DE8908890U1 - Chip conveyor - Google Patents

Description

:·!::· :: ·*! He 6605/1

Chip conveyor

The innovation relates to a chip conveyor according to the preamble of claim 1. 5

Chip conveyors (particularly belt or scraper conveyors) are subject to frequent malfunctions during operation due to a chip jam. Since the conveyor element (scraper belt or scraper chain) is more or less blocked, there is a risk

an overload of the drive unit gate.

In order to protect the drive units _L from blocking the conveyor against overload, well-known chip conveyors with a slip clutch

equipped. However, such a design is affected by various power parts. Due to the wear of the clutch discs of the slip clutch, the drive unit changes torque transmitted to the conveyor element". This

not only impairs the functional reliability of the chip conveyor^, but also makes undesirable readjustments necessary in automated production facilities.

The innovation is therefore based on the task of

to design a chip conveyor of the type specified in the preamble of claim 1 in such a way that with simple and largely maintenance-free means a reliable overload

protection of the drive unit is achieved.

This task is solved according to the innovation by the characterizing features of claim 1. Appropriate embodiments of the innovation are

Subject matter of the subclaims.

The new chip conveyor is equipped with a reversing contactor which, at a certain &dgr; load on the chip conveyor unit (measured by

the deflection of a torque support) and switches the direction of rotation of the drive unit to reverse rotation of the conveyor element. A time relay is also provided, which switches an adjustable time after the reversing

contactor switches the direction of rotation of the drive unit back to forward rotation of the conveyor element.

^tet ·

The described short-term reversal of the course

If necessary, the conveyor can be moved several times until the chip jam that triggered the overload protection has finally been cleared. Manual intervention in the operating process is thus in case of chip jams and

other clamping rounds are not required.

Since the described device provides reliable overload protection of the drive unit guaranteed, can be achieved with the inventive

Chip conveyors, the installation of a slip clutch between the drive unit and the conveyor element is not necessary. This ensures that the once set nominal torque of the drive

gregat is transferred to the conveyor body.

An example of the innovation is shown in the drawing. It shows 35

Fig. 1 is a side view of the mechanical elements of the overload protection device, _fi

Fig. 2 and 3 sections along the line II-1I and III-III of Fig.l, respectively,

Fig. 4 is a circuit diagram of the overload

Circuit.

The chip conveyor, which is not shown in detail, is driven by a motor (not shown), a drive unit 1, a drive shaft 2 designed as a hollow shaft and a chain wheel 3 connected to the drive shaft 2, via which the endlessly rotating conveyor element designed as a hinge belt or scraper chain is driven. The connection between the shaft la of the drive unit 1 and the drive shaft 2 is made via a shaft stub 4, which is connected to the shaft la via a key 5 and via a noise-reducing key 6. Z. *».

a shear pin 6 is connected to the drive shaft 2.

The drive shaft is mounted by means of a bearing 7 in a bearing plate 8, which is fastened, for example, by means of nuts 9 on bolts 10, which in turn are firmly connected to a side plate 11 of the housing of the chip conveyor.

A swing arm 12 is connected to the housing of the drive unit 1 in a rotationally fixed manner. A threaded sleeve 14 is attached to the swing arm 12 by means of a screw 13, into whose axial internal thread the screw 13 is screwed ^ At the left end (Fig. 3) of the threaded sleeve 14 there is a threaded hole offset by 90° from the sleeve axis, into which

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I » ff · &Lgr; ♦ »

a threaded rod 15 is screwed in. The connection between the threaded sleeve 14 and the threaded rod 15 can be secured by a lock nut 16 or

a safety pin. 5

The threaded rod 15 is movably guided through a stationary abutment 17 which is fastened to the bearing plate d.

At the lower end, the threaded rod 15 carries an L-shaped bracket 20 fastened by means of nuts 18, 19, on which a control cam 21 is provided for actuating a control switch 22.

A spring element, for example a compression spring 23, is provided on the threaded rod 15 between the stationary abutment 17 and the threaded sleeve 14. Another spring element, for example designed as a compression spring 24, is located between the abutment 17 and the nut 18.

The previously described mechanical parts of the overload protection device of the drive unit

work as follows: 25

It is assumed that the conveyor element of the chip conveyor is designed as a hinged belt. If the conveyor element is blocked by a fault, for example a chip jam, the swing arm 12

3" of the torque arm counterclockwise (Fig. 1)

deflected. The upper compression spring 23 is consequently compressed. The threaded rod 15, the bracket 20 and the control cam 21 move in the deflection direction (in Fig. 1, therefore downwards). At a certain

—th deflection of the rotary actuator, the control switch 22 is actuated by the control cam 21. The

* to this operation of the control switch 22

The switching operations involved are explained in more detail in Fig.

