Double-power one-way movement bone nutrition extractor
[ technical field ] A method for producing a semiconductor device
The invention relates to the technical field of dining auxiliary tools, in particular to the technical field of a double-power one-way movement bone nutrition extractor.
[ background of the invention ]
Along with the development of economy, the consumption of people to meat is more and more, the meat can provide much energy with the body, meanwhile, bones are rich in abundant nutrient elements and very useful for human bodies, the existing method for extracting nutrient substances in the bones is to boil the bones for a long time, the nutrient substances in the bones are difficult to be fully boiled due to the relatively sealed environment of the nutrient substances in the bones, meanwhile, when people eat spareribs in life, the bones are directly thrown away as garbage after meat on the bones is used up, so that very large waste is caused, no tool for effectively extracting the nutrient substances in the bones is available for personal dining in families and restaurants at present, and trace elements in the bones cannot be effectively utilized by the human bodies.
[ summary of the invention ]
The invention aims to solve the problems in the prior art, and provides a double-power one-way motion bone nutrition extractor which can enable a tool to roll and slide in a one-way mode, enables nutrient substances to be extruded out from the other end by continuously rolling and extruding a bone from one end, is convenient to use, is suitable for personal dining and is beneficial to fully utilizing the nutrient substances in the bone.
In order to achieve the purpose, the invention provides a double-power one-way motion bone nutrition extractor which comprises a main handle seat, a main rotating roller, a one-way rotation power part, a one-way sliding power part and a main sliding roller, wherein the main rotating roller is arranged at the end part of the main handle seat, the one-way rotation power part which drives the main rotating roller to rotate in a one-way mode is arranged on the main handle seat at the side part of the main rotating roller, the one-way sliding power part which slides in a one-way mode is arranged on the main handle seat, and the main sliding roller which is matched with the main rotating roller to extrude materials is arranged on the one-way sliding power part.
Preferably, the unidirectional rotary power part comprises a unidirectional rotary motion executing part and a rotary power driven gear, the rotary power driven gear is fixedly arranged at the end part of the main rotating roller, and the unidirectional rotary motion executing part is in unidirectional transmission engagement with the rotary power driven gear. A
Preferably, the unidirectional rotation motion executing part comprises a unidirectional rotation power seat, a unidirectional rotation power handle, a unidirectional rotation pawl pin and a unidirectional rotation compression spring, one end of the unidirectional rotation power handle is fixedly arranged on the unidirectional rotation power seat, the unidirectional rotation pawl pin is inserted into one end of the unidirectional rotation power handle connected with the unidirectional rotation power seat, and the unidirectional rotation compression spring for pushing the unidirectional rotation pawl pin to the rotation power driven gear is arranged between one end of the unidirectional rotation pawl pin positioned in the unidirectional rotation power handle and the unidirectional rotation power handle.
Preferably, one side of one end of the one-way rotation pawl pin, which is in contact with the rotation power driven gear, is provided with a chamfer angle.
Preferably, the side part of the main handle seat is provided with a unidirectional sliding power tooth.
Preferably, the unidirectional sliding power part comprises a sliding seat, a sliding power gear and a unidirectional sliding motion executing part, the sliding power gear and the unidirectional sliding motion executing part are respectively hinged on the sliding seat, the unidirectional sliding motion executing part is meshed with the sliding power gear, and the sliding power gear is meshed with the unidirectional sliding power gear.
Preferably, the unidirectional sliding motion executing part has the same structure as the unidirectional rotating motion executing part.
Preferably, the unidirectional sliding motion executing part comprises a unidirectional sliding power seat, a unidirectional sliding power handle, a rotary pawl plate, a pressure fit hanging body, a pressure fit spring and a rotary power driven gear, one end of the unidirectional sliding power handle is fixedly arranged on the unidirectional sliding power seat, the upper side and the lower side of the unidirectional sliding power seat are respectively provided with the rotary pawl plate in a hinged mode, the rotary pawl plate and the unidirectional sliding power seat are respectively provided with the pressure fit hanging body, the pressure fit spring is connected between the pressure fit hanging bodies, and the straight line where the fixed points at the two ends of the pressure fit spring are located on the side portion of the hinged point of the corresponding rotary pawl plate on the unidirectional sliding power seat.
