Disclosure of Invention
The invention aims to provide a detection device for a computer heat dissipation motor spindle, which can fix heat dissipation motor spindles with different specifications through a spindle fixing assembly; the track pen can be fixed through the fixed frame assembly; the composite fixed trajectory map may be fixed by the trajectory map.
The purpose of the invention is realized by the following technical scheme:
the utility model provides a check out test set of computer heat dissipation motor main shaft, includes that the fixed assembly of main shaft, switching-over transmission assembly, mount assembly, the fixed assembly of locus diagram, the fixed assembly of locus pen and adjusting device, its characterized in that: the main shaft fixing assembly is connected with the reversing transmission assembly, the fixing frame assembly is connected with the reversing transmission assembly, the track chart fixing assembly is connected with the fixing frame assembly, the track chart fixing assembly is connected with the track pen fixing assembly, and the adjusting device is connected with the track chart fixing assembly.
As a further optimization of the technical scheme, the detection device for the main shaft of the computer heat dissipation motor comprises a fixing rod, a fixing push spring, a fixing driving rod, a driving bevel gear, a matching frustum, a driving boss, a matching hollowed-out groove, an inner chute and a side wall sliding hole, wherein the fixing push spring is connected with the fixing rod in a sleeved mode, the fixing push spring is connected with the fixing driving rod in a sliding mode, the driving bevel gear is fixedly connected with the fixing driving rod, the matching frustum is fixedly connected with the fixing rod, the driving boss is fixedly connected with the matching frustum, the matching hollowed-out groove is formed in the front end of the fixing rod, and the inner chute and the side wall sliding hole are formed in the fixing driving rod.
As a further optimization of the technical scheme, the invention relates to a detection device of a main shaft of a computer heat dissipation motor, wherein a reversing transmission assembly comprises a first transmission bevel gear, a matching sleeve, a driving sleeve, a main shaft rod, a second transmission bevel gear, a first matching clamping rod, an auxiliary sleeve, a straight meshing tooth, a first hinge rod, a tension spring, a second hinge rod, a second matching clamping rod, a matching chute, a first matching boss, an inner sliding rod, a hollow pipe and a second matching boss, wherein the second matching clamping rod is fixedly connected with the first transmission bevel gear, the first matching boss and the second matching boss are both fixedly connected with the matching sleeve, the inner sliding rod is fixedly connected with the matching sleeve, the hollow pipe is arranged on the matching sleeve, the matching chute is arranged on the main shaft rod, the inner sliding rod is slidably connected with the matching chute, the matching sleeve is rotatably connected with the driving sleeve, the first transmission bevel gear and the second transmission bevel gear are both rotatably connected with the main shaft rod, the first matching clamping rod is fixedly connected with the second transmission bevel gear, the auxiliary sleeve is rotatably connected with the main shaft rod, the straight meshing teeth are fixedly connected with the main shaft rod, the first hinge rod is hinged with the auxiliary sleeve, the tension spring is connected between the first hinge rod and the auxiliary sleeve, the second hinge rod is connected in front of the first driving sleeve and the first hinge rod, the first matching boss is matched and connected with the second matching clamping rod, and the first driving bevel gear is meshed with the first transmission bevel gear and the second transmission bevel gear for transmission.
As a further optimization of the technical scheme, the invention discloses a detection device of a computer heat dissipation motor spindle, wherein a fixed frame assembly comprises a fixed bottom plate, a first fixed frame, a second fixed frame, a third fixed frame, a fourth fixed frame, a first rectangular sliding hole, a fifth fixed frame, a second rectangular sliding hole, a driving frame, a hinged connecting rod, a first driving frame rod, a second driving frame, a connecting end of the driving frame and a sliding groove of the driving frame, the first fixed frame, the second fixed frame and the third fixed frame are fixedly connected with the fixed bottom plate, the fourth fixed frame and the fifth fixed frame are fixedly connected with the fixed bottom plate, the first rectangular sliding hole is arranged on the third fixed frame, the second rectangular sliding hole is arranged on the fourth fixed frame, the sliding groove of the driving frame is arranged on the fixed bottom plate, the connecting ends of the first driving frame, the second driving frame and the driving frame are fixedly connected with the driving frame, the driving frame is slidably connected, the main shaft rod is rotatably connected with the first fixing frame and the third fixing frame, the fixed driving rod is rotatably connected with the second fixing frame, and the fifth fixing frame is fixedly connected with the auxiliary sleeve.
