger types of injection molding machines. A generic injection molding machine is beispielswiese from the DE 10 2009 018 096 A1 known.

In order to achieve a production operation with the shortest possible non-productive times, it is necessary that after the collapse of the two platens they are quickly and safely clamped or locked by means of the spars, in order to apply the tool closing force can.

Existing systems are here partly elaborately designed and correspondingly expensive.

The invention is therefore based on the task e, an injection molding machine of the type mentioned, so a two-plate machine to be designed so that the closure of the spars with a platen after the collapse of the tool halves is done quickly and safely, with a simple and thus cost-effective construction is sought.

The solution of this object by the invention is characterized in that the locking means are formed by an area of the spar and the piston of the piston-cylinder element, wherein the spar has at least one recess, so that at least one radially projecting to the longitudinal axis projection is formed wherein the piston can be rotated about the longitudinal axis of the spar in a first rotational position in which at least one radially inwardly projecting towards the longitudinal axis of the piston portion engages behind the at least one projection of the spar in the closing direction and wherein the piston about the longitudinal axis of the spar in a second rotational position can be rotated, in which the at least one piston portion is arranged without undercut in the closing direction to the at least one projection of the spar.

Preferably, the spar with its at least one projection and the piston cooperate with its at least one piston portion in the manner of a bayonet closure.

The at least one projection of the beams preferably has two, three or four projection sections distributed around the circumference of the beam; the piston has correspondingly two, three or four corresponding piston sections which can each be brought into cooperation with a projection section.

The spar usually has a number of recesses which are arranged successively in the direction of the longitudinal axis, so that a corresponding number of projections are present. So can be realized in a simple way locking for different tool installation heights.

For each of the spars may be present on one of the tool clamping plates depending on a piston-cylinder element. In order to achieve a simultaneous locking of all locking means, provides a development that synchronization means are provided with which the rotational movement of all pistons can be synchronized about the longitudinal axis of the spar. The synchronization means may be realized by linkages which engage the piston eccentrically to the longitudinal axis of the spar and connect two pistons together. The synchronization means may be realized according to another solution by gears which are arranged on pistons and which mesh with a centrally arranged sun gear.

The synchronization means may further comprise a drive element, wherein the drive element is preferably connected to one of the linkage or with the sun gear and move it. The drive element is according to a preferred construction an electrically, pneumatically or hydraulically driven actuator.

The proposal of the invention is therefore based on a two-plate injection molding machine, wherein the closing plate can be moved over the driving cylinder and the spars are mounted with punctures firmly in the fixed nozzle plate.

For locking with the machine closed or closed tool a rotary piston is provided, which is part of the piston-cylinder element (pressure cell). The piston accomplishes on the one hand the locking via a bayonet locking (with preferably 2 or 3 times milled off); on the other hand, the piston also builds up the closing force for locking the tool.

Due to this integration and the execution of the piston as a synchronous cylinder, no additional bearings for the rotational movement are necessary.

The system can operate completely maintenance-free and wear-free - since it runs in oil.

For the synchronous rotational movement of the (preferred) four pistons either a toothing with a sun gear can be used, wherein the drive can take place via a hydraulic or electric motor. Alternatively, the synchronization via a linkage with an actuator is possible, which can be actuated hydraulically or electrically via a motor spindle combination.

The proposal according to the invention can also be realized vice versa, d. H. the piston-cylinder elements (pressure boxes) with the rotatable piston are arranged in this case on or in the fixed nozzle plate.

The achievable advantages in comparison with previously known two-platen machines, which the proposed invention provides, can be summarized as follows:

It is a very short construction possible.

There is no disturbing structure in the direction of the injection unit on the nozzle plate.

The fixed bolted spars with integrated anti-rotation prevent lowering of the spars in the open position.

The design has few components and can be realized cost-effectively.

It is a maintenance-free operation possible with small amounts of oil.

The use of synchronous cylinders in the piston-cylinder units results in a high positioning accuracy.

In the drawings, embodiments of the invention are shown. Show it:

1a 1 is a schematic side view of an injection molding machine embodied as a two-platen machine according to a first embodiment of the invention;

1b the too 1a Corresponding sectional view AA according to 2 .

