DE202017002251U1 - Apparatus for shredding food (conveyor screw) - Google Patents

Abstract

Device for mincing foodstuffs, comprising a cutting means (10) and a pressure housing (20) with a cylindrical drum wall (30), wherein the pressure housing (20) at a first end portion (21a) formed with a food inlet opening (22) and in the pressure housing (20) a conveyor screw (40) is rotatably mounted, which has a plurality of at least one worm gear (41) separate from each other screw chambers (42), characterized in that the screw conveyor (40) from the cutting means (10) a worm shaft ( 45) having a constant diameter (d1) followed by a tapered portion (46) of the worm shaft (45) in the direction of the first end portion (21a) to the smaller diameter (d2).

Description

The invention relates to a device for mincing foods according to the features standing in the preamble of claim 1.

Usually so-called wolves are used for mincing foods, especially meat, cheese and fat.

The DE 10 2006 034 150 A1 describes such a wolf for mincing food, in which the food, such as meat, transported by means of the screw conveyor in the axial direction through a pressure housing called pressure housing and a end attached thereto cutting set is supplied. The auger has within the pressure tube a worm shaft, whose diameter in the region of the cutting set, for example, 150 mm, initially increased in the direction of the feed side end to 180 mm and then back to the original diameter of 150 mm. The proposed increase in diameter of the screw shaft leads within the pressure tube to a desired here compression of the food to be crushed, which has been found in practice, however, with regard to a continuous supply of the food to the cutting set as negative.

The invention therefore an object of the invention to provide a device for mincing food with an improved supply of the food to be crushed to the cutting means.

The object is achieved with the features of claim 1. The loading of the device with the food to be crushed always takes place via an inlet opening which is formed from the first end section of the drum wall which is open in the axial direction. The conveying screw rotatably mounted in the pressure housing is usually arranged concentrically with respect to the cylindrical drum wall and preferably has a flight extending between two bearing points of the screw conveyor. The worm gear can run continuously between the bearings or be interrupted at one or more points. A plurality of screw chambers separated from each other by the screw flight is understood to mean the sequence of screw chambers adjacent in the axial direction when viewing a sectional plane passing through the center axis of the screw conveyor.

The screw conveyor is basically manufactured as a one-piece integral unit, which can not be disassembled into separate components without being destroyed. The screw conveyor is always driven by a motor.

According to the invention, the screw conveyor on the part of the cutting means on a screw shaft with a constant diameter d ₁ , which adjoins a tapered portion of the screw shaft in the direction of the first end portion to the smaller diameter d ₂ . The tapered section of the worm shaft ensures better filling of the pressure housing via the axially arranged inlet opening, since the clear cross section for the food is increased due to the smaller diameter d _{2 of} the worm shaft located in this area. The worm shaft itself reduces due to their massive design, the remaining cross-section within the drum wall, or the size of the screw chambers in the radial direction.

The at least one flight may have a greater pitch in the area of the constant diameter d _{1 of} the worm shaft and a smaller pitch in the tapered portion of the worm shaft. Due to the tapered section of the worm shaft, the volume within the worm chambers of this section would increase in the area of the constant diameter d _{1 of} the worm shaft compared to the worm chambers. In order to compensate for such an increase in the volume of the screw chambers in the tapered section of the worm shaft, the screw conveyor in this area has a smaller pitch, whereby the distance x of the at least one helix is reduced in the axial direction and the volume of the screw chambers that of the area with constant Diameter d ₁ corresponds to the worm shaft.

Conveniently, the pitch of the at least one flight is selected in the range of the constant diameter d _{1 of} the worm shaft and in the tapered portion of the worm shaft such that all the screw chambers have the same volume. This ensures a constant feed of the cutting device at a constant pressure level of the food.

The cutting means preferably comprises a drum wall section with a plurality of cutting openings and a section of the screw path sweeping over these cutting openings. The cutting openings completely penetrate the drum wall section in the radial direction in all embodiments. With the help of the at least one flight, the food to be crushed is first moved in the axial direction and applied a corresponding pressure by congestion. This pressure works among other things also in the radial direction and ensures that the food at least partially protrudes into the cutting openings and is held there. The sweeping over the cutting openings portion of the screw flight of the same screw conveyor subsequently shears the inwardly from the cutting openings protruding food from. Since the screw chamber is always filled with food, the process described above continues continuously.

The essential advantage of this embodiment is that the device manages without knives and without discs, resulting in no metal abrasion and only extremely low wear. In addition, there is a sorting out of foreign substances such as cartilage, bone residues, bone fragments, tendons, rinds, plastics and other foreign bodies. In the devices known from the prior art, the majority of the foreign substances is also crushed and thus reaches the intended for consumption, crushed food. Consequently, the preferred embodiment of the device not only minces the food, but also separates desired ingredients from foreign matter originally contained in the food.