As a further optimization of the technical scheme, the invention relates to a detection device for a main shaft of a computer heat dissipation motor, the locus diagram fixing assembly comprises a fixing bottom plate, a first support, a driving straight tooth, a driving rolling shaft, a driving push plate, a driving push spring, a driving matching plate, a second support, a driven rolling shaft, a driven push plate, a driven push spring and a driven matching plate, the support I and the support II are both fixedly connected with the fixing bottom plate, the driving straight teeth are fixedly connected with the driving rolling shaft, the driving rolling shaft is rotatably connected with the support I, the driving push plate is slidably connected with the driving rolling shaft, the driving push spring is connected with the driving rolling shaft in a sleeved mode, the driving matching plate is fixedly connected with the driving rolling shaft, the driven rolling shaft is connected with the support II in a matched mode, the driven push plate is slidably connected with the driven rolling shaft, the driven push spring is connected with the driven rolling shaft in a sleeved mode, the driven matching plate is fixedly connected with the driven rolling shaft, and the fixing bottom plate is fixedly connected.
As a further optimization of the technical scheme, the detection device for the main shaft of the computer heat dissipation motor comprises a fixed end rod, a fixed end rod connection column, a driving rack plate, a fixed sleeve, a fixed clamping rod and an inner end pushing spring, wherein the fixed end rod connection column is fixedly connected with the fixed end rod, the driving rack plate is fixedly connected with the fixed end rod, the fixed sleeve is fixedly connected with the fixed end rod, the fixed clamping rod is slidably connected with the fixed sleeve, the inner end pushing spring is arranged between the fixed clamping rod and the fixed sleeve, the inner end pushing spring is in a compressed state, a meshing straight tooth is connected with the driving rack plate in a matched mode, and the fixed end rod is slidably connected with a rectangular sliding hole II.
As a further optimization of the technical scheme, the invention provides a detection device of a computer heat dissipation motor spindle, wherein an adjusting device comprises an adjusting bottom plate, a motor, an input straight tooth, a transmission bevel tooth a, a transmission bevel tooth B, an adjusting rod, an adjusting rotating rod, a transmission bevel tooth C, an output straight tooth, a first hinge frame rod and a second hinge frame rod, wherein the first hinge frame rod and the second hinge frame rod are fixedly connected with the adjusting bottom plate, the motor is fixedly connected with the adjusting bottom plate, the input straight tooth is fixedly connected with an output shaft of the motor, the input straight tooth is in meshing transmission with the transmission straight tooth, the transmission straight tooth is fixedly connected with the transmission bevel tooth a, the transmission bevel tooth a is in meshing transmission with the transmission bevel tooth B, the transmission bevel tooth B is in rotating connection with the adjusting rod, the adjusting rod is in rotating connection with the adjusting rotating rod, two ends of the adjusting rotating rod are respectively rotatably connected in the first hinge frame rod and the second hinge frame rod, the transmission bevel gear C is in meshing transmission with the transmission bevel gear B, the transmission bevel gear C is fixedly connected with the output straight tooth, the output straight tooth is in meshing transmission with the driving straight tooth, and the adjusting bottom plate is fixedly connected with the fixed bottom plate.
The detection equipment for the main shaft of the computer heat dissipation motor has the beneficial effects that:
the invention relates to a detection device for a main shaft of a computer heat dissipation motor, wherein a motor drives a transmission straight tooth to rotate through an input straight tooth so as to drive a transmission bevel tooth A to rotate, drives a transmission bevel tooth C to rotate through a transmission bevel tooth B so as to drive an output straight tooth to rotate, drives a driving rolling shaft to rotate through the meshing transmission of the output straight tooth and the driving straight tooth so as to drive a locus diagram to rotate, and enables the rotation of the main shaft of a thermoelectric motor to be converted into a locus on the locus diagram through the contact of the locus diagram and a locus pen, so that the detection device is convenient to test.
Drawings
The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.
