DE202021102773U1 - Gear motor device - Google Patents

Abstract

A gear motor device for rotating a rotatable element, for example a screw of a conveyor, comprising:
- An electric motor (2) with a rotor (4) and a stator (5), which are accommodated in a housing (7), the electric motor (2) further comprising a drive shaft (3) which extends along an axis ( Z) extends;
- a gear unit (9) comprising a first gear (12) which can be rotated by the electric motor (2) and a second gear (13), the first gear (12) and the second gear (13) inside a casing (14) are arranged, the gear unit (9) having an output shaft (10) which is offset relative to the drive shaft (3) and is connectable to the rotatable element in order to rotate the rotatable element;
- a coupling flange (25) for fastening the geared motor device (1) to a device comprising the rotatable element, the coupling flange (25) being connected to the casing (14) by a releasable and non-permanent connection, the housing ( 7) has a plurality of projections (16) protruding transversely to the axis (Z) to receive respective releasable fastening elements (15) which are arranged to releasably connect the casing (14) to the housing (7).

Description

The utility model relates to a geared motor device which is adapted to rotate a rotatable element, for example a screw of a screw conveyor. The conveyor can have a tubular enclosure in which a screw is rotatably received. A flowable material can be transported in one feed direction with the screw. The flowable material can be a liquid in which solid fractions may be dispersed, or a highly viscous fluid or a solid material comprising flakes, granules or powder.

In prior art screw conveyors, the screw is normally rotated by a gear motor device comprising an electric motor and a gear unit. The electric motor is connected to the gear unit via a standard flange, that is, a flange manufactured according to certain international standards that define numerous geometrical and dimensional parameters of the flange, such as the external diameter, the number of mounting holes with which the flange of the Motor can be attached to the gear unit, the distance between the axes of the mounting holes and the like.

While the prior art gear motor devices are robust and reliably perform their service, there is still room for improvement - particularly with regard to their dimensions, their weight and their cost.

An object of the utility model is to improve geared motor devices of the known type, in particular of the type used for rotating a screw of a tubular conveyor.

Another object is to provide a geared motor device with limited dimensions, particularly in an axial direction, in such a way that the space required in prior art conveyors to accommodate the gear motor device which drives the auger can be reduced.

Another object is to provide a geared motor device with a limited weight in order to simplify and design the support structures used in prior art screw conveyors to support the gear motor device.

Another object is to reduce the cost of the gear motor devices.

• - einen Elektromotor mit einem Rotor und einem Stator, die in einem Gehäuse aufgenommen sind, wobei der Elektromotor des Weiteren eine Antriebswelle umfasst, die sich entlang einer Achse erstreckt;
• - eine Getriebeeinheit, die ein erstes Zahnrad, das durch den Elektromotor gedreht werden kann, und ein zweites Zahnrad umfasst, wobei das erste Zahnrad und das zweite Zahnrad innerhalb einer Einfassung angeordnet sind, wobei die Getriebeeinheit eine Abtriebswelle aufweist, die relativ zu der Antriebswelle versetzt ist und mit dem drehbaren Element verbindbar ist, um das drehbare Element zu drehen;
• - einen Flansch zum Befestigen der Getriebemotorvorrichtung an einer Vorrichtung, in der das drehbare Element enthalten ist, wobei der Flansch mit der Einfassung durch eine lösbare und nicht-dauerhafte Verbindung verbunden ist,

wobei das Gehäuse mehrere Vorsprünge aufweist, die quer zu der Achse vorstehen, um entsprechende lösbare Befestigungselemente aufzunehmen, die eingerichtet sind, um die Einfassung lösbar mit dem Gehäuse zu verbinden.According to the utility model, there is provided a geared motor device for rotating a rotatable element, for example a screw conveyor of a conveyor, comprising:

• an electric motor having a rotor and a stator which are received in a housing, the electric motor further comprising a drive shaft which extends along an axis;
• a gear unit comprising a first gear rotatable by the electric motor and a second gear, the first gear and the second gear being disposed within an enclosure, the gear unit having an output shaft that is offset relative to the drive shaft and is connectable to the rotatable member to rotate the rotatable member;
• a flange for fastening the gear motor device to a device in which the rotatable element is contained, the flange being connected to the casing by a releasable and non-permanent connection,

the housing having a plurality of protrusions projecting transversely of the axis for receiving respective releasable fasteners adapted to releasably connect the bezel to the housing.

The gear motor device according to the utility model has limited axial dimensions in comparison to the gear motor devices according to the prior art.