Preferably, the cutting openings are radially aligned in the drum wall section, thereby achieving a short contact time and reducing the risk of clogging of individual cutting openings.

The cutting openings may be formed as a stepped bore and / or as a conical bore with a smaller bore diameter and a larger bore diameter, wherein advantageously the smaller bore diameter is arranged on an inner side and the larger bore diameter on an outer side of the drum wall portion. The larger diameter portion of the respective cutting opening allows the food to spread therein, particularly when it is muscle meat. As a result, the temperature of the food during comminution is significantly reduced. Together with the features described below, heating of the foodstuff of only 1 ° C to 3 ° C can be realized, whereas the same food may already begin to cook in prior art devices, also for reasons of product quality and shelf life crushed food is to be avoided in any case.

To reduce the temperature of the food has been found to be particularly useful when the smaller bore diameter is 0.7 mm to 8 mm.

It makes sense that the larger bore diameter is 2.7 mm to 10 mm.

According to a favorable embodiment, the larger bore diameter is always 1.5 mm to 2.5 mm, more preferably selected from 1.8 mm to 2.2 mm, most preferably 2 mm larger than the smaller diameter drill.

Preferably, the smaller bore diameter to the larger bore diameter in the axial extent of the passage opening has a ratio of 1: 3 to 1: 5, particularly preferably 1: 4.

Advantageously, the plurality of cutting openings are arranged both in the axial direction and in the circumferential direction around the drum wall portion. This results in a maximization of the cutting performance, since the entire circumference of the drum wall section is available as a cutting surface. The cutting openings should be arranged in the axial direction and in the circumferential direction equidistant from each other.

In a section through the pressure housing along a central axis of the screw conveyor, the plurality of cutting openings in the axial extent of the drum wall portion may be concurrently covered by three screw chambers. This results in a sufficiently large volume of the screw chambers, which is always tracked to be comminuted food.

Conveniently, the at least one flight has a sharpened cutting edge at least in the sweeping section at its distal end. The cutting edge is located on the side facing away from the inlet radially oriented wall and an adjacent, axially aligned portion of the at least one flight. A sharpened cutting edge is understood to mean a cutting edge machined by grinding or whetting.

Conveniently, an annular space with a width of 5 microns to 15 microns, more preferably 10 microns is formed between the at least one flight and the drum wall. A larger sized annular space prevents a clean cutting of the food, as this would be pressed into the annulus and crushed there, which also takes place heating. With a smaller annular space even higher demands on the manufacturing tolerances of the screw conveyor and their storage to a To prevent abutment against the cylindrical drum wall.

It has been found to be particularly advantageous when the sharpened cutting edge and / or the drum wall are hardened. The hardening of steel is an increase of its mechanical resistance by purposeful change and transformation of its structure. It can be done, for example, by heat treatment with subsequent quenching (sudden cooling). Due to the hardened cutting edge and / or the hardened drum wall, the wear can be further reduced and the service life of the cutting device increased to a throughput of about 100,000 t.

Preferably, the drum wall is formed in the axial direction with a constant inner diameter. As a result, a continuous pressure build-up in the pressure housing is possible and it is avoided pocket formation, in which can be set uncut or partially comminuted food. In addition, a screw conveyor can be used, whose at least one screw thread in the axial direction within the drum wall has a constant outer diameter D ₁ . This can be produced particularly easily and precisely with regard to the desired dimensioning of the annular space.

According to a particularly preferred embodiment, the pressure housing at a first end portion opposite the second end portion on a closing element with a Ausschuböffnung, which is closable by means of a pressure-loaded flap. Foreign substances are removed from the pressure housing via the second end section and the terminating element attached to the drum wall. For this purpose, the closure element has a Ausschuböffnung through which the foreign substances pass. The pressure loaded closure flap permits adjustment of the internal pressure within the pressure housing because the pressure loaded closure flap pivots only from the closure position to an open position when the internal pressure of the food within the pressure housing is greater than a closure force applied by the pressure loaded closure flap. If the closing force of the pressure-loaded closure flap is increased, the pressure transferable to the food within the pressure housing also increases. If the closing force of the pressure-loaded flap is reduced, the pressure transferable to the food within the pressure housing decreases. With the help of the pressure-loaded flap, the device can be adjusted to different foods and their required pressure level.

It has been found to be advantageous if the end element in the extension of the pressure housing has a conically tapered interior, the interior opening ends in the Ausschuböffnung.

