阅读说明：本技术 一种骨伤科用自动石膏固定骨骼设备 (Orthopedics is with fixed skeleton equipment of automatic gypsum ) 是由 孙凤英 于 2021-09-28 设计创作，主要内容包括：本发明涉及一种石膏固定骨骼设备,更具体的说是一种骨伤科用自动石膏固定骨骼设备,包括传送固定机构、注入联动机构、冷却联动机构,设备能够辅助患者将患者受伤的骨骼传送至定型模具型腔中,设备能够将定型磨具型腔密闭并将液态粘稠状石膏传送至磨具型腔内,设备能够在液态粘稠状石膏填充满磨具型腔时将多余的液态粘稠状石膏传送出设备以便操作人员确认磨具状态,设备能够对定型磨具型腔的上部分行进水冷却,设备能够对定型磨具型腔下部分进行风冷却,传送固定机构与注入联动机构连接,注入联动机构与冷却联动机构连接,冷却联动机构与传送固定机构连接。(The invention relates to a gypsum bone fixing device, in particular to an automatic gypsum bone fixing device for orthopedics department, which comprises a conveying and fixing mechanism, an injection linkage mechanism and a cooling linkage mechanism, wherein the device can assist a patient to convey injured bones of the patient to a cavity of a sizing die, equipment can be airtight and convey liquid thick form gypsum to the grinding apparatus die cavity with design grinding apparatus die cavity, equipment can convey unnecessary liquid thick form gypsum out of equipment so that operating personnel confirms the grinding apparatus state when liquid thick form gypsum fills up full of the grinding apparatus die cavity, equipment can carry out water cooling to the upper portion of design grinding apparatus die cavity, equipment can carry out the forced air cooling to design grinding apparatus die cavity lower part, conveying fixed establishment is connected with the injection link gear, the injection link gear is connected with cooling link gear, cooling link gear is connected with conveying fixed establishment.)

1. The utility model provides a bone equipment is fixed with automatic gypsum to orthopedics department, includes conveying fixed establishment (1), pours into link gear (2), cooling link gear (3), its characterized in that: the conveying and fixing mechanism (1) is connected with the injection linkage mechanism (2), the injection linkage mechanism (2) is connected with the cooling linkage mechanism (3), and the cooling linkage mechanism (3) is connected with the conveying and fixing mechanism (1).

2. The automatic plaster fixation bone apparatus for orthopedics and traumatology as claimed in claim 1, wherein: the conveying and fixing mechanism (1) comprises a power shaft (1-1), a friction wheel a (1-2), a conveying belt (1-3), a support frame a (1-4), a support frame b (1-5), a connecting shaft a (1-6), a shaft sleeve a (1-7), a belt a (1-8), a belt wheel a (1-9), a connecting shaft b (1-10), a friction wheel b (1-11), a lifting plate (1-12), an upper grinding tool (1-13), an elastic sealing strip (1-14), a connecting plate a (1-15), an arc plate a (1-16), an arc plate b (1-17), a connecting plate b (1-18), a limiting plate a (1-19), a limiting plate b (1-20), a lower grinding tool (1-21), A lower grinding tool supporting plate (1-22), a connecting plate c (1-23), a connecting plate d (1-24), a connecting plate e (1-25), an equipment connecting frame (1-26) and a blocking plate (1-27), wherein a power shaft (1-1) is connected with a friction wheel a (1-2), the power shaft (1-1) is in bearing connection with the equipment connecting frame (1-26), the power shaft (1-1) is connected with a connecting shaft a (1-6), the power shaft (1-1) is in friction connection with a belt a (1-8), the friction wheel a (1-2) is in friction connection with a conveyor belt (1-3), the conveyor belt (1-3) is in sliding connection with a supporting frame a (1-4), the supporting frame a (1-4) is connected with a supporting frame b (1-5), the support frame a (1-4) is connected with the connecting plate e (1-25), the support frame b (1-5) is connected with the connecting plate e (1-25), the connecting shaft a (1-6) is connected with the shaft sleeve a (1-7) through a bearing, the connecting shaft a (1-6) is connected with the equipment connecting frame (1-26) through a bearing, the belt a (1-8) is connected with the belt wheel a (1-9) through a friction way, the belt wheel a (1-9) is connected with the connecting shaft b (1-10), the connecting shaft b (1-10) is connected with the friction wheel b (1-11), the connecting shaft b (1-10) is connected with the equipment connecting frame (1-26) through a bearing, the friction wheel b (1-11) is connected with the lifting plate (1-12) through a friction way, the lifting plate (1-12) is connected with the upper grinding tool (1-13), the lifting plates (1-12) are connected with the connecting plates c (1-23) in a sliding manner, the lifting plates (1-12) are connected with the connecting plates d (1-24) in a sliding manner, two sides of the upper grinding tools (1-13) are connected with the elastic sealing strips (1-14) on the upper side, the upper grinding tools (1-13) are connected with the connecting plates a (1-15), the upper grinding tools (1-13) are connected with the arc plates a (1-16), the elastic sealing strips (1-14) on the lower side are connected with two sides of the lower grinding tools (1-21), the connecting plates a (1-15) are connected with the arc plates b (1-17) in a sliding manner, the connecting plates a (1-15) are connected with the connecting plates b (1-18) in a sliding manner, the arc plates a (1-16) are connected with the arc plates b (1-17) in a sliding manner, and the arc plates b (1-17) are connected with the connecting plates d (1-24), the upper side of a connecting plate b (1-18) is connected with a connecting plate d (1-24), the lower side is connected with a connecting plate e (1-25), a limiting plate a (1-19) is connected with the connecting plate b (1-18), the limiting plate a (1-19) is connected with a lower grinding tool (1-21), the limiting plate b (1-20) is connected with the connecting plate b (1-18), the limiting plate b (1-20) is connected with a lower grinding tool (1-21), the lower grinding tool (1-21) is connected with a lower grinding tool supporting plate (1-22), the lower grinding tool supporting plate (1-22) is connected with the connecting plate e (1-25), a connecting plate c (1-23) is connected with an equipment connecting frame (1-26), the connecting plate d (1-24) is connected with the equipment connecting frame (1-26), the connecting plate e (1-25) is connected with the equipment connecting frame (1-26), the upper ends of the blocking plates (1-27) are connected with the connecting plates d (1-24), the lower ends of the blocking plates are connected with the connecting plates e (1-25), the blocking plates (1-27) are in bearing connection with the power shaft (1-1), and the blocking plates (1-27) are connected with the limiting plates b (1-20).