2 schematically the front view of the injection molding machine according to 1 wherein two alternative synchronization means are indicated,

3a 1 is a schematic side view of an injection molding machine embodied as a two-platen machine according to a second embodiment of the invention;

3b the too 3a associated sectional view BB according to 4 .

4 schematically the front view of the injection molding machine according to 3 .

5 the section CC according to 1a .

6 schematically the piston designed as a rotary piston of a piston-cylinder element in section CC according to 1a and

7 schematically a spar in section DD according to 1a ,

In 1a . 1b and 2 is an injection molding machine 1 shown, which has a (not shown) machine bed on which a fixed platen 2 (Nozzle plate) is fixed. Furthermore, a movable platen 3 (Closing plate) arranged displaceably on the machine bed, which can move in the closing direction S on the machine bed. The movement of the tool clamping plate 3 takes place via at least one driving cylinder 16 , The movement is controlled by a linear guide 17 possible.

At the fixed platen 2 are spars 4 arranged, which have a longitudinal axis L which is parallel to the closing direction S. The from the fixed platen 2 distant end portions of the spars 4 dive when moving together the two platens 2 . 3 in holes in the movable platen 3 one. At this point are piston-cylinder units 6 arranged for generating the tool closing force, which are designed as hydraulic pressure cans. For every spar 4 is a pressure cell 6 available.

By locking means 5 , in the 1 and 2 are not shown in detail, then the spars 4 with the tool clamping plate 3 locked.

While in 1 and 2 you can see that the spars on the platen 2 are attached and with the pressure cans 6 interact in the tool clamping plate 3 installed or attached to this can also be provided conversely, that the spars 4 on the movable platen 3 are fixed and the pressure cans accordingly to the fixed platen 2 are arranged. This solution is in the 3a . 3b and 4 shown.

The way of locking the spars 4 with the pressure cans 6 go out of the others 5 to 7 out.

In synopsis with the 1 and 3 First, you can see that in the end area of the spars 4 recesses 8th (Grooves or annular grooves) are incorporated, so that radially to the longitudinal axis L protruding projections 9 arise. From these projections 9 a number is provided in the longitudinal direction L successively in order to easily realize different tool installation heights can.

The pistons 7 the piston-cylinder units 6 (Pressure boxes) are, however, designed as a rotary piston, ie they can about the longitudinal axis L by an angle α in a first rotational position I and in a second rotational position II be turned, like it 5 suggests.

How best 6 shows, the piston points 7 (In the embodiment) three around the circumference of the piston 7 radially inwardly excellent piston sections 10 on. As 7 shows are in the spar 4 (Three) longitudinal grooves L extending in the longitudinal direction 18 incorporated so that over the circumference of the spar 4 around three sections of the projection arise.

The embodiment of the rotary piston 7 and the (non-rotatably mounted on a tool platen) spars 4 it allows that rotary piston 7 and spars 4 interact in the manner of a bayonet closure.

Will the rotary piston 7 from the in 6 shown position by an angle α - in the present case by 60 ° - twisted, get the piston sections 10 in a position in which they are with the longitudinal grooves 18 in the spar 4 aligned; accordingly, the spar 4 in the piston-cylinder element 6 Immerse until the tool halves are together.

Will then the rotary piston 7 in the in 6 shown position rotated back by the angle α, grab the piston sections 10 with undercut (seen in the closing direction S) behind the corresponding projection 9 of the spar 4 one, so that the spar 4 relative to the piston 7 is locked.

The synchronous movement of all (four) pistons 7 of the (four) pressure cans 6 is through synchronization means 11 achieved in 2 are indicated.

According to one embodiment, these are rods 12 , each two pistons 7 connect together so that the rotation (by the angle α) of the one piston is transmitted to the other piston. One of the linkage 12 is with a drive element 15 connected. This drive element 15 accomplishes the said rotation of the (four) pistons 7 ,

Another embodiment provides that on each piston 7 a gear with a toothing 13 is arranged. All (four) gears of the (four) pistons 7 comb with a central sun gear 14 that the (four) pistons 7 turns according to the corresponding drive.