Conveniently, the screw conveyor is formed with a screw extension, which projects into the interior. The screw extension should then be formed complementary to the shape of the interior. In the case of a conically tapering interior, the screw extension expediently also runs conically in the direction of the discharge opening. In this area, the auger extension of the screw conveyor no longer performs crushing work, but merely conveys the foreign substances accumulated in the interior of the closing element in the direction of the discharge opening. The annular space between the screw extension and closing element is therefore designed to be larger than between drum wall section and überstreichendem section.

Preferably, the closure flap is held in a closed position by means of a spring element. With the help of the spring element can be particularly accurately adjust the closing force of the pressure-loaded flap or vary depending on the food to be crushed.

The spring element may particularly preferably be a pneumatic pressure cylinder. Due to the compressible medium enclosed in the pneumatic pressure cylinder, the presettable closing force of the pressure-loaded closure flap can be influenced by presetting the internal pressure in the pneumatic pressure cylinder. A higher set internal pressure in the pneumatic pressure cylinder provides a greater closure force of the closure flap, a lower set internal pressure for a lower closure force of the closure flap.

Between the pneumatic pressure cylinder and the closure flap can be rotatably mounted a coupling rod, which allows a fixed attachment of a portion of the pneumatic pressure cylinder spaced from the Ausschuböffnung.

Advantageously, a chute inclined to the pressure housing is arranged below the discharge opening for foreign substances. About this slide enter the foreign matter in a separate funding or collection container, which allows a separate removal of foreign matter, separated from the crushed food.

For a better understanding of the invention will be explained in more detail with reference to four figures. It show the

1 a cross section of the device according to the invention;

2 an enlarged side view of a screw conveyor;

3 : a pre-head view of the closing element with the flap open and

4 FIG. 2: a cross section through the drum wall with detailed views of the cutting openings according to a first and second embodiment. FIG.

The 1 shows a cross section of the device according to the invention with a pressure housing 20 comprising a cylindrical drum wall 30 at a first end section 21a an open in the axial direction of the inlet opening 22 for charging the device with a food. The pressure housing 20 also includes a closure element 23 , which at a second end portion 21b end to the drum wall 30 attached and thus on the opposite side of the inlet opening 22 is arranged.

Centric in the drum wall 30 is a screw conveyor 40 arranged, which one of the first end portion 21a located centering sleeve 37 and one at the second end portion 21b in the drum wall 30 used centering insert 38 is rotatably mounted. The centering sleeve 37 is at the Vorkopfseite to the drum wall 30 scheduled and has a breakthrough 37a which is coaxial with a center axis M of the screw conveyor 40 is formed (see 2 ). About the breakthrough 37a is the screw conveyor 40 connected directly or indirectly non-rotatably with a motor drive, not shown here. In the case of an indirect connection can / can, for example, between the drive and the screw conveyor 40 one or more for reasons of clarity also omitted feed screws be interposed.

Between the centering sleeve 37 and the centering insert 38 has the screw conveyor 40 a spiral around a centric worm shaft 45 spiraling helix 41 on, the outer diameter D ₁ in an overlapping region with the drum wall 30 is constant and is chosen only slightly smaller than over its entire axial length also constant internal diameter D _{i of} the drum wall 30 (please refer 4 ). The outer diameter D _{1 of} the flight 41 the screw conveyor 40 and the inner diameter D _i together form an annular space, which is 0.01 mm in the illustrated embodiment. Between at an axial distance x (see 2 ) adjacent sections of the flight 41 is each a snail chamber 42 formed, which serves to receive the food, wherein the food with rotating auger 40 through the helix 41 starting from the inlet opening 22 in the direction of the second end portion 21b is axially advanced.

The drum wall 30 points to her the second end portion 21b adjacent side a drum wall section 31 on, in which the drum wall 30 from a variety of cutting openings 32 is broken through, which is completely from an inside 35 to an outside 36 the drum wall 30 run. The cutting openings 32 of the drum wall section 31 be especially in connection with 4 explained in more detail, are distributed uniformly in the circumferential direction and extend in the axial direction at least over half the length of the drum wall 30 ,

In the presentation of the 4 are exemplary of two embodiments of the cutting openings 32 shown, wherein in the enlarged, left figure, the cutting opening 32 as a stepped bore 33 is trained. The stepped bore 33 points you to the inside 35 adjacent, smaller diameter D _Bmin, pointing towards the outside 36 discontinuous to the larger diameter D _{Bmax is} widened. Both the smaller diameter D _Bmin and _Bmax, the larger diameter D is carried out each cylindrical, and both together form the stepped bore 33 ,

In the enlarged, right picture of the 4 is an alternative embodiment of a cutting opening 32 shown as a conical bore 34 is trained. At the conical bore 34 The smaller diameter D _Bmin also _opens on the inside 35 the drum wall 30 and the larger diameter D _Bmax on the outside 36 ; the conical bore 34 However, it has a steady opening angle.