3. The automatic plaster fixation bone apparatus for orthopedics and traumatology as claimed in claim 1, wherein: the injection linkage mechanism (2) comprises a linkage belt (2-1), a stirring plate (2-2), a reverse friction wheel (2-3), a connecting shaft I (2-4), an acceleration friction wheel (2-5), a propeller (2-6), a conical input ring (2-7), a sealing plate (2-8), a connecting shaft II (2-9), an input pipe (2-10), an output pipe a (2-11), an output pipe b (2-12), an output groove a (2-13), an output pipe c (2-14), a single-side sealed output groove b (2-15), a reset shaft (2-16), a reset connecting plate a (2-17), a reset spring (2-18), a reset connecting plate b (2-19), an input pipe fixing plate (2-20), Sliding sealing plates a (2-21), sliding sealing plates b (2-22), sliding arc plates (2-23), compression plates (2-24), water-cooling return pipes (2-25), connecting shafts III (2-26), extension connecting shafts (2-27), linkage friction wheels (2-28) and trigger friction wheels (2-29), one end of one linkage belt (2-1) is in friction connection with a power shaft (1-1) and the other end is in friction connection with the connecting shafts III (2-26), one end of the other linkage belt (2-1) is in friction connection with the power shaft (1-1) and the other end is in friction connection with the connecting shafts III (2-26), the linkage belt (2-1) is connected with a stirring plate (2-2), and the two linkage belts (2-1) are in friction connection with two sides of a reverse friction wheel (2-3), the friction wheel (2-3) is connected with the connecting shaft I (2-4), the friction wheel (2-3) is connected with the acceleration friction wheel (2-5) in a friction mode, the connecting shaft I (2-4) is connected with the connecting plate e (1-25) in a bearing mode, the acceleration friction wheel (2-5) is connected with the connecting shaft II (2-9), the propeller (2-6) is connected with the connecting shaft II (2-9), the conical input ring (2-7) is connected with the sealing plate (2-8), the sealing plate (2-8) is connected with the connecting shaft II (2-9) in a bearing mode, a hole in the sealing plate (2-8) is connected with the input pipe (2-10), the connecting shaft II (2-9) is connected with the connecting plate c (1-23) in a bearing mode, and the connecting shaft II (2-9) is connected with the connecting plate d (1-24) in a bearing mode, the second connecting shaft (2-9) is connected with a connecting plate e (1-25) through a bearing, the input pipe (2-10) is made of a rubber hose and penetrates through a hole on an input pipe fixing plate (2-20) to be connected with a hole on a connecting plate d (1-24), the input pipe (2-10) is connected with a hole on an upper grinding tool (1-13), the output pipe a (2-11) is connected with a hole on the upper grinding tool (1-13), the output pipe a (2-11) is connected and communicated with an output pipe b (2-12), the output pipe b (2-12) is made of a rubber hose and is connected with a hole on the connecting plate d (1-24), a hole on the output groove a (2-13) is connected with an output pipe c (2-14), the output groove a (2-13) is connected with the input pipe fixing plate (2-20), the output grooves a (2-13) are connected with the unilateral sealing output grooves b (2-15) in a sliding way, the output grooves a (2-13) are connected with the sliding sealing plates a (2-21) in a sliding way, the output grooves a (2-13) are connected with the sliding sealing plates b (2-22) in a sliding way, the output grooves a (2-13) are connected with the equipment connecting frames (1-26), the output grooves a (2-13) are connected with the reset connecting plates a (2-17), the unilateral sealing output grooves b (2-15) are connected with the reset shafts (2-16), the unilateral sealing output grooves b (2-15) are connected with the sliding sealing plates b (2-22), the reset shafts (2-16) are connected with the reset connecting plates a (2-17) in a sliding way, the reset shafts (2-16) are connected with the reset connecting plates b (2-19), the reset shaft (2-16) is sleeved with a reset spring (2-18) and limited by the reset connecting plate a (2-17) and the reset connecting plate b (2-19), the input tube fixing plate (2-20) is in bearing connection with the connecting shaft II (2-9), the sliding sealing plate a (2-21) is connected with the sliding sealing plate b (2-22), the sliding sealing plate a (2-21) is in sliding connection with the input tube fixing plate (2-20), the sliding sealing plate b (2-22) is in sliding connection with the barrier plate (1-27), the sliding arc plate (2-23) is in sliding connection with the connecting plate b (1-18), the sliding arc plate (2-23) is connected with the compression plate (2-24), and the sliding arc plate (2-23) is connected with the water-cooling return pipe (2-25), the water-cooling return pipe (2-25) is connected with the connecting plate b (1-18) in a sliding mode, the connecting shaft III (2-26) is connected with the extension connecting shaft (2-27), the connecting shaft III (2-26) is connected with the blocking plate (1-27) through a bearing, the connecting shaft III (2-26) is connected with the trigger friction wheel (2-29), and the blocking plate (1-27) is connected with the linkage friction wheel (2-28) through a bearing.