Thanks to the projections located on the housing, the flange that connected the electric motor to the gear unit in the prior art can be omitted. This allows the weight of the geared motor device to be reduced, since it is possible to save the material that was used in the prior art for the manufacture of the flange.

The axial dimensions of the gear motor device, that is to say the dimensions of the gear motor device parallel to the motor axis, are also reduced by an amount which corresponds approximately to the thickness of the flange.

In addition, the provision of an output shaft that is not aligned with the drive shaft enables the axial dimensions of the gear motor device to be limited, since some components of the gear motor device can be arranged laterally relative to the axis of the drive shaft instead of being aligned with the latter.

In one embodiment, the first gear is supported by the drive shaft in a stationary position relative to the drive shaft.

In this way it is possible to obtain a particularly compact gear motor device. In addition, a single pair of bearings can be used to support both the drive shaft and the first gear.

In one embodiment, the housing of the motor is coupled to the enclosure of the gear unit along a coupling plane.

The housing has a cavity in which the stator and the rotor are received.

The cavity of the housing has an inner transverse dimension, for example an inner diameter, measured in the coupling plane, which is at least as large as an outer transverse dimension, for example an outer diameter, of the stator.

It is thus possible, after disconnecting the gear unit from the electric motor, to pull out the stator and replace it in the event of a malfunction.

This makes maintenance of the gear motor device particularly easy and economical.

Indeed, in the event of a malfunction of the electric motor, which in most cases is related to a malfunction of the stator, the electric motor can be repaired simply by replacing the damaged stator with a new stator.

It is therefore possible to avoid replacing the entire electric motor, which would also be quite expensive due to the special geometry of the electric motor, in which the protrusions of the housing have replaced the standard flanges of the conventional electric motors.

• 1 ist eine perspektivische Ansicht einer Getriebemotorvorrichtung zum Drehen eines drehbaren Elements, zum Beispiel einer Schnecke eines Förderers;
• 2 ist eine Seitenansicht der Getriebemotorvorrichtung von 1;
• 3 ist eine teilweise auseinandergezogene Ansicht, die einige Komponenten der Getriebemotorvorrichtung von 1 zeigt;
• 4 ist ein Querschnitt durch eine Mittelebene der Getriebemotorvorrichtung von 1.

The utility model can be better provided and implemented with reference to the accompanying drawings, which illustrate a non-limiting exemplary embodiment, in which the following is shown:

• 1 Fig. 3 is a perspective view of a geared motor device for rotating a rotatable member such as a screw of a conveyor;
• 2 FIG. 13 is a side view of the gear motor device of FIG 1 ;
• 3 FIG. 13 is a partially exploded view showing some components of the gearmotor device of FIG 1 shows;
• 4th FIG. 13 is a cross section through a median plane of the gear motor device of FIG 1 .

1 until 4th show a gear motor device 1 which can be used to rotate a rotatable element, in particular a screw of a screw conveyor.

The screw conveyor with which the gear motor device 1 can be connected can comprise a tubular skirt which at least partially receives a screw extending along a longitudinal axis. The screw conveyor can be used to transport a liquid, which may contain solids in dispersion, or a viscous fluid or a solid material in the form of flakes, granules or powder, along a feed direction. The gear motor device 1 can be connected to the screw in order to rotate the latter around the respective longitudinal axis.

The gear motor device 1 includes an electric motor 2 to provide torque as output power. The electric motor 2 includes a drive shaft 3 on which a rotor 4th is attached. A stator 5 is at a fixed position within the electric motor 2 arranged and surrounds the rotor in the illustrated example 4th . The stator 5 includes a winding 6th made in particular of copper, which in the illustrated example has a prismatic geometry with a hexagonal cross-section.

The drive shaft 3 extends along an axis Z and is associated with the rotor 4th rotatable around the Z axis.

The electric motor 2 includes a housing 7th that is the stator 5 and the rotor 4th records. The case 7th is tubular and extends around axis Z. The housing 7th has several ribs on an outer surface 8th on to the cooling of the electric motor 2 to support.

Also the drive shaft 3 is at least partially in the housing 7th recorded.

The gear motor device 1 further comprises a gear unit 9 to as output power from the gear motor device 1 provide a desired speed value by changing the speed of the drive shaft 3 is reduced.

The gear unit 9 includes an output shaft 10 that can be coupled to the rotatable element that is supported by the Gear motor device 1 should be rotated. The output shaft 10 can for example be coupled to the screw of a screw conveyor.

The output shaft 10 can be provided with a coupling element so that the output shaft 10 can be coupled to the rotatable member provided by the gear motor device 1 should be rotated. The coupling element can, for example, be a wedge profile 11 include that at one end of the output shaft 10 is trained.