FIG. 1 is a schematic view of the overall structure of the present invention;
FIG. 2 is a first schematic view of the spindle fixing assembly according to the present invention;
FIG. 3 is a schematic structural diagram of a spindle fixing assembly according to the present invention;
FIG. 4 is a third schematic structural view of the spindle fixing assembly of the present invention;
FIG. 5 is a fourth schematic view of the spindle securing assembly of the present invention;
FIG. 6 is a fifth structural schematic view of the spindle securing assembly of the present invention;
FIG. 7 is a first schematic view of the reversing transmission assembly of the present invention;
FIG. 8 is a second schematic structural view of the reversing transmission assembly of the present invention;
FIG. 9 is a third schematic structural view of the reversing transmission assembly of the present invention;
FIG. 10 is a fourth schematic structural view of the reversing transmission assembly of the present invention;
FIG. 11 is a first schematic view of a fastening frame assembly according to the present invention;
FIG. 12 is a second schematic view of the fastening frame assembly of the present invention;
FIG. 13 is a third schematic view of the fastening frame assembly of the present invention;
FIG. 14 is a first schematic view of the track map fixing assembly of the present invention;
FIG. 15 is a second schematic view of the track map fixing assembly of the present invention;
FIG. 16 is a third schematic view of the trackchart fixed assembly of the present invention;
FIG. 17 is a first schematic view of a first exemplary embodiment of a stylus pen holding assembly of the present invention;
FIG. 18 is a second structural diagram of a stylus pen fixing assembly according to the present invention;
FIG. 19 is a first schematic view of the adjusting device of the present invention;
FIG. 20 is a second schematic structural view of an adjustment device of the present invention;
fig. 21 is a third structural schematic diagram of the adjusting device of the invention.
In the figure: a main shaft fixing assembly 1; a fixing rod 1-1; fixing a push spring 1-2; a fixed drive rod 1-3; driving bevel teeth 1-4; 1-5 of a matched terrace with edge; 1-6 of a driving boss; matching with the hollow grooves 1-7; 1-8 parts of an inner chute; side wall slide holes 1-9; the reversing transmission assembly 2; the transmission bevel gear I is 2-1; matching the sleeve 2-2; 2-3 of a driving sleeve; 2-4 of a main shaft rod; 2-5 of a second transmission bevel gear; 2-6 of a first matching clamping rod; 2-7 of auxiliary sleeve; 2-8 of straight teeth are meshed; hinge rods one 2-9; 2-10 parts of a tension spring; a second hinge rod 2-11; 2-12 of a second matching clamping rod; matching with the sliding chutes 2-13; matching with the first boss 2-14; 2-15 parts of an inner sliding rod; 2-16 parts of a hollow pipe; 2-17 of a second matching boss; a holder assembly 3; a fixed base plate 3-1; a first fixing frame 3-2; 3-3 parts of a second fixing frame; 3-4 parts of a fixing frame; a fourth fixing frame 3-5; 3-6 of a rectangular sliding hole I; a fifth fixing frame 3-7; 3-8 of a rectangular sliding hole II; 3-9 of a driving frame; 3-10 parts of hinged connecting rod; 3-11 parts of a driving frame rod; 3-12 parts of a second driving frame; the driving frame is connected with the ends 3-13; driving frame sliding chutes 3-14; a trajectory graph fixing assembly 4; a fixed bottom plate 4-1; 4-2 of a first bracket; 4-3 of active straight teeth; 4-4 of a driving roller; 4-5 of an active push plate; 4-6 of active push spring; 4-7 of active matching plate; 4-8 parts of a second bracket; 4-9 parts of driven roller; 4-10 parts of a driven push plate; 4-11 parts of driven push spring; 4-12 of driven matching plates; a stylus pen fixed combination 5; a fixed end rod 5-1; a fixed end rod connecting column 5-2; driving the rack plate 5-3; 5-4 of a fixed sleeve; 5-5 of a fixed clamping rod; 5-6 parts of inner end push spring; an adjusting device 6; adjusting the bottom plate 6-1; a motor 6-2; inputting straight teeth 6-3; 6-4 of transmission straight teeth; the transmission bevel gear A6-5; the transmission bevel gear B6-6; adjusting rods 6-7; 6-8 of an adjusting rotating rod; the transmission bevel gear C6-9; outputting straight teeth 6-10; 6-11 parts of hinge frame rod I; and a second hinge frame rod 6-12.