4. The automatic plaster fixation bone apparatus for orthopedics and traumatology as claimed in claim 1, wherein: the cooling linkage mechanism (3) comprises a transmission shaft a (3-1), a sealing circular plate (3-2), a cooling propeller (3-3), a pressure bearing plate (3-4), a pressure bearing shaft (3-5), a pressure bearing spring (3-6), a mounting plate a (3-7), a mounting plate b (3-8), an air blowing pipe (3-9), a mounting plate c (3-10), a drain pipe (3-11) and a mounting plate d (3-12), wherein the transmission shaft a (3-1) is connected with the sealing circular plate (3-2), the transmission shaft a (3-1) is in sliding connection with the mounting plate a (3-7), the transmission shaft a (3-1) is in sliding connection with the mounting plate b (3-8), and the transmission shaft a (3-1) is in sliding connection with an equipment connecting frame (1-26), a sealing circular plate (3-2) is connected with an equipment connecting frame (1-26) in a sliding way, a transmission shaft a (3-1) is connected with a cooling propeller (3-3), a bearing plate (3-4) is connected with a bearing shaft (3-5) in a sliding way, the bearing shaft (3-5) is connected with a connecting plate e (1-25), a bearing spring (3-6) is sleeved on the bearing shaft (3-5) and limited on the connecting plate e (1-25) and the bearing plate (3-4), a mounting plate a (3-7) is connected with the connecting plate e (1-25), a mounting plate b (3-8) is connected with the connecting plate e (1-25), an air blowing pipe (3-9) is made of a rubber hose, one end of the air blowing pipe is connected with the mounting plate b (3-8), and the other end of the air blowing pipe penetrates through a hole on the equipment connecting frame (1-26) to be connected, the mounting plate c (3-10) is connected with the upper grinding tool (1-13), the mounting plate c (3-10) is connected with the drain pipe (3-11), the drain pipe (3-11) is connected with the mounting plate d (3-12), the drain pipe (3-11) is in sliding connection with the connecting plate b (1-18), the drain pipe (3-11) is connected with the sliding arc plate (2-23), and the mounting plate d (3-12) is connected with the sliding arc plate (2-23).

5. The automatic plaster fixation bone apparatus for orthopedics and traumatology as claimed in claim 1, wherein: the power shaft (1-1) is provided with a power source which can rotate.

Technical Field

The invention relates to a gypsum bone fixing device, in particular to an automatic gypsum bone fixing device for orthopedics and traumatology.

Background

The automatic plaster bone fixing equipment for the orthopedics department is designed because the injured bones are often required to be fixed, the operation time is long when the conventional plaster is used for fixing, secondary injury is easy to occur to the injured bones, and the plaster can generate heat when medical plaster is used for fixing the bones and easily scald the skin of a patient.