The invention has the beneficial effects that: according to the bone crushing and extruding tool, the main handle seat, the main rotating roller, the unidirectional rotating power part, the unidirectional sliding power part and the main sliding roller are applied to the bone crushing and extruding tool, so that the tool can be extruded from the other end through unidirectional rolling and sliding and continuous rolling extrusion of bones from one end, the use is convenient, the bone crushing and extruding tool is suitable for personal dining, the nutrient substances in the bones can be fully utilized, and the nutrition of a human body is more balanced.
The features and advantages of the present invention will be described in detail by embodiments in conjunction with the accompanying drawings.
[ description of the drawings ]
FIG. 1 is a front view of a dual power one-way motion bone nutrition extractor according to an embodiment of the present invention;
FIG. 2 is a right side view of a dual power unidirectional motion bone nutrition extractor according to an embodiment of the present invention;
FIG. 3 is a front perspective view of a dual power one-way motion bone nutrition extractor according to an embodiment of the present invention;
FIG. 4 is a rear perspective view of a dual power one-way motion bone nutrition extractor according to an embodiment of the present invention;
FIG. 5 is a front view of a dual power unidirectional motion bone nutrition extractor according to a second embodiment of the present invention;
FIG. 6 is a right side view of a dual power unidirectional exercise bone nutrition extractor of the second embodiment of the present invention;
FIG. 7 is a front perspective view of a second embodiment of a dual power one-way motion bone nutrition extractor of the present invention;
FIG. 8 is a rear perspective view of a second embodiment of a dual power one-way motion bone nutrition extractor of the present invention;
FIG. 9 is a perspective view of a second embodiment of the unidirectional sliding motion actuator;
FIG. 10 is a right side view of the second embodiment of the unidirectional sliding motion actuator;
FIG. 11 is a right side sectional view of the unidirectional rotary motion actuator;
fig. 12 is a perspective view of the unidirectional rotary motion performing part.
In the figure: 1-main handle seat, 2-main rotating roller, 3-unidirectional rotation power part, 31-unidirectional rotation motion executing part, 311-unidirectional rotation power seat, 312-unidirectional rotation power handle, 313-unidirectional rotation pawl pin, 314-unidirectional rotation pressing spring, 32-rotation power driven gear, 4-unidirectional sliding power part, 41-sliding seat, 42-sliding power gear, 43-unidirectional sliding motion executing part, 431-unidirectional sliding power seat, 432-unidirectional sliding power handle, 433-rotation pawl plate, 434-pressure joint hanging body, 435-pressure joint spring and 5-main sliding roller.
[ detailed description ] embodiments
In the first embodiment, referring to fig. 1-4, 11 and 12, the double-power unidirectional-motion bone nutrition extractor of the present invention comprises a main handle seat 1, a main rotating roller 2, a unidirectional rotation power part 3, a unidirectional sliding power part 4 and a main sliding roller 5, wherein the main rotating roller 2 is arranged at an end of the main handle seat 1, the unidirectional rotation power part 3 which unidirectionally drives the main rotating roller 2 to rotate is arranged on the main handle seat 1 at a side part of the main rotating roller 2, the unidirectional sliding power part 4 which unidirectionally slides is arranged on the main handle seat 1, and the main sliding roller 5 which is matched with the main rotating roller 2 to extrude materials is arranged on the unidirectional sliding power part 4. The unidirectional rotation power part 3 comprises a unidirectional rotation motion executing part 31 and a rotation power driven gear 32, the rotation power driven gear 32 is fixedly arranged at the end part of the main rotating roller 2, and the unidirectional rotation motion executing part 31 is in unidirectional transmission engagement with the rotation power driven gear 32. The unidirectional rotation motion executing part 31 includes a unidirectional rotation power base 311, a unidirectional rotation power handle 312, a unidirectional rotation pawl pin 313 and a unidirectional rotation pressing spring 314, one end of the unidirectional rotation power handle 312 is fixedly arranged on the unidirectional rotation power base 311, one end of the unidirectional rotation power handle 312 connected with the unidirectional rotation power base 311 is inserted with the unidirectional rotation pawl pin 313, and the unidirectional rotation pressing spring 314 for pushing the unidirectional rotation pawl pin 313 to the rotation power driven gear 32 is arranged between one end of the unidirectional rotation pawl pin 313 located in the unidirectional rotation power handle 312 and the unidirectional rotation power handle 312. One side of one end of the one-way rotation pawl pin 313, which is in contact with the rotation power driven gear 32, is provided with a chamfer angle. The lateral part of the main handle seat 1 is provided with unidirectional sliding power teeth. The unidirectional sliding power part 4 comprises a sliding seat 41, a sliding power gear 42 and a unidirectional sliding motion executing part 43, the sliding power gear 42 and the unidirectional sliding motion executing part 43 are respectively hinged on the sliding seat 41, the unidirectional sliding motion executing part 43 is meshed with the sliding power gear 42, and the sliding power gear 42 is meshed with the unidirectional sliding power gear. The unidirectional sliding motion executing part 43 has the same structure as the unidirectional rotary motion executing part 31.