LIST OF REFERENCE NUMBERS

1

injection molding machine

2

fixed tool clamping plate (nozzle plate)

3

movable tool clamping plate (closing plate)

4

Holme

5

locking means

6

Piston-cylinder element

7

piston

8th

Recess in the spar

9

Ledge of the spar

10

piston section

11

synchronization means

12

linkage

13

gearing

14

sun

15

driving element

16

driving cylinder

17

linear guide

18

longitudinal groove

I

first rotational position

II

second rotational position

α

angle

S

closing direction

L

longitudinal axis

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102009018096 A1 [0002]

Claims (10)

Injection molding machine ( 1 ), comprising a machine bed on which a fixed platen ( 2 ), wherein on the machine bed continue a sliding platen ( 3 ) is arranged, which relative to the first platen ( 2 ) is displaceable in a closing direction (S), wherein on one of the platens ( 2 . 3 ) a number of spars ( 4 ) are fastened with a longitudinal axis (L) which is suitable for applying a tool closing force relative to the other tool clamping plate ( 2 . 3 ) by means of locking means ( 5 ) are lockable and wherein between the spars ( 4 ) and one of the tool platens ( 2 . 3 ) Piston-cylinder elements ( 6 ) are arranged, which are designed for applying a tool clamping force, characterized in that the locking means ( 5 ) through an area of the spar ( 4 ) and the piston ( 7 ) of the piston-cylinder element ( 6 ) are formed, wherein the spar ( 4 ) at least one recess ( 8th ), so that at least one radially to the longitudinal axis (L) protruding projection ( 9 ) is formed, wherein the piston ( 7 ) about the longitudinal axis (L) of the spar ( 4 ) in a first rotational position ( I ) can be rotated in the at least one radially to the longitudinal axis (L) inwardly projecting piston portion ( 10 ) the at least one projection ( 9 ) of the spar ( 4 ) in the closing direction (S) engages behind a positive fit and wherein the piston ( 7 ) about the longitudinal axis (L) of the spar ( 4 ) in a second rotational position ( II ) can be rotated, in which the at least one piston section ( 10 ) without undercut in the closing direction (S) to the at least one projection ( 9 ) of the spar ( 4 ) is arranged. Injection molding machine according to claim 1, characterized in that the spar ( 4 ) with its at least one projection ( 9 ) and the piston ( 7 ) with its at least one piston section ( 10 ) interact in the manner of a bayonet closure. Injection molding machine according to claim 1 or 2, characterized in that the at least one projection ( 9 ) of the Holms ( 4 ) two, three or four around the circumference of the spar ( 4 ) has distributed projecting portions and the piston ( 7 ) two, three or four corresponding piston sections ( 10 ), which can each be brought into cooperation with a projection portion. Injection molding machine according to one of claims 1 to 3, characterized in that the spar ( 4 ) a number of recesses ( 8th ), which are arranged successively in the direction of the longitudinal axis (L), so that a corresponding number of projections ( 9 ) available. Injection molding machine according to one of claims 1 to 4, characterized in that for each of the spars ( 4 ) on one of the tool platens ( 2 . 3 ) one piston-cylinder element each ( 6 ) is available. Injection molding machine according to claim 5, characterized in that synchronization means ( 11 ) are present, with which the rotational movement of all pistons ( 7 ) about the longitudinal axis (L) of the spar ( 4 ) can be synchronized. Injection molding machine according to claim 6, characterized in that the synchronization means ( 11 ) by linkage ( 12 ), which are eccentric to the longitudinal axis (L) of the spar ( 4 ) on the piston ( 7 ) and two pistons ( 7 ) connect with each other. Injection molding machine according to claim 6, characterized in that the synchronization means ( 11 ) by gears ( 13 ) which are attached to pistons ( 7 ) and arranged with a centrally located sun gear ( 14 ) comb. Injection molding machine according to one of claims 6 to 8, characterized in that the synchronization means ( 11 ) further a drive element ( 15 ), wherein the drive element ( 15 ) preferably with one of the linkages ( 12 ) or with the sun wheel ( 14 ) and move this. Injection molding machine according to claim 9, characterized in that the drive element ( 15 ) is an electrically, pneumatically or hydraulically driven actuator.

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