The output shaft 10 extends along another axis Y.

The other axis Y runs parallel to the axis Z and is offset relative to this. Consequently, the output shaft is 10 not on the drive shaft 3 aligned; that is, they don't curse each other.

The gear unit 9 includes a first gear 12th that goes through the drive shaft 3 can be driven. The first gear 12th is at one end of the drive shaft 3 attached. More precisely, the first gear can 12th with an interference fit on the drive shaft 3 to be assembled. This way is the first gear 12th relative to the drive shaft 3 stationary, that is, the first gear 12th and the drive shaft 3 act like a one-piece body.

The gear unit 9 further comprises a second gear 13th that is relative to the output shaft 10 is stationary. In the example shown, the second gear is engaged 13th directly into the first gear 12th a. In other words, there are no intermediate gears between the first gear 12th and the second gear 13th arranged. The gear unit 9 includes only two gears.

In the example shown, these are the first gear 12th and the second gear 13th Spur gears with helical teeth. However, this condition is not necessary and the first gear 12th and the second gear 13th could also be spur gears with straight teeth.

The second gear 13th has a first pitch circle diameter that is larger than the pitch circle diameter of the first gear 12th . The first gear 12th can therefore be defined as a pinion and acts like a fast gear while the second gear 13th acts like a slow gear. In other words, the output shaft 10 a lower speed than the drive shaft 3 .

The gear unit 9 further comprises a bezel 14th in which the first gear 12th and the second gear 13th are included.

The edging 14th is through several detachable fasteners 15th which may in particular include threaded elements on the housing 7th attached. The releasable fasteners 15th allow the gear unit 9 as often as required on the electric motor 2 to attach and allow the gear unit 9 any number of times from the electric motor 2 to separate.

The releasable fasteners 15th engage in corresponding mounting holes in the respective projections 16 of the housing 7th are trained. The protrusions 16 stand from a main body 17th of the housing 7th transversely to the Z axis, for example perpendicular to the Z axis.

The protrusions 16 are distributed around the Z axis.

The edging too 14th has several preceding paragraphs 18th on that are set up to stick to the protrusions 16 of the housing 7th to lie on. Each preceding paragraph 18th has a hole in which a releasable fastener 15th engages to the case 7th detachable with the edging 14th connect to.

The preceding paragraphs 18th stand by the edging 14th transversely, in particular perpendicular, to the Z axis of the drive shaft 3 emerged.

The preceding paragraphs point in a plane perpendicular to the Z axis 18th a profile that matches the profile of the protrusions 16 matches.

The protrusions 16 and the preceding paragraphs 18th allow the electric motor 2 and the gear unit 9 releasably couple without using the standard flanges of the prior art.

More precisely, allow the protrusions 16 and the preceding paragraphs 18th a minimization of the material between two consecutive protrusions 16 and between two consecutive preceding paragraphs 18th compared to the case that the electric motor 2 and the gear unit 9 have circular flanges for securing each other.

It is also possible to change the axial dimensions of the electric motor 2 and the gear unit 9 by an amount roughly equivalent to the thickness of conventional flanges. The protrusions 16 and the preceding paragraphs 18th stand to the side of the main body 17th of the housing 7th or from the edging 14th emerged.

The drive shaft 3 is supported by a pair of roller bearings. More specifically, it will be the drive shaft 3 through a first camp 19th supported by the Can be ball type and at the end of the drive shaft 3 on which the first gear 12th is attached, is arranged. The drive shaft 3 is also through a second camp 20th which can also be of the ball type and at one end of the drive shaft 3 is positioned that is the end where the first gear 12th is attached, opposite.

The second camp 20th has an inner ring into which the drive shaft 3 is used, and an outer ring that is in a paragraph 21 of the housing 7th is excluded. Paragraph 21 protrudes into the interior of the housing 7th .

The first camp 19th has an inner ring through which the drive shaft extends 3 extends, and an outer ring in one in the enclosure 14th trained seat is added.

The first gear 12th has an outer diameter that is smaller than the inner diameter of the first bearing 19th . In this way it is possible to have the first camp 19th from the drive shaft 3 pulling off without using the first gear 12th to collide. The first camp 19th is from the drive shaft 3 deducted when the gear unit 9 along with the bezel 14th from the electric motor 2 is separated. When this happens, the first camp remains 19th at the edging 14th the gear unit 9 attached.

The case 7th has a cavity 22nd on where the rotor 4th and the stator 5 are included. In the example shown, the cavity 22nd has a substantially cylindrical shape.