Disclosure of Invention

The invention mainly solves the technical problem of providing automatic gypsum bone fixing equipment for orthopedics department, the equipment can assist a patient to convey injured bones of the patient to a shaping mold cavity, the equipment can seal the shaping mold cavity and convey liquid viscous gypsum into the mold cavity of a mold, the equipment can convey redundant liquid viscous gypsum out of the equipment when the mold cavity of the mold is filled with the liquid viscous gypsum so that an operator can confirm the state of the mold, the equipment can carry out water cooling on the upper part of the shaping mold cavity, and the equipment can carry out air cooling on the lower part of the mold cavity of the shaping mold.

In order to solve the technical problem, the invention relates to a gypsum fixing skeleton device, in particular to an automatic gypsum fixing skeleton device for orthopedics department, which comprises a conveying and fixing mechanism, an injection linkage mechanism and a cooling linkage mechanism, wherein the device can assist a patient to convey injured skeleton of the patient into a shaping mold cavity, the device can seal the shaping mold cavity and convey liquid viscous gypsum into the mold cavity of the mold, the device can convey redundant liquid viscous gypsum out of the device when the mold cavity of the mold is filled with the liquid viscous gypsum so that an operator can confirm the state of the mold, the device can carry out water cooling on the upper part of the mold cavity of the shaping mold, and the device can carry out air cooling on the lower part of the mold cavity of the shaping mold.

The conveying and fixing mechanism is connected with the injection linkage mechanism, the injection linkage mechanism is connected with the cooling linkage mechanism, and the cooling linkage mechanism is connected with the conveying and fixing mechanism.

As a further optimization of the technical scheme, the automatic plaster bone fixing equipment for the orthopedics department comprises a power shaft, a friction wheel a, a conveyor belt, a support frame a, a support frame b, a connecting shaft a, a shaft sleeve a, a belt wheel a, a connecting shaft b, a friction wheel b, a lifting plate, an upper grinding tool, an elastic sealing strip, a connecting plate a, an arc plate b, a connecting plate b, a limiting plate a, a limiting plate b, a lower grinding tool supporting plate, a connecting plate c, a connecting plate d, a connecting plate e, an equipment connecting frame and a blocking plate, wherein the power shaft is connected with the friction wheel a, the power shaft is connected with the connecting shaft a, the power shaft is connected with the belt a in a friction manner, the friction wheel a is connected with the conveyor belt in a friction manner, the support frame a is connected with the support frame b, the support frame a is connected with a connecting plate e, the support frame b is connected with the connecting plate e, the connecting shaft a is connected with a shaft sleeve a bearing, the connecting shaft a is connected with an equipment connecting frame bearing, the belt a is connected with a belt wheel a in a friction mode, the belt wheel a is connected with a connecting shaft b, the connecting shaft b is connected with a friction wheel b, the connecting shaft b is connected with the equipment connecting frame bearing, the friction wheel b is connected with a lifting plate in a friction mode, the lifting plate is connected with an upper grinding tool, the lifting plate is connected with a connecting plate c in a sliding mode, the lifting plate is connected with a connecting plate d in a sliding mode, two sides of the upper grinding tool are connected with elastic sealing strips on the upper side, the upper grinding tool is connected with the connecting plate a, the upper grinding tool is connected with an arc plate a, the elastic sealing strips on the lower side are connected with two sides of a lower grinding tool, the connecting plate a is connected with the arc plate b in a sliding mode, the connecting plate a is connected with the connecting plate b in a sliding mode, the arc plate a is connected with the connecting plate d, the upside of the connecting plate b is connected with the connecting plate d, the downside is connected with the connecting plate e, the limiting plate a is connected with the connecting plate b, the limiting plate a is connected with the lower grinding tool, the limiting plate b is connected with the connecting plate b, the limiting plate b is connected with the lower grinding tool, the lower grinding tool is connected with the lower grinding tool supporting plate, the lower grinding tool supporting plate is connected with the connecting plate e, the connecting plate c is connected with the equipment connecting frame, the connecting plate d is connected with the equipment connecting frame, the connecting plate e is connected with the equipment connecting frame, the upper end of the blocking plate is connected with the connecting plate d, the lower end is connected with the connecting plate e, the blocking plate is connected with the power shaft bearing, and the blocking plate is connected with the limiting plate b.

