A system to make a bread loaf includes means for moving continuously pans along a predetermined path, each pan including at least one cavity sized and configured for making a bread loaf. Means conditioning continuously a batch of unconditioned dough reduces the size of air pockets therein to form a conditioned dough. Means continuously extrude the batch of conditioned dough at a controlled volumetric feed rate and at a controlled pressure to provide a constant stream of conditioned dough that is continuously cut into individual packets. The entire batch is converted into individual packets of conditioned dough corresponding to a predetermined number of bread loaves to be produced from the batch, with all the packets deposited individually in cavities of the pans.

An automatic table-top machine (10) for kneading and extruding pasta, comprising: a machine body (11), which includes a vertical wall (11.1); a dough forming tank (12), detachably fixed in a cantilever fashion on the outer face (11.10) of said vertical wall (11.1) of the machine body (11), wherein said tank (12) comprises a fixed rear outer edge (12.1), juxtaposed against said outer face (11.10) of said vertical wall (11.1); a plurality of detachable connection means (13; 13.3, 13.4), wherein each of said detachable connection means (13; 13.3, 13.4) comprises a threaded supporting rod (13.1), which has a horizontal axis, is fixed and projects externally with respect to the outer face (11.10) of said vertical wall (11.1) of the machine body (11) and is arranged externally with respect to said rear outer edge (12.1) of said tank (12);
characterized in that each of said detachable connection means (13; 13.3, 13.4) further comprises: a fixed pin (13.2), which has a horizontal axis, projects externally with respect to said outer face (11.10) of said vertical wall (11.1) of the machine body (11), and is arranged externally to said tank (12); a removable fixing dowel (14), configured as a block having: at least one supporting face (14.1), which is juxtaposed at least partly against said outer face (11.10) of said vertical wall (11.1) of the machine body (11); a first end portion (14.2), which can be superimposed and/or juxtaposed with respect to a corresponding portion of said rear outer edge (12.1) of said tank (12); a slotted through hole (14.3) provided in said dowel (14), wherein: a first semi-cylindrical inner face (14.31) of said slotted through hole (14.3) is arranged at, or in proximity to, said first end portion (14.2) of said dowel (14) and a second semi-cylindrical inner face (14.32) of said slotted through hole (14.3) is distal with respect to said first end portion (14.2) of said dowel (14); said slotted through hole (14.3) is passed through by the free end of said threaded rod (13.1) and is configured to juxtapose at least a part of said free end of said threaded rod (13.1) against said second semi-cylindrical inner face (14.32), when said first end portion (14.2) of said dowel (14) is superimposed and/or juxtaposed with respect to a corresponding portion of said rear outer edge (12.1) of said tank (

The disclosure discloses a bevel planetary gear mechanism applied to a stand mixer, including a center bevel gear (2), a first bevel planetary gear (10), a second bevel planetary gear (3), a third bevel planetary gear (4), an internal bevel gear (5) and a bevel planetary gear bracket (11), wherein, the center bevel gear (2) is mounted on a spindle (1); the first bevel planetary gear (10), the second bevel planetary gear (3) and the third bevel planetary gear (4) are all engaged with the center bevel gear (2); the internal bevel gear (5) surrounds the first bevel planetary gear (10), the second bevel planetary gear (3) and the third bevel planetary gear (4) and are engaged with such three gears. By using the bevel planetary gear mechanism provided by the disclosure, the stand mixer has a pitched kneading hook, thereby improving the kneading effect of the stand mixer.

The disclosure discloses a bevel planetary gear mechanism applied to a stand mixer, including a center bevel gear (2), a first bevel planetary gear (10), a second bevel planetary gear (3), a third bevel planetary gear (4), an internal bevel gear (5) and a bevel planetary gear bracket (11), wherein, the center bevel gear (2) is mounted on a spindle (1); the first bevel planetary gear (10), the second bevel planetary gear (3) and the third bevel planetary gear (4) are all engaged with the center bevel gear (2); the internal bevel gear (5) surrounds the first bevel planetary gear (10), the second bevel planetary gear (3) and the third bevel planetary gear (4) and are engaged with such three gears. By using the bevel planetary gear mechanism provided by the disclosure, the stand mixer has a pitched kneading hook, thereby improving the kneading effect of the stand mixer.

The disclosure discloses a bevel planetary gear mechanism applied to a stand mixer, including a center bevel gear (2), a first bevel planetary gear (10), a second bevel planetary gear (3), a third bevel planetary gear (4), an internal bevel gear (5) and a bevel planetary gear bracket (11), wherein, the center bevel gear (2) is mounted on a spindle (1); the first bevel planetary gear (10), the second bevel planetary gear (3) and the third bevel planetary gear (4) are all engaged with the center bevel gear (2); the internal bevel gear (5) surrounds the first bevel planetary gear (10), the second bevel planetary gear (3) and the third bevel planetary gear (4) and are engaged with such three gears. By using the bevel planetary gear mechanism provided by the disclosure, the stand mixer has a pitched kneading hook, thereby improving the kneading effect of the stand mixer.

A kneading device 1 comprising an inner cone 2 and an outer cone 3, wherein the inner cone 2 and the outer cone 3 defines a space 4 in between the inner cone and the outer cone; from a horizontal plane the inner cone 2 inclines and forms an angle ic; from the same horizontal plane the outer cone 3 inclines and forms an angle oc; where the inner cone 2 has an opening in a bottom of the inner cone 2; where both the inner cone 2 and the outer cone 3 continue vertically in an inner extension 5 and an outer extension 6, respectively, wherein a space in between the inner extension 5 and the outer extension 6 is a gap E; where scraping wings 7 extend from a center portion 8 of the kneading device 1 and through the inner cone 2 and the outer cone 3 and towards, but not fixated to, an inner wall 9 of the outer cone 3; and where the outer cone 3 inclines more than the inner cone 2, when viewed from the horizontal plane, so that angle oc>angle ic.

A kneading device 1 comprising an inner cone 2 and an outer cone 3, wherein the inner cone 2 and the outer cone 3 defines a space 4 in between the inner cone and the outer cone; from a horizontal plane the inner cone 2 inclines and forms an angle ic; from the same horizontal plane the outer cone 3 inclines and forms an angle oc; where the inner cone 2 has an opening in a bottom of the inner cone 2; where both the inner cone 2 and the outer cone 3 continue vertically in an inner extension 5 and an outer extension 6, respectively, wherein a space in between the inner extension 5 and the outer extension 6 is a gap E; where scraping wings 7 extend from a center portion 8 of the kneading device 1 and through the inner cone 2 and the outer cone 3 and towards, but not fixated to, an inner wall 9 of the outer cone 3; and where the outer cone 3 inclines more than the inner cone 2, when viewed from the horizontal plane, so that angle oc>angle ic.