The gear unit 9 is with the electric motor 2 coupled along a coupling plane P, the outline of which in the 2 and 4th is shown. The coupling plane P is arranged transversely, in particular perpendicular, to the Z axis.

The edging 14th lies along a coupling zone which lies on the coupling plane P on the housing 7th at.

The cavity 22nd of the housing 7th has an inner transverse dimension (for example an inner diameter), measured in the coupling plane P, which is at least as large as an outer transverse dimension of the stator 5 is. This outer transverse dimension of the stator 5 is measured perpendicular to the Z axis and can, for example, be an outer diameter of the stator 5 be.

This allows the stator 5 easily out of the case 7th can be pulled out to carry out maintenance or repair work, as described in more detail below.

In other words, the cavity opens 22nd in the coupling level P and the gear unit 9 - or, to be more precise: its edging 14th - Acts in a mounted embodiment of the gear motor device 1 as a cap for the cavity 22nd .

The gear unit 9 extends relative to the electric motor 2 in an off-center position.

More precisely, the gear unit 9 a box-shaped body 23 on, which is the first gear 12th and the second gear 13th extends around and laterally relative to the housing 7th is offset. In other words, the box-shaped body is standing 23 to the side of the housing 7th from, that is, it is transverse to the Z axis of the housing 7th emerged.

The edging 14th also has a rib 24 on that of the box-shaped body 23 protrudes and is between the box-shaped body 23 and the case 7th extends. The rib 24 is on the opposite side of the box-shaped body 23 relative to the portion of the box-shaped body 23 arranged laterally relative to the housing 7th protrudes.

The gear motor device 1 also includes a coupling flange 25th for attaching the gear motor device 1 on the rotatable member driven by the gear motor device 1 is to be set in rotation, for example on the screw of a screw conveyor. The coupling flange 25th is at the edge 14th on that of the electric motor 2 attached opposite side.

The coupling flange 25th is through a detachable and non-permanent connection, for example through several threaded elements 26th , on the edging 14th attached. This allows the coupling flange 25th from the mount 14th can be solved without affecting the components of the transmission device 1 to be damaged. In this way it is possible to use the gear motor device 1 by simply replacing the coupling flange 25th suitable for attachment to various types of rotatable elements or augers.

The coupling flange 25th can be coaxial with the output shaft 10 get lost.

The coupling flange 25th has a central bore through which the output shaft 10 runs.

The output shaft 10 stands axially from the coupling flange 25th emerged.

The coupling flange 25th can be on an area farthest from the edging 14th away is a seat 27 have, which is intended to receive a sealing element (not illustrated) that a tight connection of the flange 25th with the rotatable element made possible by the gear motor device 1 should be set in rotation.

The gear motor device 1 also includes a fan 28 for cooling the electric motor 2 . The fan 28 can be at one end of the drive shaft 2 attached to the end where the first gear 12th is attached, opposite. In this way the fan will spin 28 together with the drive shaft 3 about the Z axis when the drive shaft is 3 turns.

The fan 28 can in one subject 29 be included that between a concave body 30th and an end face 31 of the housing 7th is formed.

There is also an electrical box 32 present, in which several components for connecting and controlling the electric motor 2 are included. The electrical box 32 stands from one side of the case 7th emerged.

During operation of the gear motor device 1 it can cause malfunctions in the electric motor 2 come. The most common component to fail in motors of this type is the stator 5 . In the event of a malfunction in the stator 5 it is possible in a relatively simple way to repair the damaged stator 5 to remove and replace with a new stator 5 to replace.

To this end, the gear motor device 1 removed from the device to which it is connected, for example the screw conveyor.

At this point, by acting on the detachable fastening elements 15th the edging 14th from the housing 7th separated.

The second gear 13th and the first camp 19th stay at the rim 14th assembled. The coupling flange 25th also remains on the edging 14th attached.

The second gear 13th is from the first gear 12th that is relative to the drive shaft 3 is stationary, separated.

The first camp 19th becomes from the second gear 13th pulled out.

At this point is the gear unit 9 from the electric motor 2 separated. The cavity 22nd is accessible from the outside and it is possible to remove the damaged stator 5 easy to remove and replace with a new stator 5 to replace.

It is now possible to use the gear unit 9 back to the electric motor 2 to assemble, the sequence of operations being the reverse of that just described, whereupon the gear motor device 1 can continue to work.

This avoids that in the event of a defect in the stator 5 the entire gear motor device 1 disposed of and replaced by a new complete gear motor device 1 must be replaced, which means a considerable cost saving.

The electric motor 2 can be specially designed for the type of application for which the gear motor device 1 should be used.