As a further optimization of the technical scheme, the automatic plaster bone fixation equipment for the orthopedics department comprises an injection linkage mechanism 2, a linkage belt 2-1, a stirring plate 2-2, a reverse friction wheel 2-3, a connecting shaft I2-4, an accelerating friction wheel 2-5, a propeller 2-6, a conical input ring 2-7, a sealing plate 2-8, a connecting shaft II 2-9, an input pipe 2-10, an output pipe a2-11, an output pipe b2-12, an output groove a2-13, an output pipe c2-14, a single-side sealed output groove b2-15, a reset shaft 2-16, a reset connecting plate a2-17, a reset spring 2-18, a reset connecting plate b2-19, an input pipe fixing plate 2-20, a sliding sealing plate a2-21, a sliding sealing plate b 2-21, a reset shaft 2-16, a reset shaft and a reset shaft 2-10, A sliding sealing plate b2-22, a sliding arc plate 2-23, a compression plate 2-24, a water-cooling return pipe 2-25, a connecting shaft III 2-26, an extension connecting shaft 2-27, a linkage friction wheel 2-28 and a trigger friction wheel 2-29, wherein one end of a linkage belt 2-1 is connected with a power shaft 1-1 in a friction way, the other end is connected with the connecting shaft III 2-26 in a friction way, one end of another linkage belt 2-1 is connected with the power shaft 1-1 in a friction way, the other end is connected with the connecting shaft III 2-26 in a friction way, the linkage belt 2-1 is connected with a stirring plate 2-2, the two linkage belts 2-1 are connected with two sides of a reverse friction wheel 2-3 in a friction way, the friction wheel 2-3 is connected with a connecting shaft I2-4, the friction wheel 2-3 is connected with an accelerating friction wheel 2-5 in a friction way, the first connecting shaft 2-4 is connected with a connecting plate e1-25 through a bearing, the accelerating friction wheel 2-5 is connected with a second connecting shaft 2-9, the propeller 2-6 is connected with the second connecting shaft 2-9, the conical input ring 2-7 is connected with a sealing plate 2-8, the sealing plate 2-8 is connected with the second connecting shaft 2-9 through a bearing, a hole in the sealing plate 2-8 is connected with an input pipe 2-10, the second connecting shaft 2-9 is connected with a connecting plate c1-23 through a bearing, the second connecting shaft 2-9 is connected with a connecting plate d1-24 through a bearing, the second connecting shaft 2-9 is connected with a connecting plate e1-25 through a bearing, the input pipe 2-10 is made of a rubber hose and penetrates through a hole in an input pipe fixing plate 2-20 and a hole in a connecting plate d1-24, and the input pipe 2-10 is connected with a hole in an upper grinding tool 1-13, an output pipe a2-11 is connected with an upper grinding tool 1-13, an output pipe a2-11 is connected with holes on an upper grinding tool 1-13, an output pipe a2-11 is connected with and communicated with an output pipe b2-12, an output pipe b2-12 is made of a rubber hose and is connected with holes on a connecting plate d1-24, holes on an output groove a2-13 are connected with an output pipe c2-14, an output groove a2-13 is connected with an input pipe fixing plate 2-20, an output groove a2-13 is in sliding connection with a unilateral sealed output groove b2-15, an output groove a2-13 is in sliding connection with a sliding sealing plate a2-21, an output groove a2-13 is in sliding connection with a sliding sealing plate b2-22, an output groove a2-13 is connected with an equipment connecting frame 1-26, an output groove a2-13 is connected with a reset connecting plate a2-17, the single-side sealing output groove b2-15 is connected with a reset shaft 2-16, the single-side sealing output groove b2-15 is connected with a sliding sealing plate b2-22, the reset shaft 2-16 is connected with a reset connecting plate a2-17 in a sliding way, the reset shaft 2-16 is connected with a reset connecting plate b2-19, a reset spring 2-18 is sleeved on the reset shaft 2-16 and limited on the reset connecting plate a2-17 and the reset connecting plate b2-19, an input tube fixing plate 2-20 is connected with a connecting shaft two 2-9 in a bearing way, the sliding sealing plate a2-21 is connected with a sliding sealing plate b2-22, a sliding sealing plate a2-21 is connected with an input tube fixing plate 2-20 in a sliding way, a sliding sealing plate b2-22 is connected with a blocking plate 1-27 in a sliding way, a sliding arc plate 2-23 is connected with a connecting plate b1-18 in a sliding way, the sliding arc plates 2-23 are connected with the compression plates 2-24, the sliding arc plates 2-23 are connected with the water-cooling return pipes 2-25, the water-cooling return pipes 2-25 are connected with the connecting plates b1-18 in a sliding mode, the connecting shafts three 2-26 are connected with the extending connecting shafts 2-27, the connecting shafts three 2-26 are connected with the blocking plates 1-27 through bearings, the connecting shafts three 2-26 are connected with the trigger friction wheels 2-29, and the blocking plates 1-27 are connected with the linkage friction wheels 2-28 through bearings.