Detailed Description
The present invention will be described in further detail with reference to the accompanying drawings.
The fixed connection in the device is realized by fixing in modes of welding, thread fixing and the like, and different fixing modes are used in combination with different use environments; the rotary connection means that the bearing is arranged on the shaft in a drying mode, a spring retainer ring groove is formed in the shaft or the shaft hole, and the elastic retainer ring is clamped in the retainer ring groove to achieve axial fixation of the bearing and achieve rotation; the sliding connection refers to the connection through the sliding of the sliding block in the sliding groove or the guide rail; the hinge joint is a movable connection mode on connecting parts such as a hinge, a pin shaft, a short shaft and the like; the required sealing positions are sealed by sealing rings or O-shaped rings.
The first embodiment is as follows:
the following describes this embodiment with reference to fig. 1 to 21, and a detection apparatus for a computer heat dissipation motor spindle includes a spindle fixing assembly 1, a reversing transmission assembly 2, a fixing frame assembly 3, a track diagram fixing assembly 4, a track pen fixing assembly 5, and an adjustment device 6, and is characterized in that: the main shaft fixing assembly 1 is connected with the reversing transmission assembly 2, the fixing frame assembly 3 is connected with the reversing transmission assembly 2, the track chart fixing assembly 4 is connected with the fixing frame assembly 3, the track chart fixing assembly 4 is connected with the track pen fixing assembly 5, and the adjusting device 6 is connected with the track chart fixing assembly 4.
The second embodiment is as follows:
the embodiment is described below with reference to fig. 1 to 21, and the embodiment further describes the first embodiment, where the spindle fixing assembly 1 includes a fixing rod 1-1, a fixing push spring 1-2, a fixing driving rod 1-3, a driving bevel gear 1-4, a matching frustum 1-5, a driving boss 1-6, a matching hollow groove 1-7, an inner chute 1-8, and a side wall sliding hole 1-9, the fixing push spring 1-2 is connected to the fixing rod 1-1 in a sleeved manner, the fixing push spring 1-2 is connected to the fixing driving rod 1-3 in a sliding manner, the driving bevel gear 1-4 is connected to the fixing driving rod 1-3 in a fixed manner, the matching frustum 1-5 is connected to the fixing rod 1-1 in a fixed manner, and the driving boss 1-6 is connected to the matching frustum 1-5 in a fixed manner, the matched hollow groove 1-7 is arranged at the front end of the fixed rod 1-1, and the inner chute 1-8 and the side wall slide hole 1-9 are arranged on the fixed driving rod 1-3;
one end of a main shaft of a radiating motor of a computer to be tested is connected with the matching hollowed-out groove 1-7 in a matching mode, the radiating motor is started at the same time, the fixing rod 1-1 is driven to rotate through the matching of the radiating motor and the matching hollowed-out groove 1-7, the fixing driving rod 1-3 is driven to rotate through the matching connection of the driving boss 1-6 and the side wall sliding hole 1-9, and then the driving bevel gear 1-4 is driven to rotate.