The working process of the invention is as follows:
in the working process of the double-power unidirectional-motion bone nutrition extractor, a unidirectional rotation motion execution part 31 and a unidirectional sliding motion execution part 43 have the same structure, one end or the middle part of a bone is arranged between a main rotating roller 2 and a main sliding roller 5, during the working process of the unidirectional sliding motion execution part 43, the unidirectional rotation power handle 312 is rotated to drive a unidirectional rotation pawl pin 313 to reciprocate to drive a sliding power gear 42 to move in a unidirectional way, the sliding power gear 42 rolls on a unidirectional sliding power tooth on a main handle seat 1, and finally the purpose that the main sliding roller 5 is close to the main rotating roller 2 is achieved, the bone is flattened through the main rotating roller 2 and the main sliding roller 5, and during the working process of the unidirectional rotation motion execution part 31: the execution part 31 drives the rotary power driven gear 32 to rotate through reciprocating rotation and unidirectional rotation, the rotary power driven gear 32 drives the main rotating roller 2 to rotate, the main rotating roller 2 and the main sliding roller 5 rotate, bones are pressed from one side to the other side, and finally nutrient substances in the bones are extruded out.
According to the double-power one-way motion bone nutrition extractor, the main handle seat 1, the main rotating roller 2, the one-way rotating power part 3, the one-way sliding power part 4 and the main sliding roller 5 are applied to a bone crushing and extruding tool, so that the tool can roll and slide in a single direction, and nutrient substances are extruded from one end of a bone through continuous rolling and extruding from the other end.
In the second embodiment, referring to fig. 5-12, the double-power unidirectional-motion bone nutrition extractor of the present invention comprises a main handle seat 1, a main rotating roller 2, a unidirectional rotation power part 3, a unidirectional sliding power part 4 and a main sliding roller 5, wherein the main rotating roller 2 is disposed at an end of the main handle seat 1, the unidirectional rotation power part 3 for driving the main rotating roller 2 to rotate in a unidirectional manner is disposed on the main handle seat 1 at a side of the main rotating roller 2, the unidirectional sliding power part 4 for unidirectional sliding is disposed on the main handle seat 1, and the main sliding roller 5 for extruding materials in cooperation with the main rotating roller 2 is disposed on the unidirectional sliding power part 4. The unidirectional rotation power part 3 comprises a unidirectional rotation motion executing part 31 and a rotation power driven gear 32, the rotation power driven gear 32 is fixedly arranged at the end part of the main rotating roller 2, and the unidirectional rotation motion executing part 31 is in unidirectional transmission engagement with the rotation power driven gear 32. The unidirectional rotation motion executing part 31 includes a unidirectional rotation power base 311, a unidirectional rotation power handle 312, a unidirectional rotation pawl pin 313 and a unidirectional rotation pressing spring 314, one end of the unidirectional rotation power handle 312 is fixedly arranged on the unidirectional rotation power base 311, one end of the unidirectional rotation power handle 312 connected with the unidirectional rotation power base 311 is inserted with the unidirectional rotation pawl pin 313, and the unidirectional rotation pressing spring 314 for pushing the unidirectional rotation pawl pin 313 to the rotation power driven gear 32 is arranged between one end of the unidirectional rotation pawl pin 313 located in the unidirectional rotation power handle 312 and the unidirectional rotation power handle 312. One side of one end of the one-way rotation pawl pin 313, which is in contact with the rotation power driven gear 32, is provided with a chamfer angle. The lateral part of the main handle seat 1 is provided with unidirectional sliding power teeth. The unidirectional sliding power part 4 comprises a sliding seat 41, a sliding power gear 42 and a unidirectional sliding motion executing part 43, the sliding power gear 42 and the unidirectional sliding motion executing part 43 are respectively hinged on the sliding seat 41, the