As a further optimization of the technical scheme, the automatic gypsum bone fixing equipment for the orthopedics department comprises a transmission shaft a, a sealing circular plate, a cooling propeller, a pressure bearing plate, a pressure bearing shaft, a pressure bearing spring, a mounting plate a, a mounting plate b, an air blowing pipe, a mounting plate c, a drain pipe and a mounting plate d, wherein the transmission shaft a is connected with the sealing circular plate, the transmission shaft a is connected with the mounting plate a in a sliding mode, the transmission shaft a is connected with the mounting plate b in a sliding mode, the transmission shaft a is connected with an equipment connecting frame in a sliding mode, the sealing circular plate is connected with the equipment connecting frame in a sliding mode, the transmission shaft a is connected with the cooling propeller, the pressure bearing plate is connected with the pressure bearing shaft, the pressure bearing shaft is connected with a connecting plate e, the pressure bearing spring is sleeved on the pressure bearing shaft and limited on the connecting plate e and the pressure bearing plate, the mounting plate a is connected with the connecting plate e, the mounting plate b is connected with the connecting plate e, the air blowing pipe is made of a rubber hose, one end of the air blowing pipe is connected with the mounting plate b, and the other end of the air blowing pipe penetrates through a hole in the connecting plate and is connected with a hole in the equipment connecting frame And the mounting plate c is connected with the upper grinding tool, the mounting plate c is connected with a water drainage pipe, the water drainage pipe is connected with the mounting plate d, the water drainage pipe is connected with the connecting plate b in a sliding manner, the water drainage pipe is connected with the sliding arc plate, and the mounting plate d is connected with the sliding arc plate.

As a further optimization of the technical scheme, the automatic plaster bone fixing equipment for the orthopedics department is characterized in that a power source is arranged on the power shaft and can rotate.

The automatic plaster bone fixing equipment for orthopedics and traumatology has the beneficial effects that:

the automatic gypsum bone fixing equipment for the orthopedics department can assist a patient to convey injured bones of the patient to a shaping mold cavity, the equipment can seal the shaping mold cavity and convey liquid viscous gypsum into the mold cavity, the equipment can convey redundant liquid viscous gypsum out of the equipment when the mold cavity is filled with the liquid viscous gypsum so that an operator can confirm the state of the mold, the equipment can carry out water cooling on the upper part of the shaping mold cavity, and the equipment can carry out air cooling on the lower part of the shaping mold cavity.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

Fig. 1 is a first structural schematic diagram of an automatic plaster bone fixation device for orthopedics department.

Fig. 2 is a second structural schematic view of the automatic plaster bone fixation device for orthopedics and traumatology of the invention.

Fig. 3 is a first structural view of a first transmission fixing mechanism 1 of an automatic plaster fixation bone device for orthopedics department of the invention.

Fig. 4 is a second structural schematic diagram of the conveying and fixing mechanism 1 of the automatic plaster fixation bone equipment for orthopedics department of the invention.

Fig. 5 is a third structural schematic diagram of the conveying and fixing mechanism 1 of the automatic plaster fixation bone equipment for orthopedics department of the invention.

Fig. 6 is a fourth structural view of the conveying and fixing mechanism 1 of the automatic plaster fixation bone equipment for orthopedics department of the invention.

Fig. 7 is a fifth structural view of the transfer fixing mechanism 1 of the automatic plaster fixation bone device for orthopedics department of the invention.

Fig. 8 is a sixth schematic structural view of the conveying and fixing mechanism 1 of the automatic plaster fixation bone equipment for orthopedics department.

Fig. 9 is a seventh structural view of the transfer fixing mechanism 1 of the automatic plaster fixation bone device for orthopedics department of the invention.

Fig. 10 is a schematic structural view of the apparatus connection frames 1-26 of the automatic plaster fixation bone apparatus for orthopedics and traumatology of the present invention.

Fig. 11 is a schematic structural view of an injection linkage mechanism 2 of an automatic plaster fixation bone device for orthopedics and traumatology according to the present invention.

Fig. 12 is a first structural view of an injection linkage mechanism 2 of an automatic plaster fixation bone device for orthopedics department according to the present invention.

Fig. 13 is a second structural schematic view of the injection linkage mechanism 2 of the automatic plaster fixation bone device for orthopedics department of the invention.

Fig. 14 is a third structural schematic view of the injection linkage mechanism 2 of the automatic plaster fixation bone device for orthopedics department of the invention.

Fig. 15 is a fourth schematic structural view of the injection linkage mechanism 2 of the automatic plaster fixation bone device for orthopedics department of the invention.

Fig. 16 is a fifth structural view illustrating the injection linkage mechanism 2 of the automatic plaster-fixation bone device for orthopedics and traumatology according to the present invention.

Fig. 17 is a sixth schematic structural view of the injection linkage mechanism 2 of the automatic plaster fixation bone device for orthopedics department of the invention.

Fig. 18 is a seventh structural view of the injection linkage mechanism 2 of the automatic plaster fixation bone device for orthopedics and traumatology of the invention.

Fig. 19 is a first structural schematic diagram of a cooling linkage mechanism 3 of the automatic plaster fixation bone equipment for orthopedics department of the invention.

Fig. 20 is a second structural schematic view of the cooling linkage mechanism 3 of the automatic plaster bone fixation device for orthopedics department of the invention.

Fig. 21 is a third schematic structural view of a cooling linkage mechanism 3 of the automatic plaster fixation bone device for orthopedics department of the invention.