The third concrete implementation mode:
the first embodiment is further described with reference to fig. 1-21, the reversing transmission assembly 2 includes a first transmission bevel gear 2-1, a first matching sleeve 2-2, a second driving sleeve 2-3, a main shaft rod 2-4, a second transmission bevel gear 2-5, a first matching clamping rod 2-6, an auxiliary sleeve 2-7, a straight meshing tooth 2-8, a first hinge rod 2-9, a tension spring 2-10, a second hinge rod 2-11, a second matching clamping rod 2-12, a matching sliding chute 2-13, a first matching boss 2-14, an inner sliding rod 2-15, a hollow pipe 2-16 and a second matching boss 2-17, the second matching clamping rod 2-12 is fixedly connected with the first transmission bevel gear 2-1, the first matching boss 2-14 and the second matching boss 2-17 are fixedly connected with the second matching sleeve 2-2, an inner slide bar 2-15 is fixedly connected with a matching sleeve 2-2, a hollow tube 2-16 is arranged on the matching sleeve 2-2, a matching chute 2-13 is arranged on a main shaft bar 2-4, the inner slide bar 2-15 is slidably connected with the matching chute 2-13, the matching sleeve 2-2 is rotatably connected with a driving sleeve 2-3, a driving bevel gear I2-1 and a driving bevel gear II 2-5 are both rotatably connected with the main shaft bar 2-4, a matching clamping bar I2-6 is fixedly connected with the driving bevel gear II 2-5, an auxiliary sleeve 2-7 is rotatably connected with the main shaft bar 2-4, a meshing straight tooth 2-8 is fixedly connected with the main shaft bar 2-4, a hinge bar I2-9 is hinged with the auxiliary sleeve 2-7, a tension spring 2-10 is connected between the hinge bar I2-9 and the auxiliary sleeve 2-7, the second hinged rod 2-11 is connected in front of the first hinged rod 2-3 and the second hinged rod 2-9, the first matching boss 2-14 is connected with the second matching clamping rod 2-12 in a matching mode, and the driving bevel gear 1-4 is in meshing transmission with the first transmission bevel gear 2-1 and the second transmission bevel gear 2-5;
the second hinge rod 2-11 is pulled, the second drive sleeve 2-3 is driven by the second hinge rod 2-11 to drag the second matching sleeve 2-2 to slide in the first matching sliding groove 2-13, the second matching clamping rod 2-12 is separated from the first matching boss 2-14, the second matching boss 2-17 is in matching connection with the first matching clamping rod 2-6 through the driving of the second hinge rod 2-11, the meshing transmission of the first drive bevel gear 1-4 and the first transmission bevel gear 2-1 is disabled, the second drive bevel gear 1-4 and the second transmission bevel gear 2-5 are in meshing transmission, the rotating direction of the main shaft rod 2-4 is changed, and the fixed end rod 5-1 moves in the second rectangular sliding hole 3-8 along the opposite direction under the driving of the first meshing gear 2-8, so that the fixed end rod 5-1 reciprocates in the rectangular sliding hole II 3-8; the stylus is placed in the fixed sleeve 5-4.
The fourth concrete implementation mode:
the embodiment is described below with reference to fig. 1 to 21, and the embodiment further describes the first embodiment, where the fixed frame assembly 3 includes a fixed bottom plate 3-1, a fixed frame one 3-2, a fixed frame two 3-3, a fixed frame three 3-4, a fixed frame four 3-5, a rectangular sliding hole one 3-6, a fixed frame five 3-7, a rectangular sliding hole two 3-8, a driving frame 3-9, a hinged connecting rod 3-10, a driving frame rod one 3-11, a driving frame two 3-12, a driving frame connecting end 3-13 and a driving frame sliding groove 3-14, the fixed frame one 3-2, the fixed frame two 3-3 and the fixed frame three 3-4 are all fixedly connected with the fixed bottom plate 3-1, the fixed frame four 3-5 and the fixed frame five 3-7 are all fixedly connected with the fixed bottom plate 3-1, the rectangular sliding hole I3-6 is arranged on the fixed frame III 3-4, the rectangular sliding hole II 3-8 is arranged on the fixed frame IV 3-5, the driving frame sliding groove 3-14 is arranged on the fixed bottom plate 3-1, the driving frame rod I3-11, the driving frame II 3-12 and the driving frame connecting end 3-13 are fixedly connected with the driving frame 3-9, the driving frame 3-9 is in sliding connection with the driving frame sliding groove 3-14, the hinged connecting rod 3-10 is in hinged connection with the driving frame connecting end 3-13, the main shaft rod 2-4 is in rotating connection with the fixed frame I3-2 and the fixed frame III 3-4, the fixed driving rod 1-3 is in rotating connection with the fixed frame II 3-3, and the fixed frame V3-7 is fixedly connected with the auxiliary sleeve 2-7.