Both embodiments with a stepped bore 33 or a conical bore 34 have in common that in the area of the inside 35 the smaller bore diameter D _Bmin and in the area of the outside 36 the larger drilling diameter D _{Bmax is} arranged. The larger bore diameter D _Bmax allows the food to expand in the radially larger, larger diameter drill diameter D _Bmax , which causes, in particular, a small increase in temperature during the grinding of muscle meat. For manufacturing reasons, it is preferred in the drum wall section 31 either stepped holes 33 or conical holes 34 contribute. However, it is also possible in the drum wall section 31 both stepped holes 33 as well as conical bores 34 train.

The 1 also shows one from the drum wall section 31 and the helix 41 formed cutting means 10 wherein the drum wall section 31 with a sweeping section 43 of the helix 41 interacts and the food from the sweeping section 43 over the cutting openings 32 transported, pressed into this and cut off there. This is the sweeping section 43 of the helix 41 with a sharpened cutting edge 44 Mistake. The sharpened cutting edge 44 is in installation position of the screw conveyor 40 between the radially outer portion and the second end portion 21 facing side of the flight 41 arranged.

The sweeping section 43 the screw conveyor 40 is with a bigger slope 47 formed and also has a constant diameter d _{1 of} the worm shaft 45 on. Between the sweeping section 43 and the first end portion 21a reduces the diameter of the worm shaft 45 in a tapered section 46 continuously down to the smaller diameter d ₂ . In the area of the tapered section 46 indicates the helix 41 a smaller slope 48 on. By reducing to the smaller slope 48 becomes the volume of the local snail chambers 42 in comparison to those in the range of the constant diameter d _{1 of} the worm shaft 45 located snail chambers 42 held constant and thereby due to the smaller diameter d _{2 of} the worm shaft 45 in the radial direction enlarged volume of the screw chambers 42 compensated.

The helix 41 is in the transitional area of smaller slope 48 to a greater slope 47 interrupted.

Non-cutting food leaves as an impurity in the axial direction of the drum wall 30 at its second end portion 21b , In this case, the foreign substances by the provided in the axial direction with openings centering 38 pushed through and enter an interior 26 of the final element 23 one. In the interior 26 also protrudes a snail extension 49 the screw conveyor 40 , which is on the from the sweeping section 43 opposite side of the centering insert 38 is trained. The snail process 49 ends in the axial direction before a Ausschuböffnung 24 attached to the distal end of the pressure housing 20 in the final element 23 is formed and over which the foreign substances, the pressure housing 20 leave.

The discharge opening 24 is by means of a pressure-loaded flap 25 closable. As a result, a pressure build-up of the food within the drum wall 30 especially in the area of the cutting means 10 controlled. The pressure-loaded flap 25 is of a spring element in the form of a pressure cylinder 27 via a coupling rod 28 as long as in one the Ausschuböffnung 24 held closing position until the of the screw conveyor 40 on the impurities transferred pressure increases so that the shutter 25 from the foreign substances against one from the printing cylinder 27 applied closing force is pushed and the foreign matter from the Ausschuböffnung 24 fall out. Preferably, an inclined chute protrudes 29 until under the discharge opening 24 which supplies the foreign substances to a conveying means or collecting container, not shown.

After a discharge of foreign matter through the Ausschuböffnung 24 reduces the internal pressure within the interior 26 first and the impression cylinder 27 applied closing force is temporarily greater than the pressure prevailing in the interior of the foreign substances. The flap 25 therefore moves back into a Ausschuböffnung 24 closing position.

The printing cylinder 27 includes a cylinder housing 27a on, which by means of a support element 27b fixed to the closing element 23 attacks. In the presentation of the 1 is one from the cylinder housing 27a outstanding piston rod 27c in an extended position, leaving the coupling rod 28 the flap 25 in one the Ausschuböffnung 24 has brought covering position. In the pre-head view of 3 is the flap 25 pivoted in an open position and thereby has the piston rod 27c in the cylinder housing 27a inserted.