Fig. 22 is a fourth structural schematic view of the cooling linkage mechanism 3 of the automatic plaster fixation bone device for orthopedics department of the invention.

In the figure: a conveying and fixing mechanism 1; a power shaft 1-1; friction wheel a 1-2; a conveyor belt 1-3; support a 1-4; support b 1-5; connecting shaft a 1-6; the shaft sleeve a 1-7; belt a 1-8; pulley a 1-9; connecting shaft b 1-10; friction wheel b 1-11; 1-12 of a lifting plate; 1-13 parts of an upper grinding tool; 1-14 parts of elastic sealing strips; connection board a 1-15; arc plates a 1-16; arc plates b 1-17; connecting plate b 1-18; the limiting plates a 1-19; the limiting plate b 1-20; 1-21 parts of a lower grinding tool; lower abrasive tool support plates 1-22; connecting plates c 1-23; connecting plates d 1-24; connecting plates e 1-25; device connection boxes 1-26; barrier plates 1-27; an injection linkage mechanism 2; 2-1 of a linkage belt; 2-2 of a stirring plate; 2-3 of a reverse friction wheel; connecting shafts I2-4; 2-5 of an acceleration friction wheel; 2-6 of a propeller; 2-7 parts of a conical input ring; 2-8 of a sealing plate; connecting shafts II 2-9; 2-10 parts of an input pipe; an output pipe a 2-11; output pipe b 2-12; output slot a 2-13; output pipe c 2-14; a single-sided sealed output slot b 2-15; reset shafts 2-16; reset connection board a 2-17; 2-18 of a return spring; reset connecting plate b 2-19; 2-20 parts of an input tube fixing plate; sliding seal plates a 2-21; sliding seal plates b 2-22; 2-23 of sliding arc plate; 2-24 of a compression plate; 2-25 parts of a water-cooling return pipe; connecting shafts III 2-26; 2-27 of a prolonged connecting shaft; 2-28 of linkage friction wheel; triggering friction wheels 2-29; a cooling link mechanism 3; a transmission shaft a 3-1; a sealing circular plate 3-2; cooling the propeller 3-3; 3-4 of a bearing plate; 3-5 of a pressure bearing shaft; 3-6 parts of pressure-bearing spring; mounting plate a 3-7; mounting plate b 3-8; 3-9 parts of an air blowing pipe; mounting plate c 3-10; 3-11 parts of a drain pipe; mounting plate d 3-12.

Detailed Description

The first embodiment is as follows:

the present embodiment will be described below with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22. the present invention relates to a gypsum-fixed skeleton device, and more particularly to an automatic gypsum-fixed skeleton device for orthopedics department, including a transfer fixing mechanism 1, an injection linkage mechanism 2, and a cooling linkage mechanism 3, the device can assist a patient to transfer a wounded skeleton of the patient into a sizing mold cavity, the device can seal the sizing mold cavity and transfer liquid viscous gypsum into the mold cavity, the device can transfer excess liquid viscous gypsum out of the device when the mold cavity is filled with the liquid viscous gypsum so that an operator can confirm the state of the mold, the device can perform water cooling on the upper portion of the sizing mold cavity, the equipment can carry out air cooling to design grinding apparatus die cavity lower part.

The conveying and fixing mechanism 1 is connected with the injection linkage mechanism 2, the injection linkage mechanism 2 is connected with the cooling linkage mechanism 3, and the cooling linkage mechanism 3 is connected with the conveying and fixing mechanism 1.

The second embodiment is as follows:

referring now to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, this embodiment further illustrates an embodiment of the present invention, wherein the present invention is capable of assisting a patient to transfer injured bones of the patient into a shaped mold cavity, the present invention is capable of sealing the shaped mold cavity and transferring liquid viscous plaster into the mold cavity, the present invention is capable of transferring excess liquid viscous plaster out of the apparatus so that an operator can confirm the state of the mold when the mold cavity is filled with the liquid viscous plaster, the power shaft 1-1 rotates to drive the friction wheel a1-2 to rotate, the friction wheel a1-2 drives the conveyor belt 1-3 to place bones on both ends of the injured conveyor belt 1-3 under the limit of the support frame a1-4 The elastic sealing strips are conveyed to two elastic sealing strips 1-14 at the lower side, when a power shaft 1-1 rotates, a belt wheel a1-9 is driven to rotate through a belt a1-8, the belt wheel a1-9 rotates, a friction wheel b1-11 rotates through a connecting shaft b1-10, the friction wheel b1-11 rotates to drive a lifting plate 1-12 to move downwards, the lifting plate 1-12 moves to drive an upper grinding tool 1-13 to move downwards, when the upper grinding tool 1-13 moves downwards to be contacted with a lower grinding tool 1-21, the upper grinding tool 1-13, the lower grinding tool 1-21 and four elastic sealing strips 1-14 can form a shaped grinding tool cavity and form a sealed grinding tool cavity together with two ends of a wounded bone of a patient, at the moment, the power shaft 1-1 continues to rotate, the friction connection between a1-2 and a conveying belt 1-3 fails, the friction connection between the friction wheel b1-11 and the lifting plate 1-12 is failed, when the power shaft 1-1 rotates, the linkage belt 2-1 drives the stirring plate 2-2 to move, the linkage belt 2-1 and the stirring plate 2-2 on the other side reversely move under the action of the reverse friction wheel 2-3 and the connecting shaft I2-4, the other sides of the two linkage belts 2-1 and the stirring plate 2-2 move under the action of the connecting shaft III 2-26, the extension connecting shaft 2-27 and the linkage friction wheel 2-28, the process can uniformly stir the viscous gypsum in the forming cavity formed by the connecting plate e1-25, the equipment connecting frame 1-26 and the barrier plate 1-27, the viscous gypsum is prevented from precipitating, and the reverse friction wheel 2-3 is in a rotating state, the reverse friction wheel 2-3 rotates to drive the accelerating friction wheel 2-5 to rotate, the accelerating friction wheel 2-5 rotates to drive the connecting shaft II 2-9 to rotate, the connecting shaft II 2-9 rotates to drive the propeller 2-6 to rotate, the propeller 2-6 can transmit viscous gypsum to the conical input ring 2-7 when rotating, and the viscous gypsum is transmitted to a cavity formed by the upper grinding tool 1-13 and the lower grinding tool 1-21 under the guidance of the connecting shaft II 2-9, the process finishes the function of transmitting the viscous gypsum in liquid state to the cavity of the grinding tool, when the cavity of the grinding tool is filled with gypsum, the redundant viscous gypsum in liquid state is transmitted to the output groove a2-13 through the output pipe a2-11 and the output pipe b2-12, and because the output groove a2-13, the connecting plate d1-24 and the sliding sealing plate b2-22 form a relatively closed cavity, therefore, the conveyed liquid viscous gypsum is filled into the single-side seal output groove b2-15, when the single-side seal output groove b2-15 is filled, pressure is applied to the single-side seal output groove b2-15, the single-side seal output groove b2-15 slides towards the reset connecting plate a2-17, the single-side seal output groove b2-15 can automatically reset under the action of the reset springs 2-18, when the holes on the lower side of the single-side seal output groove b2-15 are overlapped with the output pipe c2-14, the conveyed liquid viscous gypsum is conveyed out of the device through the output pipe c2-14, and an operator can confirm that the shaping mold cavity is filled.

The third concrete implementation mode:

the following describes the present embodiment with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, fig. 18, fig. 19, fig. 20, fig. 21, fig. 22, and the present embodiment further describes the first embodiment, in which the device can perform water cooling on the upper portion of the cavity of the sizing mill, the device can perform air cooling on the lower portion of the cavity of the sizing mill, the mounting plate c3-10 drives the drain pipe 3-11 to move downwards when the upper mill 1-13 moves downwards, the drain pipe 3-11 drives the sliding arc plate 2-23 to move, the sliding arc plate 2-23 drives the pressing plate 2-24 to move downwards, the pressing shaft a3-1 is gradually pressed when the pressing plate 2-24 moves downwards, and the driving shaft a3-1 is pressed until it contacts with the trigger friction wheel 2-29, the transmission shaft a3-1 can automatically reset under the action of the pressure-bearing spring 3-6, the trigger friction wheel 2-29 is in a rotating state in the process, the trigger friction wheel 2-29 rotates to drive the transmission shaft a3-1 to rotate, the transmission shaft a3-1 rotates to drive the cooling propeller 3-3 to rotate, when the propeller 3-3 rotates, water in a space formed by the connecting plate b1-18, the connecting plate e1-25, the equipment connecting frame 1-26 and the baffle plate 1-27 can be discharged into the water discharge pipe 3-11 which moves downwards to be close to the propeller 3-3, the water is conveyed to the upper part 1-13 under the guide of the water discharge pipe 3-11, and is discharged back to the grinding tool through the water-cooling return pipe 2-25 which moves downwards along with the grinding tool and is discharged by the connecting plate b1-18, the connecting plate e1-25, In the space formed by the equipment connecting frame 1-26 and the barrier plate 1-27, the upper grinding tool 1-13 can be cooled by water in the process, the suction force can be applied to the air blowing pipe 3-9 when the cooling propeller 3-3 rotates, the suction force is applied to the lower part of the lower grinding tool 1-21 under the guidance of the air blowing pipe 3-9, and the heat of the lower grinding tool 1-21 during gypsum solidification is absorbed into the space formed by the connecting plate b1-18, the connecting plate e1-25, the equipment connecting frame 1-26 and the barrier plate 1-27 by the air blowing pipe 3-9.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.