The fifth concrete implementation mode:
the first embodiment is further described with reference to fig. 1-21, where the fixed assembly 4 of the track map includes a fixed base plate 4-1, a first bracket 4-2, a first driving spur 4-3, a first driving roller 4-4, a first driving push plate 4-5, a first driving push spring 4-6, a first driving matching plate 4-7, a second bracket 4-8, a second driven roller 4-9, a second driven push plate 4-10, a second driven push spring 4-11, and a second driven matching plate 4-12, where the first bracket 4-2 and the second bracket 4-8 are both fixedly connected to the fixed base plate 4-1, the first driving spur 4-3 is fixedly connected to the first driving roller 4-4, the first driving roller 4-4 is rotatably connected to the first bracket 4-2, the first driving push plate 4-5 is slidably connected to the first driving roller 4-4, the driving push spring 4-6 is connected with the driving roller 4-4 in a sleeved mode, the driving matching plate 4-7 is fixedly connected with the driving roller 4-4, the driven roller 4-9 is connected with the second support 4-8 in a matched mode, the driven push plate 4-10 is connected with the driven roller 4-9 in a sliding mode, the driven push spring 4-11 is connected with the driven roller 4-9 in a sleeved mode, the driven matching plate 4-12 is fixedly connected with the driven roller 4-9, and the fixing bottom plate 4-1 is fixedly connected with the fixing bottom plate 3-1.
The sixth specific implementation mode:
referring to fig. 1-21, the present embodiment will be described in detail, and the first embodiment will be further described, in which the stylus pen fixing assembly 5 includes a fixed end bar 5-1, a fixed end bar connection post 5-2, a driving rack plate 5-3, a fixed sleeve 5-4, a fixed clamp bar 5-5, and an inner end push spring 5-6, the fixed end bar connection post 5-2 is fixedly connected to the fixed end bar 5-1, the driving rack plate 5-3 is fixedly connected to the fixed end bar 5-1, the fixed sleeve 5-4 is fixedly connected to the fixed end bar 5-1, the fixed clamp bar 5-5 is slidably connected to the fixed sleeve 5-4, the inner end push spring 5-6 is disposed between the fixed clamp bar 5-5 and the fixed sleeve 5-4, and the inner end push spring 5-6 is in a compressed state, the meshed straight teeth 2-8 are matched and connected with the driving rack plate 5-3, and the fixed end rod 5-1 is slidably connected with the rectangular sliding hole II 3-8.
The seventh embodiment:
the embodiment is described below with reference to fig. 1-21, and the embodiment will be further described, wherein the adjusting device 6 comprises an adjusting bottom plate 6-1, a motor 6-2, an input straight tooth 6-3, a transmission straight tooth 6-4, a transmission bevel tooth a6-5, a transmission bevel tooth B6-6, an adjusting rod 6-7, an adjusting rotating rod 6-8, a transmission bevel tooth C6-9, an output straight tooth 6-10, a first hinge frame rod 6-11 and a second hinge frame rod 6-12, the first hinge frame rod 6-11 and the second hinge frame rod 6-12 are both fixedly connected with the adjusting bottom plate 6-1, the motor 6-2 is fixedly connected with the adjusting bottom plate 6-1, the input straight tooth 6-3 is fixedly connected with an output shaft of the motor 6-2, the input straight tooth 6-3 is in meshing transmission with the transmission straight tooth 6-4, the transmission straight tooth 6-4 is fixedly connected with a transmission bevel tooth A6-5, the transmission bevel tooth A6-5 is rotatably connected with a transmission bevel tooth A6-5, the transmission bevel tooth A6-5 is in meshing transmission with a transmission bevel tooth B6-6, the transmission bevel tooth B6-6 is rotatably connected with an adjusting rod 6-7, the adjusting rod 6-7 is rotatably connected with an adjusting rotating rod 6-8, two ends of the adjusting rotating rod 6-8 are respectively rotatably connected in a first hinge frame rod 6-11 and a second hinge frame rod 6-12, the transmission bevel tooth C6-9 is in meshing transmission with the transmission bevel tooth B6-6, the transmission bevel tooth C6-9 is fixedly connected with an output straight tooth 6-10, the output straight tooth 6-10 is in meshing transmission with a driving straight tooth 4-3, and the adjusting bottom plate 6-1 is fixedly connected with a fixed bottom plate 4-1.