LIST OF REFERENCE NUMBERS

10

cutting means

20

pressure housing

21a

first end section

21b

second end section

22

inlet opening

23

termination element

24

out opening

25

flap

26

Interior graduation element

27

Spring element, impression cylinder

27a

cylinder housing

27b

supporting member

27c

piston rod

28

coupling rod

29

slide

30

drum wall

31

Drum wall section

32

cutting openings

33

stepped bore

34

conical bore

35

inside

36

outside

37

centering

37a

breakthrough

38

centering

40

Auger

41

snail's pace

42

screw chamber

43

sweeping section

44

sharpened cutting edge

45

worm shaft

46

tapered section of the worm shaft

47

greater slope

48

smaller slope

49

Screw extension

50

annulus

d ₁

constant ∅ worm shaft

d ₂

smaller ∅ worm shaft

D ₁

Outer diameter helix

D _Bmax

larger bore diameter cutting opening

D _Bmin

smaller bore diameter cutting opening

D _i

Inner diameter drum wall

M

Central axis screw conveyor

x

axial distance worm gear

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 102006034150 A1 [0003]

Claims (15)

Device for mincing food, comprising a cutting means ( 10 ) and a pressure housing ( 20 ) with a cylindrical drum wall ( 30 ), wherein the pressure housing ( 20 ) at a first end portion ( 21a ) with an inlet opening ( 22 ) formed for the food and in the pressure housing ( 20 ) a screw conveyor ( 40 ) is rotatably mounted, the more by at least one flight ( 41 ) separate slug chambers ( 42 ), characterized in that the screw conveyor ( 40 ) by the cutting means ( 10 ) a worm shaft ( 45 ) having a constant diameter (d ₁ ) to which a tapered section ( 46 ) of the worm shaft ( 45 ) in the direction of the first end section ( 21a ) up to the smaller diameter (d ₂ ). Device according to claim 1, characterized in that the at least one flight ( 41 ) in the region of the constant diameter (d ₁ ) of the worm shaft ( 45 ) a larger slope ( 47 ) and in the incoming section ( 46 ) of the worm shaft ( 45 ) a smaller slope ( 48 ) having. Apparatus according to claim 1 or 2, characterized in that the slope of the at least one flight ( 41 ) in the region of the constant diameter (d ₁ ) of the worm shaft ( 45 ) and in the incoming section ( 46 ) of the worm shaft ( 45 ) are selected such that all snail chambers ( 42 ) have the same volume. Device according to one of claims 1 to 3, characterized in that the cutting means ( 10 ) from a drum wall section ( 31 ), in which several cutting openings ( 32 ) are arranged, and the cutting openings ( 32 ) sweeping section ( 43 ) of the at least one flight ( 41 ) is formed. Apparatus according to claim 4, characterized in that the cutting openings ( 32 ) as a stepped bore ( 33 ) and / or as a conical bore ( 34 ) are formed with a smaller bore diameter (D _Bmin ) and a larger bore diameter (D _Bmax ). Apparatus according to claim 5, characterized in that the smaller bore diameter (D _Bmin ) on an inner side ( 35 ) and the larger bore diameter (D _Bmax ) on an outer side ( 36 ) of the drum wall section ( 31 ) is arranged. Device according to one of claims 4 to 6, characterized in that the at least one flight ( 41 ) at least in the sweeping section ( 43 ) at its distal end a sharpened cutting edge ( 44 ) having. Device according to one of claims 1 to 7, characterized in that between the at least one screw thread ( 41 ) and the drum wall ( 30 ) an annulus ( 50 ) is formed with a width of 5 microns to 15 microns, more preferably 10 microns. Apparatus according to claim 7 or 8, characterized in that the sharpened cutting edge ( 44 ) and / or the drum wall ( 30 ) are cured. Device according to one of claims 1 to 9, characterized in that the drum wall ( 30 ) is formed in the axial direction with a constant inner diameter (D _i ). Device according to one of claims 1 to 10, characterized in that the at least one screw thread ( 41 ) in the axial direction within the drum wall ( 30 ) has a constant outer diameter (D ₁ ). Device according to one of claims 1 to 11, characterized in that the pressure housing ( 20 ) at a first end portion ( 21a ), second end section (FIG. 21b ) a conclusion element ( 23 ) with a discharge opening ( 24 ), which by means of a pressure-loaded flap ( 25 ) is closable. Apparatus according to claim 12, characterized in that the closing element ( 23 ) in extension of the pressure housing ( 20 ) a tapered interior ( 26 ), wherein the interior ( 26 ) end in the Ausschuböffnung ( 24 ) opens. Apparatus according to claim 13, characterized in that the screw conveyor ( 40 ) with a screw process ( 49 ) is formed, which in the interior ( 26 ) protrudes. Device according to one of claims 12 to 14, characterized in that the closure flap ( 25 ) by means of a spring element ( 47 ) is held in a closed position.

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