For example, the gear motor device 1 used in a screw conveyor designed to transport cement in powder form. The screw conveyors of this type tend to operate intermittently and their operation includes a period of time in which the screw rotates, followed by a period in which the screw stands still and consequently the electric motor 2 is inactive.

Also, the electric motor must 2 a screw conveyor that is supposed to move cement in powder form has a relatively high initial torque in order to be able to move the cement, which can initially be highly compacted. After starting, however, it is sufficient if the electric motor 2 delivers a lower torque.

The electric motor 2 can be designed so that it works under operating conditions close to overheating during the initial phase, in which a relatively high starting torque is required. This has no negative effects on the service life or the operation of the electric motor 2 as this is able to remain inactive during the period of inactivity that follows the phase in which the electric motor 2 delivers a lower torque to cool down in a satisfactory manner.

It is thus possible to optimize the dimensioning of the motor in such a way that sufficient power is provided for the fulfillment of the transport function and the installation of “commercial” oversized motors is avoided.

The optimization enables cost savings in the engine that do not have a negative effect on the efficiency of engine operation.

Claims (15)

Gear motor device for rotating a rotatable element, for example a screw of a conveyor, comprising: - an electric motor (2) with a rotor (4) and a stator (5), which are accommodated in a housing (7), the electric motor (2) further comprising a drive shaft (3) which extends along an axis (Z ) extends; - a gear unit (9) comprising a first gear (12) which can be rotated by the electric motor (2) and a second gear (13), the first gear (12) and the second gear (13) inside a casing (14) are arranged, the gear unit (9) having an output shaft (10) which is offset relative to the drive shaft (3) and is connectable to the rotatable element in order to rotate the rotatable element; - a coupling flange (25) for fastening the geared motor device (1) to a device comprising the rotatable element, the coupling flange (25) being connected to the casing (14) by a releasable and non-permanent connection, the housing ( 7) has a plurality of projections (16) protruding transversely to the axis (Z) to receive respective releasable fastening elements (15) which are arranged to releasably connect the casing (14) to the housing (7). Gear motor device according to Claim 1 wherein the skirt (14) has a plurality of protruding shoulders (18) arranged in contact with the projections (16) of the housing (7), each releasable fastener (15) in one of the plurality of projections (16) and in a protruding shoulder of the plurality of protruding shoulders (18) is received to releasably attach the bezel (14) to the housing (7). Gear motor device according to Claim 1 or 2 wherein the housing (7) is coupled to the enclosure (14) on a coupling plane (P), the housing (7) having a cavity (22) in which the stator (5) and the rotor (4) are received wherein the cavity (22) has an inner transverse dimension, measured in the coupling plane (P), which is greater than or equal to an outer transverse dimension of the stator (5) so that the stator (5) can be pulled out of the cavity (22) after the gear unit (9) has been decoupled from the electric motor (2). A gear motor device according to any preceding claim, wherein the first gear (12) is supported by the drive shaft (3) and is fixed relative to the drive shaft (3). Gear motor device according to Claim 4 further comprising a first bearing (19) for supporting the drive shaft (3) near one end of the drive shaft (3) to which the first gear (12) is attached, and a second bearing for supporting the drive shaft (3) at one another end of the drive shaft (3) opposite that end. Gear motor device according to Claim 5 wherein the first bearing (19) has an inner diameter that is larger than an outer diameter of the first gear (12). Gear motor device according to Claim 5 or 6th wherein the first bearing (19) is mounted in a seat formed in the casing (14). A gear motor device according to any one of the preceding claims, wherein the first gear (12) is directly meshed with the second gear (13). Gear motor device according to one of the preceding claims, wherein the coupling flange (25) has a seat (27) for receiving a sealing element on its surface furthest from the casing (14). A gear motor device according to any preceding claim, further comprising a fan (28) attached to the drive shaft (3) on the opposite side of the drive shaft (3) relative to the first gear (12). Gear motor device according to one of the preceding claims, wherein the casing (14) protrudes laterally from the housing (7). Gear motor device according to one of the preceding claims, wherein the output shaft (10) extends along a further axis (Y) which is parallel to the axis (Z). A gear motor device according to any preceding claim, wherein the second gear (12) is keyed to the output shaft (10). A screw conveyor comprising a tubular housing and a screw at least partially received in the tubular housing, the screw conveyor further comprising a gear motor device (1) according to any one of the preceding claims, wherein the gear motor device (1) is connected to the screw to to rotate the screw around a respective longitudinal axis. Screw conveyor after Claim 14 intended for the transport of cement in powder form.

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