The invention discloses a detection device for a computer heat dissipation motor spindle, which has the working principle that:
when the heat dissipation motor is used, one end of a main shaft of a heat dissipation motor of a computer to be tested is in fit connection with the matching hollow-out groove 1-7, the heat dissipation motor is started, the fixing rod 1-1 is driven to rotate through the fit of the heat dissipation motor and the matching hollow-out groove 1-7, the fixing driving rod 1-3 is driven to rotate through the fit connection of the driving boss 1-6 and the side wall sliding hole 1-9, the driving bevel gear 1-4 is driven to rotate, the driving bevel gear 1-4 and the driving bevel gear I2-1 are driven to rotate on the main shaft rod 2-4 through the meshing transmission of the driving bevel gear 1-4 and the driving bevel gear I2-1 and the matching clamping rod I2-6, the driving bevel gear I2-1 rotates and is connected with the matching boss I2-14 through the matching clamping rod II 2-12, the driving device drives the matching sleeve 2-2 to rotate, and drives the main shaft rod 2-4 to rotate through the matching connection of the inner slide rod 2-15 and the matching sliding chute 2-13, and further drives the meshing straight teeth 2-8 to rotate, the fixed end rod 5-1 is driven to slide in the rectangular sliding hole II 3-8 through the matching connection of the meshing straight teeth 2-8 and the driving rack plate 5-3, the hinged connecting rod 3-10 is driven through the fixed end rod connecting column 5-2, the driving rack 3-9 is driven to slide in the driving rack sliding chute 3-14 through the hinged connection of the hinged connecting rod 3-10 and the driving rack 3-9, and the driving rack rod I3-11 is driven to slide to the right side through the sliding of the driving rack 3-9, and simultaneously, the hinged rod II 2-11 is stirred, the driving sleeve 2-3 is driven by the hinged rod two 2-11 to drag the matching sleeve 2-2 to slide in the matching sliding groove 2-13, meanwhile, the second matching clamping rod 2-12 is separated from the first matching lug boss 2-14, and the second matching clamping rod is driven by the second hinge rod 2-11, so that the matching boss II 2-17 is matched and connected with the matching clamping rod I2-6, the meshing transmission of the driving bevel gear 1-4 and the transmission bevel gear I2-1 is disabled, simultaneously, the driving bevel teeth 1-4 are meshed with the driving bevel teeth 2-5 for transmission, so that the rotation direction of the main shaft rod 2-4 is changed, driven by the meshing straight teeth 2-8, the fixed end rod 5-1 moves in the rectangular sliding hole two 3-8 along the opposite direction, so that the fixed end rod 5-1 reciprocates in the rectangular sliding hole II 3-8; placing the track pen in a fixed sleeve 5-4, enabling a fixed clamping rod 5-5 to clamp the track pen through pushing of an inner end pushing spring 5-6, and enabling the track pen to form a complete test curve in a track diagram fixed combination 4 through reciprocating motion of the fixed end rod 5-1 in a rectangular sliding hole II 3-8; the locus diagram is placed in a locus diagram fixing assembly 4, one point of the locus diagram is wound on a driven roller 4-9 and is placed between a driven push plate 4-10 and the driven roller 4-9, the driven push plate 4-10 and the driven roller 4-9 are enabled to fasten one end of the locus diagram by pushing of the driven push spring 4-11, similarly, the other end of the locus diagram is placed between a driving roller 4-4 and a driving push plate 4-5, the driving push plate 4-5 and the driving roller 4-4 are enabled to fasten the other end of the locus diagram by pushing of the driving push spring 4-6, a motor 6-2 is started at the same time, the motor 6-2 drives a transmission straight tooth 6-4 to rotate by an input straight tooth 6-3, and further drives a transmission conical tooth A6-5 to rotate, the transmission bevel gear C6-9 is driven to rotate through the transmission bevel gear B6-6, so that the output straight gear 6-10 is driven to rotate, the driving roller 4-4 is driven to rotate through the meshing transmission of the output straight gear 6-10 and the driving straight gear 4-3, so that the locus diagram is driven to rotate, the rotation of the main shaft of the thermoelectric motor is converted into a locus on the locus diagram through the contact of the locus diagram and a locus pen, and the test is convenient to carry out.
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.