unidirectional sliding motion executing part 43 is meshed with the sliding power gear 42, and the sliding power gear 42 is meshed with the unidirectional sliding power gear. The unidirectional sliding motion executing part 43 comprises a unidirectional sliding power seat 431, a unidirectional sliding power handle 432, a rotating pawl plate 433, a pressure fit hanging body 434, a pressure fit spring 435 and a rotating power driven gear 32, one end of the unidirectional sliding power handle 432 is fixedly arranged on the unidirectional sliding power seat 431, the upper side and the lower side of the unidirectional sliding power seat 431 are respectively and hingedly provided with the rotating pawl plate 433, the rotating pawl plate 433 and the unidirectional sliding power seat 431 are respectively provided with the pressure fit hanging body 434, the pressure fit spring 435 is connected between the pressure fit hanging bodies 434, and the straight lines of the fixing points at the two ends of the pressure fit spring 435 are positioned at the side part of the hinge point of the corresponding rotating pawl plate 433 on the unidirectional sliding power seat 431.
The working process of the invention is as follows:
in the working process of the double-power unidirectional-motion bone nutrition extractor, one end or the middle part of a bone is firstly placed between a main rotating roller 2 and a main sliding roller 5, a reciprocating-rotation unidirectional-sliding-motion executing part 4 drives a sliding power gear 42 to rotate, the main sliding roller 5 is close to the main rotating roller 2 through the matching of the sliding power gear 42 and a unidirectional-sliding power tooth at the side part of a main handle seat 1, the main rotating roller 2 and the main sliding roller 5 are extruded, the aim of enabling the main sliding roller 5 to be close to the main rotating roller 2 is finally achieved, and the bone is flattened through the main rotating roller 2 and the main sliding roller 5. The one-way sliding motion executing part 43 works as follows: one of the rotary pawl plates 433 is attached to the unidirectional sliding power handle 432 in a turnover mode, and the straight lines where the two ends of the pressure attaching spring 435 are located on one side of a hinge point of the rotary pawl plate 433 and the unidirectional sliding power seat 431, so that when the fixed position of the pressure attaching spring 435 on the rotary pawl plate 433 is located on one side of the hinge point of the rotary pawl plate 433 and the unidirectional sliding power seat 431, the pressure attaching spring 435 generates pressure for pressing the rotary pawl plate 433 to the side where the rotary pawl plate is located, one rotary pawl plate 433 is attached to the unidirectional sliding power handle 432 in a attaching mode, the other rotary pawl 433 is attached to the sliding power gear 42, the rotary pawl plate 433 reciprocates to drive the sliding power gear 42 to move in a unidirectional mode, and when the sliding power gear 42 needs to move in a reverse direction towards the other rotary pawl, the unidirectional sliding power handle 432 is attached. In the working process of the unidirectional rotation movement executing part 31, the unidirectional rotation power handle 312 is rotated, so that the unidirectional rotation power handle 312 drives the unidirectional rotation pawl pin 313 to reciprocate to drive the unidirectional rotation power driven gear 32 to perform unidirectional movement, the rotational power driven gear 32 drives the main rotating roller 2 to rotate, the main rotating roller 2 and the main sliding roller 5 extrude and roll, bones are pressed from one side to the other side, and finally nutrient substances in the bones are extruded.
According to the double-power one-way motion bone nutrition extractor, the main handle seat 1, the main rotating roller 2, the one-way rotating power part 3, the one-way sliding power part 4 and the main sliding roller 5 are applied to a bone crushing and extruding tool, so that the tool can roll and slide in a single direction, and nutrient substances are extruded from one end of a bone through continuous rolling and extruding from the other end.
The above embodiments are illustrative of the present invention, and are not intended to limit the present invention, and any simple modifications of the present invention are within the scope of the present invention.