° While a hinged belt conveyor is basically

on the upper run of the endlessly rotating conveyor, the chip transport in the case of crank conveyors is carried out with the lower run of the conveyor designed as a scraper chain. The direction of rotation of the drive unit is therefore normally

Operation of a scraper conveyor is generally the opposite of the direction of rotation of a hinged belt conveyor.

If the conveyor element of the chip conveyor is designed as a scraper chain and a malfunction occurs during operation, for example a chip jam, the swing arm 12 of the torque support is deflected clockwise (Fig. 1). The lower compression spring 24 is compressed more strongly, whereby the threaded rod 15, the bracket 20 and the

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Vtl VA/dl WCfTV

The control switch 22 is actuated when the torque support is deflected.

With reference to Fig. 4, the electrical elements

The function of the overload protection device and the switching processes that occur when the control switch 22 is actuated are explained in more detail.

The circuit according to Fig. 4 shows the drive motor

Ml, a motor protection switch Ql, a contactor Kl

(with contacts k. , k,u» k, , k,- as well as with einsr

relay coil Sl), furthermore a reversing contactor K" (with

contacts k _2a , ^b'*2c'*2d' *2e ^eow ^ ^em * ^fc a relay coil S2) , furthermore a time relay K3 (with & a contact k, as well as a relay coil S3),

furthermore the control switch 22 (with the contacts 22a, 22b) already mentioned in Fig. 1.

The function of the switches according to Fig.4 is as follows: If connected to terminals 1, 2 and 3 of the

Main control voltage is applied, current flows via the closed motor protection switch Ql and the closed contacts 22a and k- _d to the relay contactor Sl, so that the contactor Kl is activated.

1& thus closed contacts k« , k,., k. receives

the motor Ml voltage so that the chip conveyor starts.

If a chip jam occurs and the control switch 22 is operated, the contact 22a opens

and the contact 22b closes= InfQlgedeesen the relay coil Sl is de-energized so that the contacts k _la , k _lb , k, open. At the same time the relay coil S2 receives voltage via the closed contacts 22b, ]&sfgr; so that the contactor K2 picks up and the

Contacts k _2a , k _2t) , fc _2c close. Tsh:; Drive motor Ml consequently runs backwards.

The contactor K2 is latched via the contact k _2. The drive motor Ml therefore also runs

then continue backwards when the control switch is no longer actuated (so that contact 22b is opened again).

Simultaneously with the activation of contactor K2

also receives the relay coil S3 of the delay

time relay K3 voltage. When the set time is reached, the time relay K3 is activated so that the contact k _3a opens. This causes the relay

coil S2 of the reversing contactor K2 is de-energized.

If the reversing contactor K2 is de-energized and the control switch 22 is no longer actuated, the contactor K1 is activated again so that the motor runs in the conveying direction again.

If the chip jam has not been cleared by this brief reversal of the conveying direction, the process described can be repeated as often as desired. The motor is protected by the

Motor protection switch Ql sufficiently protected.

Claims (4)

He 6605/1 Protection claims: 1. Chip conveyor, containing a) a hinged belt or a scraper chain trained, «ndios circulating conveyor orgaB, h) a drive connected to the conveyor ac.- c) a device for overload protection of the drive unit, characterized by the following elements of Overload protection device: c,) a drive unit connected to the drive unit Torque support, 20 cJ a control switch that can be actuated by a certain deflection of the torque support (22), C^ on when the control switch (22) is operated reversing contactor (K2) that switches the direction of rotation of the drive unit to reverse rotation of the conveyor element, C ₄ ) a time relay (K3) which has an adjustable Time after the reversing contactor (K2) has been activated, the direction of rotation of the drive unit switches back to forward running of the conveyor element. 2. Chip conveyor according to claim 1, characterized by the following parts of the torque arm: C ₁₁ ) a rocker (12) connected in a rotationally fixed manner to the housing of the drive unit, Cj,) a threaded rod (15) which is connected at one end to the swing arm (12) via a threaded sleeve (14), 10 c, ,f a tait the other end of the thread 'i connected switch cam i21) for operating the control switch (22) designed as a tappet roller switch, 15 C ₁₄ ) a stationary abutment (17) through which the threaded rod (15) is movably guided. ^c i5^ ^two i ^on ^ the threaded rod (15) arranged, pre-stressed compression springs (23, 24) which are clamped between the abutment (17) and the two ends of the threaded rod and, when moving, the swing arm (12) in opposite directions says: will. 3. Chip conveyor according to claim 1, characterized in that the drive unit is a worm gear (1) which has a Shaft stub (4) is connected to a drive shaft (2) of the conveying element designed as a hollow shaft. 4. Chip conveyor according to claims 2 and 3, characterized in that the compression springs (23, 24), the threaded rod (15) and the stationary abutment (17) of the torque support are arranged in a bearing plate (S) attached laterally to the housing (11) of the chip conveyor, which at the same time contains the bearing (7) of the drive shaft (2) of the conveyor element.